The new approach uses samples from infected humans to allow real-time monitoring of pathogens circulating in human populations, and enable vaccine-evading bugs to be quickly and automatically identified. This could inform the development of vaccines that are more effective in preventing disease.

The approach can also quickly detect emerging variants with resistance to antibiotics. This could inform the choice of treatment for people who become infected - and try to limit the spread of the disease.

It uses genetic sequencing data to provide information on the genetic changes underlying the emergence of new variants. This is important to help understand why different variants spread differently in human populations.

There are very few systems in place to keep watch for emerging variants of infectious diseases, apart from the established COVID and influenza surveillance programmes. The technique is a major advance on the existing approach to these diseases, which has relied on groups of experts to decide when a circulating bacteria or virus has changed enough to be designated a new variant.

By creating ‘family trees’, the new approach identifies new variants automatically based on how much a pathogen has changed genetically, and how easily it spreads in the human population – removing the need to convene experts to do this. 

It can be used for a broad range of viruses and bacteria and only a small number of samples, taken from infected people, are needed to reveal the variants circulating in a population. This makes it particularly valuable for resource-poor settings.

The report is published today in the journal Nature.

“Our new method provides a way to show, surprisingly quickly, whether there are new transmissible variants of pathogens circulating in populations - and it can be used for a huge range of bacteria and viruses,” said Dr Noémie Lefrancq, first author of the report, who carried out the work at the University of Cambridge’s Department of Genetics.

Lefrancq, who is now based at ETH Zurich, added: “We can even use it to start predicting how new variants are going to take over, which means decisions can quickly be made about how to respond.” 

“Our method provides a completely objective way of spotting new strains of disease-causing bugs, by analysing their genetics and how they’re spreading in the population. This means we can rapidly and effectively spot the emergence of new highly transmissible strains,” said Professor Julian Parkhill, a researcher in the University of Cambridge’s Department of Veterinary Medicine who was involved in the study.

Testing the technique

The researchers used their new technique to analyse samples of Bordetella pertussis, the bacteria that causes whooping cough. Many countries are currently experiencing their worst whooping cough outbreaks of the last 25 years. It immediately identified three new variants circulating in the population that had been previously undetected.

“The novel method proves very timely for the agent of whooping cough, which warrants reinforced surveillance given its current comeback in many countries and the worrying emergence of antimicrobial resistant lineages,” said Professor Sylvain Brisse, Head of the National Reference Center for whooping cough at Institut Pasteur, who provided bioresources and expertise on Bordetella pertussis genomic analyses and epidemiology.

In a second test, they analysed samples of Mycobacterium tuberculosis, the bacteria that causes Tuberculosis. It showed that two variants with resistance to antibiotics are spreading.

“The approach will quickly show which variants of a pathogen are most worrying in terms of the potential to make people ill. This means a vaccine can be specifically targeted against these variants, to make it as effective as possible,” said Professor Henrik Salje in the University of Cambridge’s Department of Genetics, senior author of the report.

He added: “If we see a rapid expansion of an antibiotic-resistant variant, then we could change the antibiotic that’s being prescribed to people infected by it, to try and limit the spread of that variant.”

The researchers say this work is an important piece in the larger jigsaw of any public health response to infectious disease.

A constant threat

Bacteria and viruses that cause disease are constantly evolving to be better and faster at spreading between us. During the COVID pandemic, this led to the emergence of new strains: the original Wuhan strain spread rapidly but was later overtaken by other variants, including Omicron, which evolved from the original and were better at spreading. Underlying this evolution are changes in the genetic make-up of the pathogens.

Pathogens evolve through genetic changes that make them better at spreading. Scientists are particularly worried about genetic changes that allow pathogens to evade our immune system and cause disease despite us being vaccinated against them. 

“This work has the potential to become an integral part of infectious disease surveillance systems around the world, and the insights it provides could completely change the way governments respond,” said Salje.

The research was primarily funded by the European Research Council.

Reference: Lefrancq, N. et al: ‘Learning the fitness dynamics of pathogens from phylogenies.’ January 2025, DOI: 10.1038/s41586-024-08309-9
 

Researchers have come up with a new way to identify more infectious variants of viruses or bacteria that start spreading in humans - including those causing flu, COVID, whooping cough and tuberculosis.

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Former University of Cambridge Vice-Chancellor Professor Sir Leszek Borysiewicz, an Honorary Fellow of Wolfson College and Homerton College, is made Knight Grand Cross (GBE) for services to cancer research, clinical research, medicine and to charities.

Professor Ijeoma Uchegbu, who has been President of Wolfson College since October 2024, becomes a Dame (DBE) for services to chemical sciences and inclusion and diversity. Prof Uchegbu is a renowned expert in the field of pharmaceutical science and was most recently Professor of Pharmaceutical Nanoscience at University College London. Her research has focussed on methods that can be used to help drugs reach their target more effectively and reduce the likelihood of uncomfortable side effects. While at UCL she spearheaded a project to improve outcomes for both staff and students from under-represented ethnic groups. She is is a Fellow of the Academy of Medical Sciences and an Honorary Fellow of the Royal Society of Chemistry.

She said: “I’m absolutely thrilled. I wouldn’t say I’m humbled – I know people say that, but when I saw the letter at the Porters’ Lodge what I felt was an overwhelming sense of gratitude and pride. In my wildest dreams I never believed I would get such an award.”

Professor Ashley Moffet, Professor of Reproductive Immunology, is made Companion of the Most Distinguished Order of Saint Michael and Saint George (CMG) for services to reproductive health. A Fellow of King's College, she is the foremost international authority on the immunology of human reproduction and her work on genetic research has helped explain high rates of pre-eclampsia and maternal mortality in Ugandan populations. She is a Fellow of both the Academy of Medical Sciences and the Royal College of Obstetricians and Gynaecologists. 

She said: "I am delighted by this honour that is a tribute to the hard work and dedication of my many colleagues both here in Cambridge and in Uganda who are working together so tirelessly to support women in the field of maternal health."

Professor Gilly Carr is Professor of Conflict Archaeology and Holocaust Heritage and receives an OBE for services to Holocaust research and education. Professor Carr, a Fellow of St Catharine's College, is a member of both the UK delegation of the International Holocaust Remembrance Alliance (IHRA) and the academic advisory board for the UK Holocaust Memorial Centre. Professor Carr has a particular research interest in wartime incarceration, internment and imprisonment. 2024 saw the publication of her latest book 'A Materiality of Internment' which drew on over 15 years of research and interviews with more than 65 former internees. 

She said: “I am absolutely thrilled for my research and teaching to be recognised in this way. I've been working hard on behalf of victims of Nazism and the Holocaust for 15 years and for this to be seen as nationally important and worthwhile encourages me to continue my work with vigour.”

Professor Rachel Oliver, who also receives an OBE, is a materials engineer, inventor and commercial spinout founder. A Fellow of Robinson College, she is currently Director of the Cambridge Centre for Gallium Nitride and Chief Scientific Officer of Poro Technologies Ltd. (Porotech). Her research is in understanding and engineering the small-scale structure of semiconductor materials to enable new technologies to develop. Prof Oliver is a Fellow of the Royal Society of Engineering and is a passionate advocate for equality, diversity and inclusion in science and engineering. 

She said: “I am delighted to receive this honour and it is vital that I acknowledge the fabulous teams that I work with both in the University of Cambridge and at Porotech, a company that spun out from my research group.  I hope I can encourage more people to get involved in semiconductors in the UK. The semiconductor ecosystem has been an exciting place to work throughout my career, but never more so than right now, with both research and industry rapidly growing and stepping up to address some of the most pressing challenges we face.”

Dr James Biddulph, former headteacher of the University of Cambridge Primary School, has been awarded an MBE for services to education. Dr Biddulph was the inaugural headteacher of the school from 2015 until 2023, and under his leadership it attained an Outstanding Ofsted rating in 2018.

Eleanor Sharpston KC, an Emeritus Fellow of King's College, has been made Dame Commander of the Order of St Michael and St George (DCMG) for services to Justice and to the Education of Law in the UK and Europe. Dame Eleanor has combined a career as a barrister (specialising in European Union and European Convention on Human Rights law) with an academic career first at University College London and then at the University of Cambridge where she continues as a Yorke Distinguished Visiting Fellow at the Law Faculty. She was also Arthur Goodhart Visiting Professor in Legal Science from 2023 to 2024.

Academics and staff at both the University of Cambridge and Colleges feature in the 2025 list, which recognises the achievements and service of people across the UK.

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The near future could see AI assistants that forecast and influence our decision-making at an early stage, and sell these developing “intentions” in real-time to companies that can meet the need – even before we have made up our minds.

This is according to AI ethicists from the University of Cambridge, who say we are at the dawn of a “lucrative yet troubling new marketplace for digital signals of intent”, from buying movie tickets to voting for candidates. They call this the Intention Economy.

Researchers from Cambridge’s Leverhulme Centre for the Future of Intelligence (LCFI) argue that the explosion in generative AI, and our increasing familiarity with chatbots, opens a new frontier of “persuasive technologies” – one hinted at in recent corporate announcements by tech giants.

“Anthropomorphic” AI agents, from chatbot assistants to digital tutors and girlfriends, will have access to vast quantities of intimate psychological and behavioural data, often gleaned via informal, conversational spoken dialogue. 

This AI will combine knowledge of our online habits with an uncanny ability to attune to us in ways we find comforting – mimicking personalities and anticipating desired responses – to build levels of trust and understanding that allow for social manipulation on an industrial scale, say researchers.

“Tremendous resources are being expended to position AI assistants in every area of life, which should raise the question of whose interests and purposes these so-called assistants are designed to serve”, said LCFI Visiting Scholar Dr Yaqub Chaudhary.

“What people say when conversing, how they say it, and the type of inferences that can be made in real-time as a result, are far more intimate than just records of online interactions”

“We caution that AI tools are already being developed to elicit, infer, collect, record, understand, forecast, and ultimately manipulate and commodify human plans and purposes.”

Dr Jonnie Penn, an historian of technology from Cambridge’s LCFI, said: “For decades, attention has been the currency of the internet. Sharing your attention with social media platforms such as Facebook and Instagram drove the online economy.”

“Unless regulated, the intention economy will treat your motivations as the new currency. It will be a gold rush for those who target, steer, and sell human intentions.”

“We should start to consider the likely impact such a marketplace would have on human aspirations, including free and fair elections, a free press, and fair market competition, before we become victims of its unintended consequences.”

In a new Harvard Data Science Review paper, Penn and Chaudhary write that the intention economy will be the attention economy “plotted in time”: profiling how user attention and communicative style connects to patterns of behaviour and the choices we end up making.

“While some intentions are fleeting, classifying and targeting the intentions that persist will be extremely profitable for advertisers,” said Chaudhary.

In an intention economy, Large Language Models or LLMs could be used to target, at low cost, a user’s cadence, politics, vocabulary, age, gender, online history, and even preferences for flattery and ingratiation, write the researchers.

This information-gathering would be linked with brokered bidding networks to maximize the likelihood of achieving a given aim, such as selling a cinema trip (“You mentioned feeling overworked, shall I book you that movie ticket we’d talked about?”).

This could include steering conversations in the service of particular platforms, advertisers, businesses, and even political organisations, argue Penn and Chaudhary.

While researchers say the intention economy is currently an “aspiration” for the tech industry, they track early signs of this trend through published research and the hints dropped by several major tech players.

These include an open call for “data that expresses human intention… across any language, topic, and format” in a 2023 OpenAI blogpost, while the director of product at Shopify – an OpenAI partner – spoke of chatbots coming in “to explicitly get the user’s intent” at a conference the same year.

Nvidia’s CEO has spoken publicly of using LLMs to figure out intention and desire, while Meta released “Intentonomy” research, a dataset for human intent understanding, back in 2021.

In 2024, Apple’s new “App Intents” developer framework for connecting apps to Siri (Apple’s voice-controlled personal assistant), includes protocols to “predict actions someone might take in future” and “to suggest the app intent to someone in the future using predictions you [the developer] provide”.

“AI agents such as Meta’s CICERO are said to achieve human level play in the game Diplomacy, which is dependent on inferring and predicting intent, and using persuasive dialogue to advance one’s position,” said Chaudhary.

“These companies already sell our attention. To get the commercial edge, the logical next step is to use the technology they are clearly developing to forecast our intentions, and sell our desires before we have even fully comprehended what they are.”

Penn points out that these developments are not necessarily bad, but have the potential to be destructive. “Public awareness of what is coming is the key to ensuring we don’t go down the wrong path,” he said.

Conversational AI agents may develop the ability to covertly influence our intentions, creating a new commercial frontier that researchers call the “intention economy”.

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Desert locusts typically lead solitary lives until something - like intense rainfall - triggers them to swarm in vast numbers, often with devastating consequences. 

This migratory pest can reach plague proportions, and a swarm covering one square kilometre can consume enough food in one day to feed 35,000 people. Such extensive crop destruction pushes up local food prices and can lead to riots and mass starvation.

Now a team led by the University of Cambridge has developed a way to predict when and where desert locusts will swarm, so they can be dealt with before the problem gets out of hand. 

It uses weather forecast data from the UK Met Office, and state-of the-art computational models of the insects’ movements in the air, to predict where swarms will go as they search for new feeding and breeding grounds. The areas likely to be affected can then be sprayed with pesticides.

Until now, predicting and controlling locust swarms has been ‘hit and miss’, according to the researchers. Their new model, published today in the journal PLOS Computational Biology, will enable national agencies to respond quickly to a developing locust threat.

Desert locust control is a top priority for food security: it is the biggest migratory pest for smallholder farmers in many regions of Africa and Asia, and capable of long-distance travel across national boundaries.

Climate change is expected to drive more frequent desert locust swarms, by causing trigger events like cyclones and intense rainfall. These bring moisture to desert regions that allows plants to thrive, providing food for locusts that triggers their breeding.

“During a desert locust outbreak we can now predict where swarms will go several days in advance, so we can control them at particular sites. And if they’re not controlled at those sites, we can predict where they’ll go next so preparations can be made there,” said Dr Renata Retkute, a researcher in the University of Cambridge’s Department of Plant Sciences and first author of the paper.

“The important thing is to respond quickly if there’s likely to be a big locust upsurge, before it causes a major crop loss.  Huge swarms can lead to really desperate situations where people could starve,” said Professor Chris Gilligan in the University of Cambridge’s Department of Plant Sciences, senior author of the paper.

He added: “Our model will allow us to hit the ground running in future, rather than starting from scratch as has historically been the case.”

The team noticed the need for a comprehensive model of desert locust behaviour during the response to a massive upsurge over 2019-2021, which extended from Kenya to India and put huge strain on wheat production in these regions. The infestations destroyed sugarcane, sorghum, maize and root crops. The researchers say the scientific response was hampered by the need to gather and integrate information from a range of disparate sources.

“The response to the last locust upsurge was very ad-hoc, and less efficient than it could have been. We’ve created a comprehensive model that can be used next time to control this devastating pest,” said Retkute. 

Although models like this have been attempted before, this is the first that can rapidly and reliably predict swarm behaviour. It takes into account the insects’ lifecycle and their selection of breeding sites, and can forecast locust swarm movements both short and long-term. 

The new model has been rigorously tested using real surveillance and weather data from the last major locust upsurge. It will inform surveillance, early warning, and management of desert locust swarms by national governments, and international organisations like the Food and Agriculture Organisation of the United Nations (FAO).

The researchers say countries that haven’t experienced a locust upsurge in many years are often ill-prepared to respond, lacking the necessary surveillance teams, aircraft and pesticides. As climate change alters the movement and spread of major swarms, better planning is needed - making the new model a timely development.

The project involved collaborators at the FAO and the UK Met Office. It was funded by the UK Foreign, Commonwealth and Development Office and the Bill and Melinda Gates Foundation.

Reference: Retkute, R., et al: ‘A framework for modelling desert locust population dynamics and large-scale dispersal.’ PLOS Computational Biology, December 2024. DOI: 10.1371/journal.pcbi.1012562
 

A new tool that predicts the behaviour of desert locust populations will help national agencies to manage huge swarms before they devastate food crops in Africa and Asia. 

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Like a bear gorging itself on salmon before hibernating for the winter, or a much-needed nap after Christmas dinner, this black hole has overeaten to the point that it is lying dormant in its host galaxy.

An international team of astronomers, led by the University of Cambridge, used the NASA/ESA/CSA James Webb Space Telescope to detect this black hole in the early universe, just 800 million years after the Big Bang.

The black hole is huge – 400 million times the mass of our Sun – making it one of the most massive black holes discovered by Webb at this point in the universe’s development. The black hole is so enormous that it makes up roughly 40% of the total mass of its host galaxy: in comparison, most black holes in the local universe are roughly 0.1% of their host galaxy mass.

However, despite its gigantic size, this black hole is eating, or accreting, the gas it needs to grow at a very low rate – about 100 times below its theoretical maximum limit – making it essentially dormant.

Such an over-massive black hole so early in the universe, but one that isn’t growing, challenges existing models of how black holes develop. However, the researchers say that the most likely scenario is that black holes go through short periods of ultra-fast growth, followed by long periods of dormancy. Their results are reported in the journal Nature.

When black holes are ‘napping’, they are far less luminous, making them more difficult to spot, even with highly sensitive telescopes such as Webb. Black holes cannot be directly observed, but instead they are detected by the tell-tale glow of a swirling accretion disc, which forms near the black hole’s edges. When black holes are actively growing, the gas in the accretion disc becomes extremely hot and starts to glow and radiate energy in the ultraviolet range.

“Even though this black hole is dormant, its enormous size made it possible for us to detect,” said lead author Ignas Juodžbalis from Cambridge’s Kavli Institute for Cosmology. “Its dormant state allowed us to learn about the mass of the host galaxy as well. The early universe managed to produce some absolute monsters, even in relatively tiny galaxies.”

According to standard models, black holes form from the collapsed remnants of dead stars and accrete matter up to a predicted limit, known as the Eddington limit, where the pressure of radiation on matter overcomes the gravitational pull of the black hole. However, the sheer size of this black hole suggests that standard models may not adequately explain how these monsters form and grow.

“It’s possible that black holes are ‘born big’, which could explain why Webb has spotted huge black holes in the early universe,” said co-author Professor Roberto Maiolino, from the Kavli Institute and Cambridge’s Cavendish Laboratory. “But another possibility is they go through periods of hyperactivity, followed by long periods of dormancy.”

Working with colleagues from Italy, the Cambridge researchers conducted a range of computer simulations to model how this dormant black hole could have grown to such a massive size so early in the universe. They found that the most likely scenario is that black holes can exceed the Eddington limit for short periods, during which they grow very rapidly, followed by long periods of inactivity: the researchers say that black holes such as this one likely eat for five to ten million years, and sleep for about 100 million years.

“It sounds counterintuitive to explain a dormant black hole with periods of hyperactivity, but these short bursts allow it to grow quickly while spending most of its time napping,” said Maiolino.

Because the periods of dormancy are much longer than the periods of ultra-fast growth, it is in these periods that astronomers are most likely to detect black holes. “This was the first result I had as part of my PhD, and it took me a little while to appreciate just how remarkable it was,” said Juodžbalis. “It wasn’t until I started speaking with my colleagues on the theoretical side of astronomy that I was able to see the true significance of this black hole.”

Due to their low luminosities, dormant black holes are more challenging for astronomers to detect, but the researchers say this black hole is almost certainly the tip of a much larger iceberg, if black holes in the early universe spend most of their time in a dormant state.

“It’s likely that the vast majority of black holes out there are in this dormant state – I’m surprised we found this one, but I’m excited to think that there are so many more we could find,” said Maiolino.

The observations were obtained as part of the JWST Advanced Deep Extragalactic Survey (JADES). The research was supported in part by the European Research Council and the Science and Technology Facilities Council (STFC), part of UK Research and Innovation (UKRI).

Reference:
Ignas Juodžbalis et al. ‘A dormant overmassive black hole in the early Universe.’ Nature (2024). DOI: 10.1038/s41586-024-08210-5

Scientists have spotted a massive black hole in the early universe that is ‘napping’ after stuffing itself with too much food.

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The annual Trial VIIIs, the UK’s final rowing event of the year, serves as a dress rehearsal for The Boat Race, with two evenly matched Cambridge University Boat Club (CUBC) crews rowing the full Championship Course for the first and only time before 12–13 April 2025.

This year, all 31 Cambridge Colleges were represented at the start of trials. The crews showcased an exciting mix of seasoned experience and youthful energy, featuring international rowers and returning Blues alongside many College rowers proudly wearing Cambridge Blue for the first time.

Read the full race report on the CUBC website.

The Cambridge contenders for The Boat Race 2025 have become clearer after a thrilling day of action on the Thames.

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A leading advocate for the rights of women and girls in Afghanistan, in particular the right to education, Joya is the founder of Rukhshana Media, a news agency dedicated to telling the stories of Afghan women in their own voices. Her appointment recognises her transformational work and reflects Hughes Hall’s mission to advance inclusive education.

Joya said: “In a time when, as a woman, I have been deprived of my basic rights in my own country, joining the extraordinary Hughes Hall team at the University of Cambridge is a great honour for me. I view this opportunity as a chance to step into a wellspring of knowledge, and I hope to learn from this team and bring what I learn here back to my people.”

Sir Laurie Bristow, President of Hughes Hall, welcomed Joya to the College: “Zahra’s work on behalf of Afghanistan’s women and girls has never been more urgent nor her own story more pertinent. Zahra’s work is about enabling Afghan women and girls to speak for themselves. It is about the right of all girls to receive an education. It is about challenging gender-based oppression and protecting the rights of some of the most vulnerable people in our world today.”

Read the full story on the Hughes Hall website.

Zahra Joya, an Afghan journalist and one of TIME magazine's Women of the Year 2022, has been appointed By-Fellow at Hughes Hall.

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Photonic chips transmit and manipulate light instead of electricity, and offer significantly faster performance with lower power consumption than traditional electronic chips. 

The Cambridge Graphene Centre and Cornerstone Photonics Innovation Centre at the University of Southampton will partner with members from across Europe to host a pilot line, coordinated by the Institute of Photonic Sciences in Spain, combining state-of-the-art equipment and expertise from 20 research organisations.

The PIXEurope consortium has been selected by the European Commission and Chips Joint Undertaking, a European initiative aiming to bolster the semiconductor industry by fostering collaboration between member states and the private sector. The consortium is supported by €380m in total funding.

The UK participants will be backed by up to £4.2 million in funding from the Department of Science, Innovation and Technology (DSIT), match-funded by Horizon Europe. The UK joined the EU’s Chips Joint Undertaking in March 2024, allowing the country to collaborate more closely with European partners on semiconductor innovation.

The new pilot line will combine state-of-the-art equipment and expertise from research organisations across 11 countries. It aims to encourage the adoption of cutting-edge photonic technologies across more industries to boost their efficiency.

Photonic chips are already essential across a wide range of applications, from tackling the unprecedented energy demands of datacentres, to enabling high-speed data transmission for mobile and satellite communications. In the future, these chips will become ever more important, unlocking new applications in healthcare, AI and quantum computing. 

Researchers at the Cambridge Graphene Centre will be responsible for the integration of graphene and related materials into photonic circuits for energy efficient, high-speed communications and quantum devices. “This may lead to life-changing products and services, with huge economic benefit for the UK and the world,” said Professor Andrea C. Ferrari, Director of the Cambridge Graphene Centre. 

The global market for photonic integrated circuits (PICs) production is expected to grow by more than 400% in the next 10 years. By the end of the decade, the global photonics market is expected to exceed €1,500bn, a figure comparable to the entire annual gross domestic product of Spain.

This growth is due to the demand from areas such as telecommunications, artificial intelligence, image sensing, automotive and mobility, medicine and healthcare, environmental care, renewable energy, defense and security, and a wide range of consumer applications.

The combination of microelectronic chips and photonic chips provides the necessary features and specifications for these applications. The former are responsible for information processing by manipulating electrons within circuits based on silicon and its variants, while the latter uses photons in the visible and infrared spectrum ranges in various materials.

The new pilot line aims to offer cutting-edge technological platforms, transforming and transferring innovative and disruptive integrated photonics processes and technologies to accelerate their industrial adoption. The objective is the creation of European-owned/made technology in a sector of capital importance for technological sovereignty, and the creation and maintenance of corresponding jobs in the UK and across Europe.

“My congratulations to Cornerstone and the Cambridge Graphene Centre on being selected to pioneer the new pilot line – taking a central role in driving semiconductor innovation to the next level, encouraging adoption of new technologies,” said Science Minister Lord Vallance. “The UK laid the foundations of silicon photonics in the 1990s, and by pooling our expertise with partners across Europe we can address urgent global challenges including energy consumption and efficiency.”

“The UK’s participation in the first Europe-wide photonics pilot line marks the start of the world’s first open access photonics integrated circuits ecosystem, stimulating new technology development with industry and catalyse disruptive innovation across the UK, while strengthening UK collaboration with top European institutions working in the field,” said Ferrari.

“PIXEurope is the first photonics pilot line that unifies the whole supply chain from design and fabrication, to testing and packaging, with technology platforms that will support a broad spectrum of applications,” said CORNERSTONE Coordinator Professor Calum Littlejohns. “I am delighted that CORNERSTONE will form a crucial part of this programme.”

The Chips JU will also launch new collaborative R&D calls on a range of topics in early 2025. UK companies and researchers are eligible to participate. 

The University of Cambridge is one of two UK participants named as part of the PIXEurope consortium, a collaboration between research organisations from across Europe which will develop and manufacture prototypes of their products based on photonic chips.

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Temperatures in cities are rising across the globe and urban heat stress is already a major problem causing illness, death, a surge in energy use to cool buildings down, heat-related social inequality issues and problems with urban infrastructure.

Some cities have already started implementing mitigation strategies, with tree planting prominent among them. But a University of Cambridge-led study now warns that planting the wrong species or the wrong combination of trees in suboptimal locations or arrangements can limit their benefits.

The study, published today in Communications Earth & Environment found that urban trees can lower pedestrian-level air temperature by up to 12°C. Its authors found that the introduction of trees reduced peak monthly temperatures to below 26°C in 83% of the cities studied, meeting the ‘thermal comfort threshold’. However, they also found that this cooling ability varies significantly around the world and is influenced by tree species traits, urban layout and climate conditions.

“Our study busts the myth that trees are the ultimate panacea for overheating cities across the globe,” said Dr Ronita Bardhan, Associate Professor of Sustainable Built Environment at Cambridge's Dept. of Architecture.

“Trees have a crucial role to play in cooling cities down but we need to plant them much more strategically to maximise the benefits which they can provide.”

Previous research on the cooling effects of urban trees has focused on specific climates or regions, and considered case studies in a fragmented way, leaving major gaps in our knowledge about unique tree cooling mechanisms and how these interact with diverse urban features.

To overcome this, the authors of this study analysed the findings of 182 studies – concerning 17 climates in 110 global cities or regions – published between 2010 and 2023, offering the first comprehensive global assessment of urban tree cooling.

During the day, trees cool cities in three ways: by blocking solar radiation; through evaporation of water via pores in their leaves; and by foliage aerodynamically changing airflow. At night, however, tree canopies can trap longwave radiation from the ground surface, due to aerodynamic resistance and ‘stomatal closure’ – the closing of microscopic pores on the surface of leaves partly in response to heat and drought stress.

Variation by climate type

The study found that urban trees generally cool cities more in hot and dry climates, and less in hot humid climates.

In the ‘tropical wet and dry or savanna’ climate, trees can cool cities by as much as 12 °C, as recorded in Nigeria. However, it was in this same climate that trees also warmed cities most at night, by up to 0.8°C.

Trees performed well in arid climates, cooling cities by just over 9°C and warming them at night by 0.4 °C.

In tropical rainforest climates, where humidity is higher, the daytime cooling effect dropped to approximately 2°C while the nighttime heating effect was 0.8 °C.

In temperate climates, trees can cool cities by up to 6°C and warm them by 1.5°C.

Using trees more strategically

The study points out that cities which have more open urban layouts are more likely to feature a mix of evergreen and deciduous trees of varying sizes. This, the researchers found, tends to result in greater cooling in temperate, continental and tropical climates.

The combined use of trees in these climates generally results in 0.5 °C more cooling than in cities where only deciduous or evergreen trees feature. This is because mixed trees can balance seasonal shading and sunlight, providing three-dimensional cooling at various heights.

In arid climates, however, the researchers found that evergreen species dominate and cool more effectively in the specific context of compact urban layouts such as Cairo in Egypt, or Dubai in UAE.

In general, trees cooled more effectively in open and low-rise cities in dry climates. In open urban layouts, cooling can be improved by about 0.4 °C because their larger green spaces allow for more and larger tree canopies and a greater mix of tree species.

“Our study provides context-specific greening guidelines for urban planners to more effectively harness tree cooling in the face of global warming,” Dr Ronita Bardhan said.

“Our results emphasize that urban planners not only need to give cities more green spaces, they need to plant the right mix of trees in optimal positions to maximize cooling benefits.”

 “Urban planners should plan for future warmer climates by choosing resilient species which will continue to thrive and maintain cooling benefits,” said Dr Bardhan, a Fellow of Selwyn College, Cambridge.

Matching trees to urban forms

The study goes further, arguing that species selection and placement needs to be compatible with urban forms. The orientation of the ‘street canyon’, local climate zones, aspect ratio, visible sky ratio and other urban features that influence the effects of trees all need to be carefully considered.

Although a higher degree of tree canopy cover in street canyons generally results in more cooling effects, excessively high cover may trap heat at the pedestrian level, especially in compact urban zones in high temperature climates. In such locations, narrow species and sparse planting strategies are recommended.

The researchers emphasise that we cannot rely entirely on trees to cool cities, and that solutions such as solar shading and reflective materials will continue to play an important role.

The researchers have developed an interactive database and map to enable users to estimate the cooling efficacy of strategies based on data from cities with similar climates and urban structures.

Reference

H Li et al., ‘Cooling efficacy of trees across cities is determined by background climate, urban morphology, and tree trait’, Communications Earth & Environment (2024). DOI: 10.1038/s43247-024-01908-4

While trees can cool some cities significantly during the day, new research shows that tree canopies can also trap heat and raise temperatures at night. The study aims to help urban planners choose the best combinations of trees and planting locations to combat urban heat stress.

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Professor Richards joins Cambridge from the University of Oxford, where he has been since 2019. His particular research interest is the demonstration of clinical proof of concept of novel therapeutics through the application of experimental medicine techniques, especially human challenge studies.

As Climax Professor of Clinical Therapeutics, director of the Oxford Clinical Trial Research Unit (OCTRU), and the NIHR Oxford Clinical Research Facility, he led a broad portfolio focused on new medicines for multiple conditions. His focus has been the acceleration of promising new drug treatments through better decision-making in early phase clinical trials.

Professor Richards also brings with him a wealth of experience in a number of Pharmaceutical R&D clinical development roles. In 2003 he joined GSK and held a number of roles of increasing responsibility, latterly as Head of Clinical Pharmacology and Experimental Medicine, including directorship of GSK’s phase 1 and experimental medicine unit in Cambridge (CUC).

Commenting on his appointment, Professor Richards said: “As a clinical pharmacologist, I have been fortunate to work across a broad range of therapeutic areas over the years. I am excited by the breadth and depth of expertise within the Department of Medicine and look forward to working with the first-class scientific team. My goal is to work with the Department team, the Clinical School, and hospitals to maximise the impact of the important work taking place in Cambridge.”

Members of the department’s leadership team are looking forward to the continued development of the department under Professor Richards, building on its legacy of collaboration and groundbreaking translational research to drive our future success.

Professor Mark Wills, Interim Head of Department of Medicine, said: “Duncan brings to his new role a fantastic breadth of experience, which encompasses his clinical speciality in pharmacology, extensive experience of working within the pharmaceutical industry R&D at senior levels and most recently establishing academic clinical trials units and human challenge research facilities.

“I am very excited to welcome Duncan to the Department and looking forward to working with him, as he takes on the role of delivering of the Department of Medicine’s vision to increase the efficacy of translation of its world class fundamental research, and its impact upon clinical practice and patient wellbeing.”

Menna Clatworthy, Professor of Translational Immunology and Director of the Cambridge Institute for Therapeutic Immunology and Infectious Disease (CITIID), said: "Duncan has a wealth of leadership experience in biomedicine, in both academia and pharma. That skillset will be invaluable in ensuring the Department of Medicine continues to deliver world-leading research to transform patient outcomes."

Charlotte Summers, Professor of Intensive Care Medicine and Director of the Victor Phillip Dahdaleh Heart & Lung Research Institute, said: “Duncan’s exemplary track record of translating fundamental scientific discoveries into therapies that benefit patients will help us further increase the impact of our research as we continue our mission to improve human health.”

The appointment underpins the recently announced five-year collaboration between GSK and the University of Cambridge, the Cambridge-GSK Translational Immunology Collaboration (CG-TIC). The £50 million investment will accelerate research and development in kidney and respiratory diseases to improve patient outcomes.

Professor Richards will assume the role in February 2025, replacing Interim Head of Department Dr Mark Wills who was appointed after the departure of Professor Ken Smith in January 2024.  Dr Wills will continue as Director of Research and Deputy Head of the Department of Medicine as well as leading his research group. 

Professor Richards trained in medicine at Oxford University and after junior doctor roles in London, he returned to Oxford as Clinical Lecturer in Clinical Pharmacology. His DM thesis research was on a translational model using platelet ion flux to interrogate angiotensin biology and he is author of the Oxford Handbook of Practical Drug Therapy and the 3rd edition of Drug Discovery and Development.

Professor Richards has been a core member of the UK COVID-19 Therapeutics Advisory Panel. He is a member of the Oxford Bioescalator Management Board, UK Prix Galien Prize Committee, and the therapeutic advisory committee of several national platform clinical trials.

Professor Duncan Richards has today been announced as the new Head of the Department of Medicine at the University of Cambridge.

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The technique, called hyperpolarised carbon-13 imaging, can increase the detected signal in an MRI scanner by more than 10,000 times. Scientists have found that the technique can distinguish between 2 different subtypes of ovarian cancer, to reveal their sensitivities to treatment.

They used it to look at patient-derived cell models that closely mimic the behaviour of human high grade serous ovarian cancer, the most common lethal form of the disease. The technique clearly shows whether a tumour is sensitive or resistant to Carboplatin, one of the standard first-line chemotherapy treatments for ovarian cancer. 

This will enable oncologists to predict how well a patient will respond to treatment, and to see how well the treatment is working within the first 48 hours. 

Different forms of ovarian cancer respond differently to drug treatments. With current tests, patients typically wait for weeks or months to find out whether their cancer is responding to treatment. The rapid feedback provided by this new technique will help oncologists to adjust and personalise treatment for each patient within days.

The study compared the hyperpolarised imaging technique with results from Positron Emission Tomography (PET) scans, which are already widely used in clinical practice. The results shows that PET did not pick up the metabolic differences between different tumour subtypes, so could not predict the type of tumour present.

The report is published today in the journal Oncogene.

“This technique tells us how aggressive an ovarian cancer tumour is, and could allow doctors to assess multiple tumours in a patient to give a more holistic assessment of disease prognosis so the most appropriate treatment can be selected,” said Professor Kevin Brindle in the University of Cambridge’s Department of Biochemistry, senior author of the report. 

Ovarian cancer patients often have multiple tumours spread throughout their abdomen. It isn’t possible to take biopsies of all of them, and they may be of different subtypes that respond differently to treatment. MRI is non-invasive, and the hyperpolarised imaging technique will allow oncologists to look at all the tumours at once.

Brindle added: “We can image a tumour pre-treatment to predict how likely it is to respond, and then we can image again immediately after treatment to confirm whether it has indeed responded. This will help doctors to select the most appropriate treatment for each patient and adjust this as necessary. 

“One of the questions cancer patients ask most often is whether their treatment is working. If doctors can speed their patients onto the best treatment, then it’s clearly of benefit.”

The next step is to trial the technique in ovarian cancer patients, which the scientists anticipate within the next few years.

Hyperpolarised carbon-13 imaging uses an injectable solution containing a ‘labelled’ form of the naturally occurring molecule pyruvate. The pyruvate enters the cells of the body, and the scan shows the rate at which it is broken down - or metabolised – into a molecule called lactate. The rate of this metabolism reveals the tumour subtype and thus its sensitivity to treatment.

This study adds to the evidence for the value of the hyperpolarised carbon-13 imaging technique for wider clinical use. 

Brindle, who also works at the Cancer Research UK Cambridge Institute, has been developing this imaging technique to investigate different cancers for the last two decades, including breast, prostate and glioblastoma - a common and aggressive type of brain tumour. Glioblastoma also shows different subtypes that vary in their metabolism, which can be imaged to predict their response to treatment. The first clinical study in Cambridge, which was published in 2020, was in breast cancer patients.

Each year about 7,500 women in the UK are diagnosed with ovarian cancer - around 5,000 of these will have the most aggressive form of the disease, called high-grade serous ovarian cancer (HGSOC). 

The cure rate for all forms of ovarian cancer is very low and currently only 43% of women in England survive five years beyond diagnosis. Symptoms can easily be missed, allowing the disease to spread before a woman is diagnosed - and this makes imaging and treatment challenging. 

The research was funded by Cancer Research UK.

Reference: Chia, M L: ‘Metabolic imaging distinguishes ovarian cancer subtypes and detects their early and variable responses to treatment.’ Oncogene, December 2024. DOI: 10.1038/s41388-024-03231-w

An MRI-based imaging technique developed at the University of Cambridge predicts the response of ovarian cancer tumours to treatment, and rapidly reveals how well treatment is working, in patient-derived cell models.

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Researchers hope that early detection, through the simple urine test, could enable earlier treatment interventions, significantly improving patient outcomes and prognosis. Around 36,600 lives are saved from lung cancer in the UK every year, according to new analysis from Cancer Research UK.

Professor Ljiljana Fruk and Dr Daniel Munoz Espin and their teams at the University of Cambridge are leading on the research, funded by Cancer Research UK.

The work, at Cambridge’s Department of Chemical Engineering and Biotechnology, and the Early Cancer Institute, will provide a cheap, affordable sensor that uses urine samples to help doctors detect lung cancer before the disease develops.

Lung cancer has a poor prognosis for many patients because often there are no noticeable symptoms until it has spread through the lungs or into other parts of the body. The new urine test will allow doctors to spot the disease before it develops.

To create the test, scientists looked at proteins excreted by senescent cells: “zombie” cells which are alive but unable to grow and divide. It’s these cells that cause tissue damage by reprogramming their immediate environment to help promote the emergence of cancer cells.

Now, researchers have developed an injectable sensor that interacts with zombie cell proteins and releases easily detectable compound into urine, signalling their presence.

“Early detection of cancer requires cost-effective tools and strategies that enable detection to happen quickly and accurately,” said Fruk. “We designed a test based on peptide-cleaving proteins, which are found at higher levels in the presence of zombie cells, and in turn appear in the early stages of cancer.

“Ultimately, we want to develop a urine test that could help doctors identify signs of the early stages of cancer – potentially months or even years before noticeable symptoms appear.”

As well as targeting lung cancer, Fruk hopes her research, along with joint efforts across other university departments, will result in the development of probes capable of detecting other cancers.

“We have almost completed a functional urine test to detect ‘zombie' cells in lung cancer, which will spot cancer earlier and avoid the need for invasive procedures, but this test does have potential for other cancers,” she said. “Developing more efficient cancer treatments requires earlier detection and better therapies, but also work with other disciplines for a more holistic view of the disease, which is an essential part of my research.”

From uncovering the causes of lung cancer to pioneering drugs to treat it, Cancer Research UK has helped power progress for people affected by lung cancer. Over the last 10 years, the charity has invested over £231 million in lung cancer research.

“Cancer Research UK has played a key role in advancing lung cancer research and improving survival,” said Dr Iain Foulkes, Cancer Research UK’s executive director of research and innovation. “This project being led by Professor Fruk is another example of our commitment to driving progress so that more people can live longer, better lives, free from the fear of cancer.”

Adapted from a Cancer Research UK media release. 

Cambridge scientists have developed a urine test for early detection of lung cancer. The test, the first of its kind, detects ‘zombie’ cells that could indicate the first signs of the disease.

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The Cambridge Centre for Advanced Research and Education in Singapore (CARES) is hosting two projects that aim to aid Singapore’s business transition away from petrochemicals towards a net-zero emissions target by 2050.

Under the newly launched CREATE Thematic Programme in Decarbonisation supported by the National Research Foundation (NRF), the two projects will investigate non-fossil fuel-based pathways for Singapore’s chemical manufacturing industry and energy systems. 

Deputy Prime Minister and Chairman of the NRF, Mr Heng Swee Keat toured the first of three laboratories for the programme to view the technical capabilities required for the various project teams, including CARES’ projects on the Sustainable Manufacture of Molecules and Materials in Singapore (SM3), and Hydrogen and Ammonia Combustion in Singapore (HYCOMBS).

SM3 aims to provide a path to a net-zero, high-value chemical manufacturing industry in Singapore. Its core goal is to address the dependency of producers of performance chemicals on starting materials that typically come from fossil-based carbon sources. The SM3 team hope to develop effective synthetic methods that best convert cheap and abundant fossil-free raw materials into high-value molecules, for use in sectors such as medicines and agrochemicals.

In project HYCOMBS, universities from Singapore, UK, Japan, France and Norway will work together to investigate the underlying combustion process of hydrogen and ammonia to minimise pollutants and accelerate industry innovation. 

As part of the lab demonstrations on decarbonisation, CARES showcased an additional ongoing activity with City Energy investigating hydrogen-rich town gas for residential and commercial cooking stoves.

Mr Heng Swee Keat said: "The need to tackle climate change and its impact grows ever more urgent. During my visit to Cambridge CARES (Centre for Advanced Research and Education in Singapore) — Cambridge University's first and only research centre outside the UK — I witnessed how research and international collaboration are driving innovative solutions to combat climate change, particularly in the area of decarbonisation.

"In just a decade, CARES has established cutting-edge R&D facilities dedicated to decarbonisation projects that not only reduce emissions but also pave the way for a more sustainable future for Singapore. From hydrogen combustion and laser-based combustion diagnostics to the development of cleaner fuels for gas stoves, their work is closely aligned with the goals outlined in our Singapore Green Plan 2030, and achieving Singapore’s net-zero emissions goal by 2050.

"It was encouraging to hear from Director of CARES, Professor Markus Kraft, as he shared how being based in the CREATE facility at the National University of Singapore facilitates interactions with researchers from diverse countries and disciplines. This collaborative and interdisciplinary approach embodies the essence of research — working together to address shared global challenges."

Since 2013, CARES has been involved in research programmes with Nanyang Technological University and the National University of Singapore as the University of Cambridge’s first overseas centre. One of its early flagship programmes, the Centre for Carbon Reduction in Chemical Technologies (C4T), has investigated areas from sustainable reaction engineering, electrochemistry, and maritime decarbonisation to digitalisation.

By building on this foundation and leveraging the local talent pool, CARES has attracted new partners from international universities and institutes for SM3 and HYCOMBS. This includes EPFL, the Swiss Federal Institute of Technology Lausanne, which will provide skills in the domain AI for chemistry. CNRS, the French National Centre for Scientific Research, the Norwegian University of Science and Technology, and Tohoku University from Japan will contribute technical equipment and key talent in hydrogen and ammonia combustion.

Adapted from a release originally published by CARES. 

Mr Heng Swee Keat, Deputy Prime Minister of Singapore and Chairman of the National Research Foundation (NRF) paid a visit to the University of Cambridge’s overseas research centre in Singapore and viewed its technical capabilities for decarbonisation research.

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The recent conflict in Lebanon has deepened a national education crisis in which children have already lost up to 60% of school time over the past 6 years, new research warns.

The report, by the Centre for Lebanese Studies and the University of Cambridge’s REAL Centre, is the first to assess the state of education since Israel began its ground offensive in Lebanon in October. Using surveys and interviews with parents and teachers, it provides a snapshot of the situation a few weeks before the new ceasefire between Israel and Hezbollah.

The study stresses that even if that ceasefire holds, a co-ordinated, forward-thinking response is essential to prevent further learning losses in an already fragile education system.

Before the recent conflict, Lebanese schools had endured over a decade of compounded crises, including an influx of Palestinian and Syrian refugees, a major financial crisis, the 2020 Beirut explosion, and the COVID-19 pandemic. Since 2018, the authors calculate, students have missed more than 760 teaching days due to strikes, disruption and closures.

The report shows that the effects of the latest violence have been uneven, depending on where families and teachers are based and their immediate circumstances. Refugee children and students with disabilities have been disproportionately affected and are among those who face the greatest risk of missing out further, even as the education system struggles to recover.

Dr Maha Shuayb, Director of the Centre for Lebanese Studies and a researcher at the University of Cambridge’s Faculty of Education: “The war has deepened learning losses that were already near-catastrophic. Whatever happens next, flexible, inclusive, multi-agency strategies are urgently needed to ensure education reaches those who need it most.”

“Without thorough response planning, existing inequalities will become more entrenched, leaving entire sections of the younger generation behind.”

The report is the second in a series examining the impact of war on education in the Middle East. The previous report, on Gaza, warned that conflict there could set children’s education back by several years.

REAL Centre Director Professor Pauline Rose said: “In Lebanon and Gaza, it is not only clear that violence, displacement and trauma are causing devastating learning losses; we also need a much more co-ordinated response. Education should not be an afterthought in times of crisis; it is vital to future stability.”

More than 1.3 million civilians have been displaced in Lebanon since Israel escalated its military operations. The new study was undertaken at the end of October, and involved a survey with 1,151 parents and teachers, supplemented with focus groups and interviews.

The authors calculate that by November, over 1 million students and 45,000 teachers had been directly affected by the conflict. About 40% of public (state-run) schools had been converted into shelters. A further 30% were in war zones, severely limiting space for schooling.

Lebanon’s Ministry of Education and Higher Education (MEHE) attempted to reopen  public schools on 4 November, but the study shows that for many people, violence, displacement and inadequate infrastructure impeded the resumption. Researchers found that 303 public schools were running in-person learning and 297 functioning online, but in conflict-hit regions like Baalbek-Hermel, the South, and Nabatiyyeh, barely any were physically open.

Many of the survey participants were living in shelters or overcrowded shared accommodation, where online learning – often the only option available – was difficult. Financial pressures, exacerbated by the war, have further disrupted education. 77% of parents and 66% of teachers said the conflict had reduced their incomes amid rising living costs.

While all teachers and parents wanted education to resume, the study therefore found that they were not universally prepared. Only 19% of teachers in areas heavily affected by the fighting, for example, considered restarting education a ‘high priority’. They also tended to prefer online learning, often for safety reasons, while those in less disrupted regions felt better prepared to resume education in-person.

Both parents and teachers highlighted the resource shortages hindering learning. Many lacked reliable internet, digital devices or even electricity. For example, only 62% of teachers and 49% of parents said they had an internet connection.

The report also highlights the extremely difficult experiences of Palestinian and Syrian refugee children and those with disabilities: groups that were disproportionately affected by systemic inequalities before the conflict began.

The authors estimate that as many as 5,000 children with disabilities could be out of school, with some parents reluctant to send children back due to a lack of inclusive provision. Refugee families, meanwhile, are among those who most urgently need food, shelter and financial help. Despite this, Syrian parents were statistically more likely to consider education a high priority. This may reflect concerns that they have been overlooked in MEHE’s plans.

Some families and teachers suggested the government’s November restart was proving chimerical. “The authorities claim that the school year has been launched successfully, but this isn’t reflective of reality,” one teacher said. “It feels more like a drive for revenue than a genuine commitment.”

MEHE’s attempts at a uniform strategy, the researchers stress, will not help everyone. “The focus has largely been on resuming schooling, with little attention paid to quality of learning," they write, adding that there is a need for a far more inclusive response plan, involving tailored strategies which reflect the different experiences of communities on the ground.

The report adds that this will require much closer collaboration between government agencies, NGOs, universities, and disability-focused organisations to address many of the problems raised by the analysis, such as financial instability, a lack of online learning infrastructure, and insufficient digital teaching capacity.

Even if the ceasefire holds, challenges remain. Many displaced families may not return home for weeks, while schools may still be used as shelters or require repairs. Temporary learning spaces, targeted infrastructure restoration, and trauma-informed approaches to helping children who need psychosocial learning recovery, will all be required.

Yusuf Sayed, Professor of Education, University of Cambridge said: “Everyone hopes that Lebanon will return to normality, but we have grave reservations about the quality, consistency and accessibility of education in the medium term. Addressing that requires better data collection and monitoring, a flexible plan and multi-agency support. Our working assumption should be that for more than a million children, this crisis is far from over.”

Israel-Hezbollah conflict has deepened an education crisis in which children have lost up to 60% of schooling in 6 years, study shows.

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Around a third (32%) of people who grew up in Chicago have carried a concealed firearm on the city streets at least once by the time they turn 40 years old, according to a major study of gun usage taking in a quarter of a century of data.

Urban sociologists behind the research argue that such carry rates are likely to be similar across many other major US cities. 

The research suggests that almost half of men (48%) have carried a concealed gun by the age of 40, compared to just 16% of women.*

The study, published in Science Advances, is one of the few to track gun usage in the same US population across decades, and reveals that two-thirds of those who carried a gun in the past year started doing so in adulthood, compared to only a third who began in adolescence.

The research also found that gun carrying in adolescence and adulthood may occur in response to different concerns. Those who started carrying in their teens often picked up a handgun in response to experiencing gun violence first-hand.** This was not true of those who began carrying over the age of 21.

“Among adolescents, we found a strong association between either witnessing a shooting or being shot, and beginning to carry soon after,” said Dr Charles Lanfear, study lead author from the University of Cambridge.

“The majority of people who ever carry a concealed handgun start doing so in adulthood. For those adults, we found no link between direct exposure to gun violence and gun carrying,” said Lanfear from Cambridge’s Institute of Criminology.

“This pattern suggests that gun carrying among adults may be linked to perceived threats of a more general nature, such as the idea that the world is a dangerous place, and police are incapable of ensuring public safety. Whereas gun carrying in adolescence may more often be related to direct experiences of gun violence.

“One simple but crucial fact is clear from our study, that carrying a concealed firearm is now a common event in the life course for Americans,” Lanfear said.

In the US between 1995 and 2021 some 89% of firearm homicides were committed with a handgun. However, despite the US gun stock doubling over the past quarter-century, and homicides spiking in COVID-era America, little is known about when and why people start carrying handguns.

The latest study was conducted by researchers from the University of Cambridge, University of Pennsylvania and Harvard University. Data was taken from a representative sample of 3,403 children originally from Chicago who were tracked over a 25-year period between 1994 and 2021.

When data-gathering began in the mid-90s, children were drawn at random from 80 of Chicago’s 343 neighbourhoods and from across the racial and socioeconomic spectrum, as part of a major longitudinal study run by Harvard.

The new analysis of this huge tranche of data reveals what researchers have called ‘dual pathways’ of concealed gun carrying: those who start in adolescence and those who start in adulthood, with the cut-off being the 21st birthday – the legal age for purchasing and carrying a handgun. 

In addition to findings on why people carry, the team discovered that most people who carry a gun in their teens do not continue in later life, with only 37% still carrying in 2021. Those who start carrying handguns in adulthood are more persistent, with 85% still taking a gun out in public in 2021.

Moreover, the use of guns – whether it be shooting someone, shooting at someone, or brandishing a gun in self-defence – differs among the 2 groups.

Teenage gun-carriers that fired or brandished their weapons all did so for the first time before adulthood. “We found that no one who began carrying a gun in adolescence ended up using it for the first time after the age of twenty-one,” said Lanfear.

Those who picked up a gun in adulthood had a relatively steady rate of first usage over time, so that by middle age (40 years old) both groups of carriers had reached almost identical levels of gun usage: with around 40% of carriers having used a gun.

Researchers found a racial component to gun-carrying. Black individuals carried at rates over 2 times as great as those of Hispanic and white individuals. However, a previous study by the same team showed that Black city residents were twice as likely as White residents to witness a shooting by age 40.

In fact, the research found that those least likely to witness gun violence – White residents – are the most likely to start carrying a firearm in response to gun violence exposure.

While all self-described gun-carriers – whether they started in adolescence or adulthood –are more likely to have an arrest history compared to those who don’t carry guns, the researchers say their study reveals ‘stark’ differences in why and when and for how long people take guns onto the streets.

Added Lanfear: “These findings take on new relevance given recent social changes in America. In 2020 and 2021 the nation saw a sharp increase in adult gun carrying, coinciding with an uptick in gun purchases following the outbreak of COVID-19 and the murder of George Floyd. We found the same trends in adult gun-carrying among our study sample.”

Major 25-year study reveals a ‘dual pathway’ for when people start carrying.

* The researchers found female gun-carrying to be uncommon. However, they detected a rapid increase in some cohorts at the age of 35, but these increases all occurred during the first year of COVID-19 (2020). Researchers say this is consistent with other research finding large COVID-era increases in gun ownership among groups with historically lower rates of ownership.

**Exposure to gun violence before age 15 is associated with a doubling in the probability of carrying a concealed gun between ages 15 and 21. Around 44% of adolescent gun carriers started carrying after being exposed to gun violence. In contrast, exposure to gun violence at an older age is not statistically or substantively associated with gun-carrying. Direct exposure to gun violence after age 21 is far less frequent than during adolescence.

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This year’s Wolfson History Prize has been awarded to Joya Chatterji, Emeritus Professor of South Asian History and Fellow of Trinity College, for her book Shadows At Noon: The South Asian Twentieth Century, first published in 2023.

The book charts the story of the subcontinent from the British Raj through independence and partition to the forging of the modern nations of India, Pakistan and Bangladesh.

Chatterji’s history pushes back against standard narratives that emphasise differences between the 3 countries, and instead seeks to highlight what unites these nations and their peoples.

Interwoven with Chatterji’s personal reflections on growing up in India, this distinctive academic work uses a conversational writing style and takes a thematic rather than chronological approach. It adds to the discussions of politics and nationhood typical of other histories of the region by weaving in everyday experiences of food, cinema, and domestic life.

As a result, the cultural vibrancy of South Asia shines through the research, according to the Wolfson History Prize judges, allowing readers a more nuanced understanding of South Asian history.

A judging panel that included fellow Cambridge historians Professors Mary Beard and Richard Evans, and headed by panel chair Professor David Cannadine, described Chatterji’s book as “written with verve and energy”, and said that it “beautifully blends the personal and the historical”.

“Shadows at Noon is a highly ambitious history of 20th-century South Asia that defies easy categorisation, combining rigorous historical research with personal reminiscence and family anecdotes,” said Cannadine.  

“Chatterji writes with wit and perception, shining a light on themes that have shaped the subcontinent during this period. We extend our warmest congratulations to Joya Chatterji on her Wolfson History Prize win.”

“For over 50 years, the Wolfson History Prize has celebrated exceptional history writing that is rooted in meticulous research with engaging and accessible prose,” said Paul Ramsbottom, Chief Executive of the Wolfson Foundation.

“Shadows at Noon is a remarkable example of this, and Joya Chatterji captivates readers with her compelling storytelling of modern South Asian history.”

Shadows at Noon was also longlisted for the Women’s Prize for Non-Fiction 2024 and shortlisted for the Cundill History Prize 2024.

Now in its 52nd year, the Wolfson History Prize celebrates books that combine excellence in research with readability for a general audience.

Recent winners have included other Cambridge historians: Clare Jackson, Honorary Professor of Early Modern History, for Devil-Land: England Under Siege, 1588-1688 (2022) and David Abulafia, Professor Emeritus of Mediterranean History, for The Boundless Sea: A Human History of the Oceans (2020). Helen McCarthy, Professor of Modern and Contemporary British History, was shortlisted for Double Lives: A History of Working Motherhood in 2021.

Chatterji wins for Shadows at Noon, her genre-defying history of South Asia during the 20th century.

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The initiative, called Polymathic AI, uses technology like that powering large language models such as OpenAI’s ChatGPT or Google’s Gemini. But instead of ingesting text, the project’s models learn using scientific datasets from across astrophysics, biology, acoustics, chemistry, fluid dynamics and more, essentially giving the models cross-disciplinary scientific knowledge.

“These datasets are by far the most diverse large-scale collections of high-quality data for machine learning training ever assembled for these fields,” said team member Michael McCabe from the Flatiron Institute in New York City. “Curating these datasets is a critical step in creating multidisciplinary AI models that will enable new discoveries about our universe.”

On 2 December, the Polymathic AI team released two of its open-source training dataset collections to the public — a colossal 115 terabytes, from dozens of sources — for the scientific community to use to train AI models and enable new scientific discoveries. For comparison, GPT-3 used 45 terabytes of uncompressed, unformatted text for training, which ended up being around 0.5 terabytes after filtering.

The full datasets are available to download for free on HuggingFace, a platform hosting AI models and datasets. The Polymathic AI team provides further information about the datasets in two papers accepted for presentation at the NeurIPS machine learning conference, to be held later this month in Vancouver, Canada.

“Just as LLMs such as ChatGPT learn to use common grammatical structure across languages, these new scientific foundation models might reveal deep connections across disciplines that we’ve never noticed before,” said Cambridge team lead Dr Miles Cranmer from Cambridge’s Institute of Astronomy. “We might uncover patterns that no human can see, simply because no one has ever had both this breadth of scientific knowledge and the ability to compress it into a single framework.”

AI tools such as machine learning are increasingly common in scientific research, and were recognised in two of this year’s Nobel Prizes. Still, such tools are typically purpose-built for a specific application and trained using data from that field. The Polymathic AI project instead aims to develop models that are truly polymathic, like people whose expert knowledge spans multiple areas. The project’s team reflects intellectual diversity, with physicists, astrophysicists, mathematicians, computer scientists and neuroscientists.

The first of the two new training dataset collections focuses on astrophysics. Dubbed the Multimodal Universe, the dataset contains hundreds of millions of astronomical observations and measurements, such as portraits of galaxies taken by NASA’s James Webb Space Telescope and measurements of our galaxy’s stars made by the European Space Agency’s Gaia spacecraft.

The other collection — called the Well — comprises over 15 terabytes of data from 16 diverse datasets. These datasets contain numerical simulations of biological systems, fluid dynamics, acoustic scattering, supernova explosions and other complicated processes. Cambridge researchers played a major role in developing both dataset collections, working alongside PolymathicAI and other international collaborators.

While these diverse datasets may seem disconnected at first, they all require the modelling of mathematical equations called partial differential equations. Such equations pop up in problems related to everything from quantum mechanics to embryo development and can be incredibly difficult to solve, even for supercomputers. One of the goals of the Well is to enable AI models to churn out approximate solutions to these equations quickly and accurately.

“By uniting these rich datasets, we can drive advancements in artificial intelligence not only for scientific discovery, but also for addressing similar problems in everyday life,” said Ben Boyd, PhD student in the Institute of Astronomy.

Gathering the data for those datasets posed a challenge, said team member Ruben Ohana from the Flatiron Institute. The team collaborated with scientists to gather and create data for the project. “The creators of numerical simulations are sometimes sceptical of machine learning because of all the hype, but they’re curious about it and how it can benefit their research and accelerate scientific discovery,” he said.

The Polymathic AI team is now using the datasets to train AI models. In the coming months, they will deploy these models on various tasks to see how successful these well-rounded, well-trained AIs are at tackling complex scientific problems.

“It will be exciting to see if the complexity of these datasets can push AI models to go beyond merely recognising patterns, encouraging them to reason and generalise across scientific domains,” said Dr Payel Mukhopadhyay from the Institute of Astronomy. “Such generalisation is essential if we ever want to build AI models that can truly assist in conducting meaningful science.”

“Until now, haven’t had a curated scientific-quality dataset cover such a wide variety of fields,” said Cranmer, who is also a member of Cambridge’s Department of Applied Mathematics and Theoretical Physics. “These datasets are opening the door to true generalist scientific foundation models for the first time. What new scientific principles might we discover? We're about to find out, and that's incredibly exciting.”

The Polymathic AI project is run by researchers from the Simons Foundation and its Flatiron Institute, New York University, the University of Cambridge, Princeton University, the French Centre National de la Recherche Scientifique and the Lawrence Berkeley National Laboratory.

Members of the Polymathic AI team from the University of Cambridge include PhD students, postdoctoral researchers and faculty across four departments: the Department of Applied Mathematics and Theoretical Physics, the Department of Pure Mathematics and Mathematical Statistics, the Institute of Astronomy and the Kavli Institute for Cosmology.

What can exploding stars teach us about how blood flows through an artery? Or swimming bacteria about how the ocean’s layers mix? A collaboration of researchers, including from the University of Cambridge, has reached a milestone toward training artificial intelligence models to find and use transferable knowledge between fields to drive scientific discovery.

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Lindsay’s appointment comes at a critical moment for the sustainability movement and for CISL. 

Following another year of record temperatures, extreme weather events and sustained biodiversity loss, the evidence is clear that the world is not on track. Confidence within the sustainability movement has faltered and big questions are being asked about what is needed to deliver the change we need. Under Lindsay’s leadership as interim CEO the Institute has engaged with these important questions. Read more about Lindsay Hooper's appointment here

The University of Cambridge Institute for Sustainability Leadership announces it has appointed Lindsay Hooper its permanent CEO and Head of Department.

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In June 1913, 3 candidates in the UK took the first ever Cambridge English exam. Since then, Cambridge English exams have become available in 130 countries and are recognised by more than 25,000 organisations around the world, including governments, universities and employers, as reliable proof of English language ability.

The Cambridge English exams, which are designed for all levels of English language ability, include Cambridge English Qualifications, Linguaskill and IELTS, the English language test.

Read more on the Cambridge University Press & Assessment website.

100 million Cambridge English exams and tests have been taken around the world since 1913, according to figures from Cambridge University Press & Assessment.

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Even if global production and pollution of new plastic is drastically reduced, scientists, writing in the journal Nature Communications, say that legacy plastics, the billions of tonnes of waste already in the environment, will continue to break down into tiny particles called microplastics for decades or centuries.

These fragments contaminate oceans, land, and the air we breathe, posing risks to marine life, food production and human health.

The researchers – from the University of Cambridge, GNS Science in New Zealand and The Ocean Cleanup in The Netherlands – say the problem lies in a gap between ambition and action, called the fragmentation gap.

At a meeting this week in Busan, South Korea, the Intergovernmental Negotiating Committee on Plastic Pollution is meeting to finalise the Global Plastics Treaty, the first legally binding treaty to tackle plastic pollution.

While the treaty’s initial discussions highlight prevention of plastic pollution, the researchers say it largely overlooks the need to remove existing waste. This omission means microplastics will continue to accumulate, even if plastic pollution slows.

“The treaty is aiming to eliminate plastic pollution by 2040, but this goal is unlikely without stronger action,” said co-author Zhenna Azimrayat-Andrews, a PhD student at Cambridge’s Department of Earth Sciences. “Even with a sharp reduction in plastic entering the ocean, existing debris will split into smaller pieces and persist for centuries.”

These microplastics have already infiltrated marine ecosystems and are harming marine ecosystems, degrading commercial seafood quality, and disrupting critical ocean processes.

The researchers argue that plastic clean-up efforts must be prioritised alongside reduction targets. Strategies to remove plastics from terrestrial and marine environments, such as those targeting pollution in beaches and rivers, could help prevent microplastics from forming. In fact, a 3% annual removal of legacy plastic, combined with aggressive reduction measures, could significantly curb future contamination, they say.

Without action to address legacy plastic, the treaty risks leaving behind a long-lasting problem for marine life and future generations. Experts are calling for clean-up efforts to become an equal pillar of the treaty, alongside prevention and recycling.

As world leaders gather to negotiate the treaty this week, the spotlight is on their ability to craft a comprehensive plan that doesn't just slow pollution but also begins to reverse the damage that has already been done.

Reference:
Karin Kvale, Zhenna Azimrayat Andrews & Matthias Egger. ‘Mind the fragmentation gap.’ Nature Communications (2024). DOI: 10.1038/s41467-024-53962-3

As the UN meets this week to finalise the Global Plastics Treaty, researchers warn that the agreement could fail to address one of the biggest threats to marine environments—microplastics.

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The Department of Archaeology and McDonald Institute for Archaeological Research at the University of Cambridge mourn the death and celebrate the extraordinary life of Professor Colin Renfrew, Lord Renfrew of Kaimsthorn, formerly tenth Disney Professor of Archaeology, the McDonald’s founding Director, and Master of Jesus College.

Colin was, and will always remain, one of the titans of modern archaeology, a distinguished public figure, and a fine friend and colleague to innumerable archaeologists around the world. This loss makes the world of archaeology a poorer place intellectually, as well as in terms of the sheer energy and optimism that he brought to everything he did.

From his first years as one of the brave new archaeologists of the 1960s, Colin stood out as an exceptional mind, and as a spirit of profound, exciting and rigorous change. He pioneered new, theoretically informed ways of thinking about the explanation of social and political change in the past, within and then far beyond his first enduring regional love for the prehistoric Aegean, while advocating scientific techniques of dating and provenance as an integral part of archaeological endeavour. From this perspective, he was one of the first to appreciate the significance of the calibration of radiocarbon dates for the understanding of European prehistory. 

He went on to ask equally fresh questions about the link between language evolution and archaeology and, as the first Director of the McDonald Institute for Archaeological Research, championed some of the earliest applications of archaeogenetics, as well as a critical and investigative approach to the illicit antiquities market. His fieldwork expanded to Orkney, and latterly returned to the more southerly isles of the Cyclades, subject of his doctoral research, and to remarkable discoveries on the island of Keros. To the very end, he remained engaged with the forefront of archaeological developments, attending and clearly relishing the 36th Annual McDonald Lecture on the Wednesday before he left us.

As those who knew him will amply testify, there was far, far more to Colin than the world-leading and much honoured archaeologist. He took on the mantle of a working peer in the House of Lords, where he spoke up for matters of heritage and archaeological legislation with the customary eloquence and lapidary reasoning of a one-time President of the Cambridge Union.

He was a passionate and knowledgeable expert and collector of modern art, by which Jesus College under his care remains permanently graced. Social events under his hospitality became unforgettable and often hugely convivial gatherings of brilliant minds from the widespread fields that he drew together, and under the right circumstances often culminated in demonstrations of Colin’s skills as a dancer. Last but far from least, he was a much-loved husband to his wife Jane, and father to Helena, Alban and Magnus.

Colin passed away peacefully in his sleep during the night of Saturday 23 to Sunday 24 November 2024. All of us at Cambridge extend our heartfelt condolences and profound respects to his family and to all those who loved and knew him.

Professor Cyprian Broodbank remembers Professor Lord Colin Renfrew, founding Director of the McDonald Institute for Archaeological Research and former Master of Jesus College, who passed away at the weekend aged 87.  

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Remotely operated camera traps, sound recorders and drones are increasingly being used in conservation science to monitor wildlife and natural habitats, and to keep watch on protected natural areas.

But Cambridge researchers studying a forest in northern India have found that the technologies are being deliberately misused by local government and male villagers to keep watch on women without their consent.

Cambridge researcher Dr Trishant Simlai spent 14 months interviewing 270 locals living around the Corbett Tiger Reserve, a national park in northern India, including many women from nearby villages.

His report, published today in the journal Environment and Planning F, reveals how forest rangers in the national park deliberately fly drones over local women to frighten them out of the forest, and stop them collecting natural resources despite it being their legal right to do so.

The women, who previously found sanctuary in the forest away from their male-dominated villages, told Simlai they feel watched and inhibited by camera traps, so talk and sing much more quietly. This increases the chance of surprise encounters with potentially dangerous wildlife like elephants and tigers. One woman he interviewed has since been killed in a tiger attack.

The study reveals a worst-case scenario of deliberate human monitoring and intimidation. But the researchers say people are being unintentionally recorded by wildlife monitoring devices without their knowledge in many other places - even national parks in the UK. 

“Nobody could have realised that camera traps put in the Indian forest to monitor mammals actually have a profoundly negative impact on the mental health of local women who use these spaces,” said Dr Trishant Simlai, a researcher in the University of Cambridge’s Department of Sociology and lead author of the report.

“These findings have caused quite a stir amongst the conservation community. It’s very common for projects to use these technologies to monitor wildlife, but this highlights that we really need to be sure they’re not causing unintended harm,” said Professor Chris Sandbrook, Director of the University of Cambridge’s Masters in Conservation Leadership programme, who was also involved in the report.

He added: “Surveillance technologies that are supposed to be tracking animals can easily be used to watch people instead – invading their privacy and altering the way they behave.”

Many areas of conservation importance overlap with areas of human use. The researchers call for conservationists to think carefully about the social implications of using remote monitoring technologies – and whether less invasive methods like surveys could provide the information they need instead.

Intimidation and deliberate humiliation

The women living near India’s Corbett Tiger Reserve use the forest daily in ways that are central to their lives: from gathering firewood and herbs to sharing life’s difficulties through traditional songs.

Domestic violence and alcoholism are widespread problems in this rural region and many women spend long hours in forest spaces to escape difficult home situations.

The women told Simlai that new technologies, deployed under the guise of wildlife monitoring projects, are being used to intimidate and exert power over them - by monitoring them too. 

“A photograph of a woman going to the toilet in the forest – captured on a camera trap supposedly for wildlife monitoring - was circulated on local Facebook and WhatsApp groups as a means of deliberate harassment,” said Simlai. 

He added: “I discovered that local women form strong bonds while working together in the forest, and they sing while collecting firewood to deter attacks by elephants and tigers. When they see camera traps they feel inhibited because they don’t know who’s watching or listening to them – and as a result they behave differently - often being much quieter, which puts them in danger.”

In places like northern India, the identity of local women is closely linked to their daily activities and social roles within the forest. The researchers say that understanding the various ways local women use forests is vital for effective forest management strategies.

Reference: Simlai, T. et al: ‘The Gendered Forest: Digital Surveillance Technologies for Conservation and Gender-Environment relationships.’ November 2024. DOI:10.17863/CAM.111664
 

Camera traps and drones deployed by government authorities to monitor a forest in India are infringing on the privacy and rights of local women.

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Fry brings outstanding experience to the role of communicating to diverse audiences, including with people not previously interested in maths. She will follow in the footsteps of giants of public engagement with mathematics, including David Spiegelhalter and the late Stephen Hawking as she joins the Department of Applied Mathematics and Theoretical Physics (DAMTP).

“I’m really looking forward to joining the Cambridge community,” said Fry, “to those chance encounters and interactions that end up sparking new ideas and collaborations: it’s so exciting to be in an environment where every single person you speak to is working on something absolutely fascinating.”

Fry won the Christopher Zeeman Medal for promoting mathematics in 2018 and the Royal Society David Attenborough Award in 2024, and is the current President of the Institute of Mathematics and its Applications.

She is currently Professor of the Mathematics of Cities at UCL, where she works with physicists, mathematicians, computer scientists, architects and geographers to study patterns in human behaviour – particularly in an urban setting. Her research applies to a wide range of social problems and questions, from shopping and transport to urban crime, riots and terrorism, and she has applied this research by advising and working alongside governments, police forces, supermarkets and health analysts.

“When you create a mathematical model, it doesn’t really matter how beautifully crafted your equations are, or how accurate your simulations are,” said Fry. “You have to think about how the work you’ve created is going to be seen and perceived by other people and how it’s going to be understood or misunderstood.”

The new professorship builds on Cambridge’s long track record in sharing maths. DAMTP is also the home of the largest subject-specific outreach and engagement project in the University – the Millennium Mathematics Project (MMP).

Fry says she plans for her work at Cambridge to follow on from Spiegelhalter's extensive public communication work, which she sees as a vital part of the research process.

“Communication is not an optional extra: if you are creating something that is used by, or interacts with members of the public or the world in general, then I think it’s genuinely your moral duty to engage the people affected by it,” she said. “I’d love to build and grow a community around excellence in mathematical communication at Cambridge – so that we’re really researching the best possible methods to communicate with people.”

“Hannah is an outstanding mathematician and researcher, and one of the UK’s best maths communicators,” said Professor Colm-cille Caulfield, Head of DAMTP. “Mathematics affects so many aspects of our everyday lives in interesting and exciting ways, and Hannah will strengthen the excellent work already being done at Cambridge in this area. We in DAMTP and our Faculty of Mathematics colleagues in the Department of Pure Mathematics and Mathematical Statistics are so excited to have her join us.”

Professor Fry announced her appointment at an event yesterday (21 November) organised by the MMP in collaboration with the Newton Gateway to Mathematics at the Isaac Newton Institute in Cambridge. The event – Communicating mathematical and data sciences – what does success look like? – explored evidence for effectively communicating mathematical and data science research to policymakers, mainstream media and the wider public.

“Professor Fry is one of the most exciting voices in science and mathematics today,” said Professor Nigel Peake, Head of the School of the Physical Sciences. “Her deep commitment to sharing the excitement of maths with people of all ages and backgrounds, at a time when mathematical literacy has never been so important, will be an enormous benefit to Cambridge, and the UK as a whole.”

Professor Hannah Fry, mathematician, best-selling author, award-winning science presenter and host of popular podcasts and television shows, will join the University of Cambridge as the first Professor of the Public Understanding of Mathematics on 1 January.

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The first three students to be supported by the Arm donation will begin their studies at the new research centre in the autumn of 2025. They will be followed by another three students each year for the following four years.  

Arm – the company building the future of computing with its global headquarters in Cambridge – is the first organisation to donate to the new CASCADE Research Centre, part of the Department of Computer Science and Technology.

“We’re very grateful to them for their generous support,” said Professor Timothy Jones, Director of the Centre. “As well as funding 15 PhD students over the next five years, Arm’s involvement is helping us realise our vision of a centre where research into addressing key challenges in this field is informed and supported by our industrial partners.This is extremely valuable to us as we work to make the Centre a destination for collaboration between companies, generating pre-competitive open-source artefacts and driving development of novel computer architectures.”

Richard Grisenthwaite, executive vice president and chief architect, Arm said: “Our long-standing commitment to the University of Cambridge through this latest CASCADE funding highlights the vital collaboration between academia and industry as we embark on ground-breaking intent-based programming work to realize the future promise of AI through the next generation of processor designs."

“The Centre has the potential to enable further technology innovation within the semiconductor industry and is an important part of Arm’s mission to build the future of computing.” 

Jones added: "Computer architecture is a critical area of computing. It underpins today’s technologies and drives the next generation of computing systems. Here in the Department of Computer Science and Technology, we’re proud of our research and innovation in this area. And the recently published National Semiconductor Strategy underlined how vital such work is, showing that the UK is currently a leader in computer architecture."

"But to maintain this leading position, we need to invest in developing the research leaders of tomorrow. That's why we have established the new CASCADE Research Centre to fund PhD students working in this area, through support from industry. It is currently taking applications for its first cohort of students."

The Centre will focus on research that addresses some of the grand challenges in computer architecture, design automation and semiconductors.  

PhD students will work alongside researchers here who have expertise across the breadth of the area, encompassing the design and optimisation of general-purpose microprocessors, specialised accelerators, on-chip interconnect and memory systems, verification, compilation and networking, quantum architecture and resource estimation. This will allow them to explore the areas they are most passionate about, while addressing industry-relevant research.

Students receiving funding from Arm will be working in the general area of intent-based computing, researching systems that communicate what programs will do in the future so that the processor can make better decisions about how to execute them.

Arm was born in Cambridge in 1990 with the goal of changing the computing landscape. Its success since then in designing, architecting, and licensing high-performance, power-efficient CPUs — the 'brain' of all computers and many household and electronic devices — helped fuel the smartphone revolution and has made it a household name.

Arm has long had a research relationship with Cambridge University. Most notably, this has led to the development of new cybersecurity technology, focusing on innovative ways to design the architecture of a computer’s CPU to make software less vulnerable to security breaches.

Adapted from a news release published by the Department of Computer Science and Technology

Arm is donating £3.5 million to enable 15 PhD students over the next five years to study at CASCADE, the University's new Computer Architecture and Semiconductor Design Centre.

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‘Manifest’ was looked up almost 130,000 times on the Cambridge Dictionary website, making it one of the most-viewed words of 2024.  

The word jumped from use in the self-help community and on social media to being widely used across mainstream media and beyond, as celebrities such as singer Dua Lipa, Olympic sprinter Gabby Thomas and England striker Ollie Watkins spoke of manifesting their success in 2024. 

Mentions of it gained traction during the pandemic and have grown in the years since, especially on TikTok and other social media, where millions of posts and videos used the hashtag #manifest.

They use ‘to manifest’ in the sense of: ‘to imagine achieving something you want, in the belief that doing so will make it more likely to happen’. Yet, manifesting is an unproven idea that grew out of a 100-year-old spiritual philosophy movement.

Wendalyn Nichols, Publishing Manager of the Cambridge Dictionary, said: “When we choose a Cambridge Dictionary Word of the Year, we have three considerations: What word was looked up the most, or spiked? Which one really captures what was happening in that year? And what is interesting about this word from a language point of view?

“‘Manifest’ won this year because it increased notably in lookups, its use widened greatly across all types of media due to events in 2024, and it shows how the meanings of a word can change over time.”

However experts warn that ‘manifesting’ has no scientific validity, despite its popularity. It can lead to risky behaviour or the promotion of false and dangerous beliefs, such as that diseases can be simply wished away.

“Manifesting is what psychologists call ‘magical thinking’ or the general illusion that specific mental rituals can change the world around us," said Cambridge University social psychologist Professor Sander van der Linden, author of The Psychology of Misinformation.

“Manifesting gained tremendous popularity during the pandemic on TikTok with billions of views, including the popular 3-6-9 method which calls for writing down your wishes three times in the morning, six times in the afternoon and nine times before bed. This procedure promotes obsessive and compulsive behaviour with no discernible benefits. But can we really blame people for trying it, when prominent celebrities have been openly ‘manifesting’ their success?

‘Manifesting’ wealth, love, and power can lead to unrealistic expectations and disappointment. Think of the dangerous idea that you can cure serious diseases simply by wishing them away," said Van der Linden.

“There is good research on the value of positive thinking, self-affirmation, and goal-setting. Believing in yourself, bringing a positive attitude, setting realistic goals, and putting in the effort pays off because people are enacting change in the real world. However, it is crucial to understand the difference between the power of positive thinking and moving reality with your mind – the former is healthy, whereas the latter is pseudoscience.” 

‘Manyfest’, manifest destiny, and manifestos

The 600-year history of the word ‘manifest’ shows how the meanings of a word can evolve.

The oldest sense – which Geoffrey Chaucer spelled as ‘manyfest’ in the 14th century – is the adjective meaning ‘easily noticed or obvious’.

In the mid-1800s, this adjective sense was used in American politics in the context of “manifest destiny”, the belief that American settlers were clearly destined to expand across North America.

Chaucer also used the oldest sense of the verb ‘manifest’, ‘to show something clearly, through signs or actions’. Shakespeare used manifest as an adjective in The Merchant of Venice: ‘For it appears, by manifest proceeding, that...thou hast contrived against the very life of the defendant’.

The verb is still used frequently in this way: for example, people can manifest their dissatisfaction, or symptoms of an illness can manifest themselves. Lack of confidence in a company can manifest itself through a fall in share price.

The meaning of making something clear is reflected in the related noun 'manifesto': a ‘written statement of the beliefs, aims, and policies of an organisation, especially a political party’ – a word that also resonated in 2024 as scores of nations, including the United Kingdom and India, held elections where parties shared manifestos.

Other words of 2024

The Cambridge Dictionary is the world’s most popular dictionary for learners of the English language. Increases and spikes in lookups reflect global events and trends. Beyond “manifest”, other popular terms in 2024 included: 

brat: a child, especially one who behaves badly

“Brat” went viral in the summer of 2024 thanks to pop artist Charli XCX’s album of the same name about nonconformist women who reject a narrow and highly groomed female identity as portrayed on social media. (We weren’t the only dictionary publisher to notice this.) 

demure: quiet and well behaved 

Influencer Jools Lebron’s satirical use of “demure” in a TikTok post mocking stereotypical femininity drove lookups in the Cambridge Dictionary.  After brat summer, we had a demure fall. 

Goldilocks: used to describe a situation in which something is or has to be exactly right  

Financial reporters characterized India’s strong growth and moderate inflation as a Goldilocks economy in early 2024.  

ecotarian: a person who only eats food produced or prepared in a way that does not harm the environment  

This term rose in overall lookups in 2024, reflecting growing interest in environmentally conscious living.  

New words, future entries?   

All year round, Cambridge Dictionary editors track the English language as it changes. Newly emerging words that are being considered for entry are shared every Monday on the Cambridge Dictionary blog, About Words. 

Words Cambridge began tracking in 2024 include: 

quishing: the scam of phishing via QR code. 

resenteeism: to continue doing your job but resent it. This blend of “resent” and “absenteeism” is appearing in business journalism.  

gymfluencer: a social media influencer whose content is focused on fitness or bodybuilding. 

cocktail party problem (also cocktail party effect): the difficulty of focusing on one voice when there are multiple speakers in the room. This term from audiology is now being used with reference to AI. 

vampire: a vampire device or vampire appliance is one which uses energy even when not in use. This is a new, adjective sense of an existing word.  

Adapted from the Cambridge University Press & Assessment website. 

The controversial global trend of manifesting has driven Cambridge Dictionary’s Word of the Year for 2024.

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People from Belfast proved most able to detect someone faking their accent, while people from London, Essex and Bristol were least accurate.

The study, published today in Evolutionary Human Sciences found that the ability of participants from Scotland, the north-east of England, Ireland and Northern Ireland to tell whether short recordings of their native accent were real or fake ranged from approximately 65% – 85%. By contrast, for Essex, London and Bristol, success ranged from just over 50%, barely better than chance, to 65% –75%.

In the biggest study of its kind, drawing on 12,000 responses, the researchers found that participants across all groups were better than chance at detecting fake accents, succeeding just over 60% of the time. Unsurprisingly, participants who spoke naturally in the test accent tended to detect more accurately than non-native listener groups – some of which performed worse than chance – but success varied between regions.

“We found a pretty pronounced difference in accent cheater detection between these areas,” said corresponding author Dr Jonathan R Goodman, from Cambridge’s Department of Archaeology, and Cambridge Public Health.

“We think that the ability to detect fake accents is linked to an area’s cultural homogeneity, the degree to which its people hold similar cultural values.”

The researchers argue that the accents of speakers from Belfast, Glasgow, Dublin, and north-east England have culturally evolved over the past several centuries, during which there have been multiple cases of between-group cultural tension, particularly involving the cultural group making up southeast England, above all London.

This, they suggest, probably caused individuals from areas in Ireland and the northern regions of the United Kingdom to place emphasis on their accents as signals of social identity.

The study argues that greater social cohesion in Belfast, Dublin, Glasgow and the north-east may have resulted in a more prominent fear of cultural dilution by outsiders, which would have encouraged the development of improved accent recognition and mimicry detection.

People from London and Essex proved least able to spot fake accents because, the study suggests, these areas have less strong ‘cultural group boundaries’ and people are more used to hearing different kinds of accents, which could make them less attuned to accent fakery.

The study points out that many speakers of the Essex accent only moved to the area over the past 25 years from London, whereas the accents of people living in Belfast, Glasgow and Dublin have ‘evolved over centuries of cultural tension and violence.’

Some might have expected Bristolians to authenticate recordings of their accent more accurately, but Goodman points out that “cultural heterogeneity has been increasing significantly in the city”. The researchers would also like to obtain more data for Bristol.

An evolved ability

Previous research has shown that when people want to demarcate themselves for cultural reasons, their accents become stronger. In human evolution, the ability to recognise and thwart ‘free riders’ is also thought to have been pivotal in the development of large-scale societies.

Dr Goodman said: “Cultural, political, or even violent conflict are likely to encourage people to strengthen their accents as they try to maintain social cohesion through cultural homogeneity. Even relatively mild tension, for example the intrusion of tourists in the summer, could have this effect.

“I'm interested in the role played by trust in society and how trust forms. One of the first judgments a person will make about another person, and when deciding whether to trust them, is how they speak. How humans learn to trust another person who may be an interloper has been incredibly important over our evolutionary history and it remains critical today.”

Overall, the study found that participants were better than chance at detecting fake accents but is it surprising that so many people failed 40–50% of the time?

The authors point out that participants were only given 2-3 second clips so the fact that some authenticated with 70–85% accuracy is very impressive. If participants had heard a longer clip or been able to interact with someone face-to-face, the researchers would expect success rates to rise but continue to vary by region.

How the tests worked

The researchers constructed a series of sentences designed to elicit phonetic variables distinguishing between 7 accents of interest: north-east England, Belfast, Dublin, Bristol, Glasgow, Essex, and Received Pronunciation (RP), commonly understood as standard British English. The researchers chose these accents to ensure a high number of contrasting phonemes between sentences.

Test sentences included: ‘Hold up those two cooked tea bags’; ‘She kicked the goose hard with her foot’; ‘He thought a bath would make him happy’; ‘Jenny told him to face up to his weight’; and ‘Kit strutted across the room’.

The team initially recruited around 50 participants who spoke in these accents and asked them to record themselves reading the sentences in their natural accent. The same participants were then asked to mimic sentences in the other six accents in which they did not naturally speak, chosen randomly. Females mimicked females, males mimicked males. The researchers selected recordings which they judged came closest to the accents in question based on the reproduction of key phonetic variables.

Finally, the same participants were asked to listen to recordings made by other participants of their own accents, of both genders. Therefore, Belfast accent speakers heard and judged recordings made by native Belfast speakers as well as recordings of fake Belfast accents made by non-native speakers.

Participants were then asked to determine whether the recordings were authentic. All participants were asked to determine whether the speaker was an accent-mimic for each of 12 recordings (six mimics and six genuine speakers, presented in random order). The researchers obtained 618 responses.

In a second phase, the researchers recruited over 900 participants from the United Kingdom and Ireland, regardless of which accent they spoke naturally. This created a control group for comparison and increased the native speaker sample sizes. In the second phase, the researchers collected 11,672 responses.

“The UK is a really interesting place to study,” Dr Goodman said. “The linguistic diversity and cultural history is so rich and you have so many cultural groups that have been roughly in the same location for a really long time. Very specific differences in language, dialect and accents have emerged over time, and that's a fascinating side of language evolution.”

Reference

JR Goodman et al., ‘Evidence that cultural groups differ in their abilities to detect fake accents’, Evolutionary Human Sciences (2024). DOI: 10.1017/ehs.2024.36

People from Glasgow, Belfast, Dublin and the north-east of England are better at detecting someone imitating their accent than people from London and Essex, new research has found.

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Appearing as ‘bumps’ in the data from high-energy experiments, these signals came to be known as short-lived ‘XYZ states.’ They defy the standard picture of particle behaviour and are a problem in contemporary physics, sparking several attempts to understand their mysterious nature.

But theorists at the U.S. Department of Energy’s Thomas Jefferson National Accelerator Facility in Virginia, with colleagues from the University of Cambridge, suggest the experimental data could be explained with fewer XYZ states, also called resonances, than currently claimed.

The team used a branch of quantum physics to compute the energy levels, or mass, of particles containing a specific ‘flavour’ of the subatomic building blocks known as quarks. Quarks, along with gluons, a force-carrying particle, make up the Strong Force, one of the four fundamental forces of nature.

The researchers found that multiple particle states sharing the same degree of spin – or angular momentum – are coupled, meaning only a single resonance exists at each spin channel. This new interpretation is contrary to several other theoretical and experimental studies.

The researchers have presented their results in a pair of companion papers published for the international Hadron Spectrum Collaboration (HadSpec) in Physical Review Letters and Physical Review D. The work could also provide clues about an enigmatic particle: X(3872).

The charm quark, one of six quark ‘flavours’, was first observed experimentally in 1974. It was discovered alongside its antimatter counterpart, the anticharm, and particles paired this way are part of an energy region called ‘charmonium.’

In 2003, Japanese researchers discovered a new charmonium candidate dubbed X(3872): a short-lived particle state that appears to defy the present quark model.

“X(3872) is now more than 20 years old, and we still haven’t obtained a clear, simple explanation that everyone can get behind,” said lead author Dr David Wilson from Cambridge’s Department of Applied Mathematics and Theoretical Physics (DAMTP).

Thanks to the power of modern particle accelerators, scientists have detected a hodgepodge of exotic charmonium candidate states over the past two decades.

“High-energy experiments started seeing bumps, interpreted as new particles, almost everywhere they looked,” said co-author Professor Jozef Dudek from William & Mary. “And very few of these states agreed with the model that came before.”

But now, by creating a tiny virtual ‘box’ to simulate quark behaviour, the researchers discovered that several supposed XYZ particles might actually be just one particle seen in different ways. This could help simplify the confusing jumble of data scientists have collected over the years.

Despite the tiny volumes they were working with, the team required enormous computing power to simulate all the possible behaviours and masses of quarks.

The researchers used supercomputers at Cambridge and the Jefferson Lab to infer all the possible ways in which mesons – made of a quark and its antimatter counterpart – could decay. To do this, they had to relate the results from their tiny virtual box to what would happen in a nearly infinite volume – that is, the size of the universe.

“In our calculations, unlike experiment, you can't just fire in two particles and measure two particles coming out,” said Wilson. “You have to simultaneously calculate all possible final states, because quantum mechanics will find those for you.”

The results can be understood in terms of just a single short-lived particle whose appearance could differ depending upon which possible decay state it is observed in.

“We're trying to simplify the picture as much as possible, using fundamental theory with the best methods available,” said Wilson. “Our goal is to disentangle what has been seen in experiments.”

Now that the team has proved this type of calculation is feasible, they are ready to apply it to the mysterious particle X(3872).

“The origin of X(3872) is an open question,” said Wilson. “It appears very close to a threshold, which could be accidental or a key part of the story. This is one thing we will look at very soon."

Professor Christopher Thomas, also from DAMTP, is a member of the Hadron Spectrum Collaboration, and is a co-author on the current studies. Wilson’s contribution was made possible in part by an eight-year fellowship with the Royal Society. The research was also supported in part by the Science and Technology Facilities Council (STFC), part of UK Research and Innovation (UKRI). Many of the calculations for this study were carried out with the support of the Cambridge Centre for Data Driven Discovery (CSD3) and DiRAC high-performance computing facilities in Cambridge, managed by Cambridge’s Research Computing Services division.

Reference:
David J. Wilson et al. ‘Scalar and Tensor Charmonium Resonances in Coupled-Channel Scattering from Lattice QCD.’ Physical Review Letters (2024). DOI: 10.1103/PhysRevLett.132.241901

David J. Wilson et al. ‘Charmonium xc0 and xc2 resonances in coupled-channel scattering from lattice QCD.’ Physical Review D (2024). DOI: 10.1103/PhysRevD.109.114503

Adapted from a Jefferson Lab story.

An elusive particle that first formed in the hot, dense early universe has puzzled physicists for decades. Following its discovery in 2003, scientists began observing a slew of other strange objects tied to the millionths of a second after the Big Bang.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

A team of researchers from the UK and Australia analysed charcoal and pollen contained in ancient mud to determine how Aboriginal Tasmanians shaped their surroundings. This is the earliest record of humans using fire to shape the Tasmanian environment.

Early human migrations from Africa to the southern part of the globe were well underway during the early part of the last ice age – humans reached northern Australia by around 65,000 years ago. When the first Palawa/Pakana (Tasmanian Indigenous) communities eventually reached Tasmania (known to the Palawa people as Lutruwita), it was the furthest south humans had ever settled.

These early Aboriginal communities used fire to penetrate and modify dense, wet forest for their own use – as indicated by a sudden increase in charcoal accumulated in ancient mud 41,600 years ago.

The researchers say their results, reported in the journal Science Advances, could not only help us understand how humans have been shaping the Earth’s environment for tens of thousands of years, but also help understand the long-term Aboriginal-landscape connection, which is vital for landscape management in Australia today.

Tasmania currently lies about 240 kilometres off the southeast Australian coast, separated from the Australian mainland by the Bass Strait. However, during the last ice age, Australia and Tasmania were connected by a huge land bridge, allowing people to reach Tasmania on foot. The land bridge remained until about 8,000 years ago, after the end of the last ice age, when rising sea levels eventually cut Tasmania off from the Australian mainland.

“Australia is home to the world’s oldest Indigenous culture, which has endured for over 50,000 years,” said Dr Matthew Adeleye from Cambridge’s Department of Geography, the study’s lead author. “Earlier studies have shown that Aboriginal communities on the Australian mainland used fire to shape their habitats, but we haven’t had similarly detailed environmental records for Tasmania.”

The researchers studied ancient mud taken from islands in the Bass Strait, which is part of Tasmania today, but would have been part of the land bridge connecting Australia and Tasmania during the last ice age. Due to low sea levels at the time, Palawa/Pakana communities were able to migrate from the Australian mainland.

Analysis of the ancient mud showed a sudden increase in charcoal around 41,600 years ago, followed by a major change in vegetation about 40,000 years ago, as indicated by different types of pollen in the mud.

“This suggests these early inhabitants were clearing forests by burning them, in order to create open spaces for subsistence and perhaps cultural activities,” said Adeleye. “Fire is an important tool, and it would have been used to promote the type of vegetation or landscape that was important to them.”

The researchers say that humans likely learned to use fire to clear and manage forests during their migration across the glacial landscape of Sahul – a palaeocontinent that encompassed modern-day Australia, Tasmania, New Guinea and eastern Indonesia – as part of the extensive migration out of Africa.

“As natural habitats adapted to these controlled burnings, we see the expansion of fire-adapted species such as Eucalyptus, primarily on the wetter, eastern side of the Bass Strait islands,” said Adeleye.

Burning practices are still practiced today by Aboriginal communities in Australia, including for landscape management and cultural activities. However, using this type of burning, known as cultural burning, for managing severe wildfires in Australia remains contentious. The researchers say understanding this ancient land management practice could help define and restore pre-colonial landscapes.

“These early Tasmanian communities were the island’s first land managers,” said Adeleye. “If we’re going to protect Tasmanian and Australian landscapes for future generations, it’s important that we listen to and learn from Indigenous communities who are calling for a greater role in helping to manage Australian landscapes into the future.”

The research was supported in part by the Australian Research Council.

Reference:
Matthew A. Adeleye et al. ‘Landscape burning facilitated Aboriginal migration into Lutruwita/Tasmania 41,600 years ago.’ Science Advances (2024). DOI: 10.1126/sciadv.adp6579

Some of the first human beings to arrive in Tasmania, over 41,000 years ago, used fire to shape and manage the landscape, about 2,000 years earlier than previously thought.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

A team of researchers from the UK and Australia analysed charcoal and pollen contained in ancient mud to determine how Aboriginal Tasmanians shaped their surroundings. This is the earliest record of humans using fire to shape the Tasmanian environment.

Early human migrations from Africa to the southern part of the globe were well underway during the early part of the last ice age – humans reached northern Australia by around 65,000 years ago. When the first Palawa/Pakana (Tasmanian Indigenous) communities eventually reached Tasmania (known to the Palawa people as Lutruwita), it was the furthest south humans had ever settled.

These early Aboriginal communities used fire to penetrate and modify dense, wet forest for their own use – as indicated by a sudden increase in charcoal accumulated in ancient mud 41,600 years ago.

The researchers say their results, reported in the journal Science Advances, could not only help us understand how humans have been shaping the Earth’s environment for tens of thousands of years, but also help understand the long-term Aboriginal-landscape connection, which is vital for landscape management in Australia today.

Tasmania currently lies about 240 kilometres off the southeast Australian coast, separated from the Australian mainland by the Bass Strait. However, during the last ice age, Australia and Tasmania were connected by a huge land bridge, allowing people to reach Tasmania on foot. The land bridge remained until about 8,000 years ago, after the end of the last ice age, when rising sea levels eventually cut Tasmania off from the Australian mainland.

“Australia is home to the world’s oldest Indigenous culture, which has endured for over 50,000 years,” said Dr Matthew Adeleye from Cambridge’s Department of Geography, the study’s lead author. “Earlier studies have shown that Aboriginal communities on the Australian mainland used fire to shape their habitats, but we haven’t had similarly detailed environmental records for Tasmania.”

The researchers studied ancient mud taken from islands in the Bass Strait, which is part of Tasmania today, but would have been part of the land bridge connecting Australia and Tasmania during the last ice age. Due to low sea levels at the time, Palawa/Pakana communities were able to migrate from the Australian mainland.

Analysis of the ancient mud showed a sudden increase in charcoal around 41,600 years ago, followed by a major change in vegetation about 40,000 years ago, as indicated by different types of pollen in the mud.

“This suggests these early inhabitants were clearing forests by burning them, in order to create open spaces for subsistence and perhaps cultural activities,” said Adeleye. “Fire is an important tool, and it would have been used to promote the type of vegetation or landscape that was important to them.”

The researchers say that humans likely learned to use fire to clear and manage forests during their migration across the glacial landscape of Sahul – a palaeocontinent that encompassed modern-day Australia, Tasmania, New Guinea and eastern Indonesia – as part of the extensive migration out of Africa.

“As natural habitats adapted to these controlled burnings, we see the expansion of fire-adapted species such as Eucalyptus, primarily on the wetter, eastern side of the Bass Strait islands,” said Adeleye.

Burning practices are still practiced today by Aboriginal communities in Australia, including for landscape management and cultural activities. However, using this type of burning, known as cultural burning, for managing severe wildfires in Australia remains contentious. The researchers say understanding this ancient land management practice could help define and restore pre-colonial landscapes.

“These early Tasmanian communities were the island’s first land managers,” said Adeleye. “If we’re going to protect Tasmanian and Australian landscapes for future generations, it’s important that we listen to and learn from Indigenous communities who are calling for a greater role in helping to manage Australian landscapes into the future.”

The research was supported in part by the Australian Research Council.

Reference:
Matthew A Adeleye et al. ‘Landscape burning facilitated Aboriginal migration into Lutruwita/Tasmania 41,600 years ago.’ Science Advances (2024). DOI: 10.1126/sciadv.adp6579

Some of the first human beings to arrive in Tasmania, over 41,000 years ago, used fire to shape and manage the landscape, about 2,000 years earlier than previously thought.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

An initial £10 million donation will be used to support education and research into areas including the conservation of biodiversity, enhancing business sustainability, and the restoration of natural habitats in Brazil and beyond. The agreement will establish the Suzano Scholars Fund, a perpetual endowment at Jesus College to fund Brazilian nationals studying for a postgraduate degree at the University of Cambridge connected to the environment, ecology and conservation, educating the next generation of sustainability experts and leaders. Funding will also be provided to academics based at the Conservation Research Institute to undertake research projects exploring the interaction between human and natural systems in areas such as biodiversity, climate change, water resource management, and ecosystem restoration. Read more about this new initiative here

Suzano, one the world’s largest producers of bio-based raw materials, based in São Paulo, Brazil, establishes a long-term initiative with Jesus College and the University of Cambridge. 

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This year’s Challenge, held at the iconic Somerset House in London, saw the Oxford and Cambridge University Boat Clubs come together in celebration of one of British sport’s most enduring rivalries. The event traditionally sees the Presidents representing the losing teams of the previous year’s races formally challenge those from the winning teams, marking the renewal of an intense competition which stretches back nearly 200 years.

Those in attendance gathered with anticipation to witness Oxford Presidents Tom Mackintosh and Annie Anezakis challenge Cambridge Presidents Luca Ferraro and Lucy Havard. The pairs faced off before shaking hands on stage in front of the coveted men’s and women’s trophies.

The Umpires were confirmed as Sarah Winckless MBE and Sir Matthew Pinsent, for the Men’s and Women’s races respectively. Winckless becomes the first woman to umpire the Men’s Race on The Championship Course.

The Boat Race will take place on Sunday 13 April, with The 79th Women’s Boat Race to be followed shortly after by The 170th Men’s Boat Race. Two hundred thousand spectators are expected to line the banks of the River Thames to watch the event - which is free to attend and broadcast live on the BBC - while millions more are expected to watch globally.

The Boat Race is made up of six races and in 2024, Cambridge won five. The make-up of the squads will be more diverse than ever in 2025, with 157 student rowers spanning 18 different nationalities from countries such as Nigeria, Sweden, Australia, New Zealand, Switzerland, Germany, Italy, France, Sri Lanka and China. Oxford’s Luisa Fernandez Chirino, should she be selected to face Cambridge, would be the first Mexican woman to compete at The Boat Race.

There will also be six Olympians within the squads. For Cambridge, this includes two-time Olympian Claire Collins, alongside reserve athlete for the 2024 British Olympic team, James Robson. For Oxford, this includes Paris men’s eight bronze medallist Nick Rusher, Paris women’s eight bronze medallist Heidi Long, Tokyo men’s eight gold medallist Tom Mackintosh, as well as Paris Olympian Nicholas Kohl. Meanwhile, Harry Brightmore, Paris gold medallist in the men’s eight, has joined Oxford as an assistant coach.

Asked by host, Olympic champion and four-time Boat Race winner Constantine Louloudis MBE, if this year's race would be "rinse and repeat" for Cambridge, Women's President, Lucy Havard, who is pursuing a PhD in Early Modern History at Gonville & Caius College, said: "Absolutely not - it's never the same, every year it's new people and Boat Race wins don't come easily. Everyone is gunning for it, everyone is putting so much time and effort in."

Luca Ferraro, who is taking an MPhil in History of Art and Architecture at Peterhouse, was asked about how it felt to take on the responsibility of Men's President. "I would be lying if I didn't say it didn't add a certain extra layer... racing an opponent you don't really get to meet at full strength until next year," he said. "You have the odd moment of thinking are we doing the right things, are we going fast enough and no-one feels that quite as keenly as the President, but we are surrounded by such a great team and it is so rewarding to have that extra level of responsibility."

First raced by crews from Oxford and Cambridge University in 1829, The Boat Race is now one of the world’s oldest and most famous amateur sporting events, offering an unrivalled educational experience to the student athletes who take part. The famous Championship Course stretches over 4.25 miles of tidal Thames in West London between Putney and Mortlake.

The countdown to the 2025 Boat Race is officially underway, with the annual Presidents’ Challenge ushering in another season of competition between the universities of Oxford and Cambridge.

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People in their late teens experience an increased sensitivity to threats after just a few hours left in a room on their own – an effect that endures even if they are interacting online with friends and family.

This is according to latest findings from a cognitive neuroscience experiment conducted at the University of Cambridge, which saw 40 young people aged 16-19 undergo testing before and after several hours alone – both with and without their smartphones.

Many countries have declared an epidemic of loneliness*. The researchers set out to “induce” loneliness in teenagers and study the effects through a series of tests, from a Pavlovian task to electrodes that measure sweat. 

Scientists found that periods of isolation, including those in which participants could use their phones, led to an increased threat response – the sensing of and reacting to potential dangers. This alertness can cause people to feel anxious and uneasy.

The authors of the study say that isolation and loneliness might lead to excessive “threat vigilance”, even when plugged in online, which could negatively impact adolescent mental health over time.

They say it could contribute to the persistent and exaggerated fear responses typical of anxiety disorders on the rise among young people around the world.

While previous studies show isolation leads to anxious behaviour and threat responses in rodents, this is believed to be the first study to demonstrate these effects through experiments involving humans.

The findings are published today in the journal Royal Society Open Science.

“We detected signs of heightened threat vigilance after a few hours of isolation, even when the adolescents had been connected through smartphones and social media,” said Emily Towner, study lead author from Cambridge’s Department of Psychology.

“This alertness to perceived threats might be the same mechanism that leads to the excessive worry and inability to feel safe which characterises anxiety,” said Towner, a Gates Cambridge Scholar.   

“It makes evolutionary sense that being alone increases our vigilance to potential threats. These threat response mechanisms undergo a lot of changes in adolescence, a stage of life marked by increasing independence and social sensitivity.”

"Our experiment suggests that periods of isolation in adolescents might increase their vulnerability to the development of anxiety, even when they are connected virtually.”

Researchers recruited young people from the local area in Cambridge, UK, conducting extensive screening to create a pool of 18 boys and 22 girls who had good social connections and no history of mental health issues.

Participants were given initial tests and questionnaires to establish a “baseline”. These included the Pavlovian threat test, in which they were shown a series of shapes on a screen, one of which was paired with a harsh noise played through headphones, so the shape became associated with a feeling of apprehension.

Electrodes attached to fingers monitored “electrodermal activity” – a physiological marker of stress – throughout this test.**

Each participant returned for two separate stints of around four hours isolated in a room in Cambridge University’s Psychology Department, after which the tests were completed again. There was around a month, on average, between sessions.

All participants underwent two isolation sessions. One was spent with a few puzzles to pass the time, but no connection to the outside world. For the other, participants were allowed smartphones and given wi-fi codes, as well as music and novels. The only major rule in both sessions was they had to stay awake.***

“We set out to replicate behaviour in humans that previous animal studies had found after isolation,” said Towner. “We wanted to know about the experience of loneliness, and you can’t ask animals how lonely they feel.”

Self-reported loneliness increased from baseline after both sessions. It was lower on average after isolation with social media, compared to full isolation.****

However, participants found the threat cue – the shape paired with a jarring sound – more anxiety-inducing and unpleasant after both isolation sessions, with electrodes also measuring elevated stress activity.

On average across the study, threat responses were 70% higher after the isolation sessions compared to the baseline, regardless of whether participants had been interacting digitally.

“Although virtual social interactions helped our participants feel less lonely compared to total isolation, their heightened threat response remained,” said Towner.

Previous studies have found a link between chronic loneliness and alertness to threats. The latest findings support the idea that social isolation may directly contribute to heightened fear responses, say researchers.  

Dr Livia Tomova, co-senior author and lecturer in Psychology at Cardiff University, who conducted the work while at Cambridge, added: “Loneliness among adolescents around the world has nearly doubled in recent years. The need for social interaction is especially intense during adolescence, but it is not clear whether online socialising can fulfil this need.

“This study has shown that digital interactions might not mitigate some of the deep-rooted effects that isolation appears to have on teenagers.”

Scientists say the findings might shed light on the link between loneliness and mental health conditions such as anxiety disorders, which are on the rise in young people.

*For example, in 2023 the U.S. Surgeon General declared an epidemic of loneliness and isolation.

**Electrodes placed on the fingers record small deflections in sweat and subsequent changes in electrical conductivity of the skin (electrodermal activity). Electrodermal activity is used to detect stress levels and increases with emotional or physical arousal.

***The baseline tests were always taken first. The order of the two isolation sessions was randomly allocated. For sessions with digital interactions allowed, most participants used social media (35 out of 40), with texting being the most common form of interaction (37 out of 40). Other popular platforms included Snapchat, Instagram, and WhatsApp. Participants mainly connected virtually with friends (38), followed by family (19), romantic partners (13), and acquaintances (4).

**** Average self-reported loneliness more than doubled after the isolation session with social media compared to baseline and nearly tripled after the complete isolation session compared to baseline.

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In an article published today in Lancet Planetary Health, a team of researchers – including several from the University of Cambridge – argue that much more needs to be done to mitigate the impacts of climate change on women, girls and gender-diverse individuals.

Focusing specifically on the intersection between climate change, gender, and human health, the researchers call on countries to work harder to ensure there is gender equity within their delegations to climate conferences and to ensure climate strategies identify gender-specific risks and vulnerabilities and address their root causes.

As the world prepares for COP29, concerns about gender representation and equality have reignited following the initial appointment of 28 men and no women to the COP29 organising committee in January 2024.

The effects of climate change – from heavy rains, rising temperatures, storms and floods through to sea level rises and droughts – exacerbate systemic inequalities and disproportionately affect marginalised populations, particularly those living in low-income areas.

While the specific situation may be different depending on where people live or their social background (like their class, race, ability, sexuality, age, or location), women, girls, and gender minorities are often at greater risk from the impacts of climate change. For example, in many countries, women are less likely to own land and resources to protect them in post-disaster situations, and have less control over income and less access to information, resulting in increased vulnerability to acute and long-term climate change impacts.

They are also particularly at risk from climate-related threats to their health, say the researchers. For example, studies have linked high temperatures to adverse birth outcomes such as spontaneous preterm births, pre-eclampsia and birth defects. Extreme events, which are expected to become more likely and intense due to climate change, also take a severe toll on women's social, physical, and mental well-being. Numerous studies highlight that gender-based violence is reported to increase during or after extreme events, often due to factors related to economic instability, food insecurity, disrupted infrastructure and mental stress.

Dr Kim Robin van Daalen, a former Gates Cambridge Scholar at the University of Cambridge, and researcher at the Barcelona Supercomputing Center (BSC), said: “Given how disproportionately climate change affects women, girls and gender minorities – a situation that is only likely to get worse – we need to ensure that their voices are heard and meaningfully included in discussions of how we respond to this urgent climate crisis. This is not currently happening at anywhere near the level it needs to.”

The team summarised the inclusion of gender, health and their intersection in key decisions and initiatives under the United Nations Framework Convention on Climate Change (UNFCCC), and analysed gender representation among representatives of Party and Observer State delegations at COPs between 1995-2023. Progress has been slow, they say.

They highlight how previous scholars have consistently noted that emphasis remains mainly on achieving a gender ‘number-based balance’ in climate governance, over exploring gender-specific risks and vulnerabilities and addressing their root causes. They also discuss how there remains limited recognition of the role climate change has in worsening gendered impacts on health, including gender-based violence and the lack of safeguarding reproductive health in the face of climate change.

Although the situation is slowly improving, at COP28, almost three-quarters (73%) of Party delegations were still majority men, and only just over one in six (16%) showed gender parity (that is, 45-55% women). In fact, gender parity has only been achieved in the ‘Western European and Other’ UN grouping (which also includes North America, Australia and New Zealand). Based on current trends, several countries - particularly those in the Asia-Pacific and Africa regions - are expected to take at least a decade from COP28 before reaching gender parity in their delegations.

Dr Ramit Debnath, former Gates Cambridge Scholar and now an Assistant Professor at Cambridge, said: “The urgency of climate action, as well as the slow understanding of climate, gender, and health connections, is cause for concern. Institutions like the UNFCCC must recognize these disparities, design appropriate methods to improve gender parity in climate governance, and keep these representation gaps from growing into societal and health injustices.”

Beyond ensuring that their voices are heard, more equitable inclusion of women has consistently been suggested to transform policymaking across political and social systems, including the generation of policies that better represent women’s interests. Previous recent analyses of 49 European countries revealed that greater women’s political representation correlates with reduced inequalities in self-reported health, lower geographical inequalities in infant mortality and fewer disability-adjusted life-years lost across genders.

Similar positive findings have been reported related to environmental policies, with women’s representation in national parliaments being associated with increased ratification of environmental treaties and more stringent climate change policies. For example, women legislators in the European parliament and US House of Representatives have been found to be more inclined to support environmental legislation than men.

Dr Ronita Bardhan, Associate Professor at the University of Cambridge, said: "Achieving equitable gender representation in climate action is not just about fairness - it's a strategic necessity with significant co-benefits. We can shape climate policies and infrastructure that address a broader spectrum of societal needs, leading to more inclusive solutions enhancing public health, social equity, and environmental resilience."

While the researchers’ analyses focused on achieving gender balance, studies on women’s involvement in climate governance suggest that increased representation does not by itself always lead to meaningful policy changes. Even when formally included, women’s active participation in male-dominated institutions is often constrained by existing social and cultural norms, implicit biases and structural barriers.

Dr van Daalen added: “If we’re to meaningfully incorporate gender into climate policy and practice, we need to understand the risks and vulnerabilities that are gender-specific and look at how we can address them and their root causes at all phases of programme and policy development.

“But we also need to resist reducing women to a single, homogenous group, which risks deepening existing inequalities and overlooks opportunities to address the needs of all individuals. It is crucial to recognise the diversity of women and their embodiment of multiple, intersecting identities that shape their climate experiences as well as their mitigation and adaptation needs.”

The team also highlights that gender-diverse people face unique health and climate-related risks due to their increased vulnerability, stigma, and discrimination. For example, during and after extreme events, transgender people in the United States report being threatened or prohibited access to shelters. Similarly, in the Philippines, Indonesia, and Samoa, gender-diverse individuals often face discrimination, mockery, and exclusion from evacuation centres or access to food. Yet, say the researchers, there are major gaps in knowledge about the health implications of climate change for such groups.

Find out how Cambridge's pioneering research in climate and nature is regenerating nature, rewiring energy, rethinking transport and redefining economics - forging a future for our planet.

Reference
Van Daalen, KR et al. Bridging the gender, climate, and health gap: the road to COP29. Lancet Planetary Health; 11 Nov 2024; DOI: 10.1016/S2542-5196(24)00270-5

Climate governance is dominated by men, yet the health impacts of the climate crisis often affect women, girls, and gender-diverse people disproportionately, argue researchers ahead of the upcoming 29th United Nations Climate Summit (COP29) in Azerbaijan.

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Cambridge University Boat Club (CUBC) student and alumni crews took part in the race, which is held on the Charles River over a 3-mile course comprising several bends that require skilled coxing. Cambridge walked away with gold in the Men’s Championship Eights, Women’s Master’s Double, Men’s Alumni Fours, and Men’s Senior Master’s Fours against top international crews, with an impressive set of results across the board.

Read the full story on the CUBC website.

Cambridge have claimed four golds at one of the biggest events in the global rowing calendar, the Head of the Charles Regatta in Boston, Massachusetts, USA.

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But, writing in the journal Nature Geoscience, an international group of scientists, led by the University of Cambridge and the University of Århus, argue that tree planting at high latitudes will accelerate, rather than decelerate, global warming.

As the climate continues to warm, trees can be planted further and further north, and large-scale tree-planting projects in the Arctic have been championed by governments and corporations as a way to mitigate the worst effects of climate change.

However, when trees are planted in the wrong places - such as normally treeless tundra and mires, as well as large areas of the boreal forest with relatively open tree canopies - they can make global warming worse.

According to lead author Assistant Professor Jeppe Kristensen from Aarhus University in Denmark, the unique characteristics of Arctic and sub-Arctic ecosystems make them poorly suited for tree planting for climate mitigation.

“Soils in the Arctic store more carbon than all vegetation on Earth,” said Kristensen. “These soils are vulnerable to disturbances, such as cultivation for forestry or agriculture, but also the penetration of tree roots. The semi-continuous daylight during the spring and early summer, when snow is still on the ground, also makes the energy balance in this region extremely sensitive to surface darkening, since green and brown trees will soak up more heat from the sun than white snow.” 

In addition, the regions surrounding the North Pole in North America, Asia and Scandinavia are prone to natural disturbances - such as wildfires and droughts - that kill off vegetation. Climate change makes these disturbances both more frequent and more severe.

“This is a risky place to be a tree, particularly as part of a homogeneous plantation that is more vulnerable to such disturbances,” said Kristensen. “The carbon stored in these trees risks fuelling disturbances and getting released back to the atmosphere within a few decades.”

The researchers say that tree planting at high latitudes is a prime example of a climate solution with a desired effect in one context but the opposite effect in another.

“The climate debate is very carbon-focused because the main way humans have modified the Earth’s climate in the last century is through emitting greenhouse gases from burning fossil fuels,” said Kristensen. “But at the core, climate change is the result of how much solar energy entering the atmosphere stays, and how much leaves again – Earth’s so-called energy balance.”

Greenhouse gases are one important determinant of how much heat can escape our planet’s atmosphere. However, the researchers say that at high latitudes, how much sunlight is reflected back into space, without being converted into heat (known as the albedo effect), is more important than carbon storage for the total energy balance.

The researchers are calling for a more holistic view of ecosystems to identify truly meaningful nature-based solutions that do not compromise the overall goal: slowing down climate change.

“A holistic approach is not just a richer way of looking at the climate effects of nature-based solutions, but it’s imperative if we’re going to make a difference in the real world,” said senior author Professor Marc Macias-Fauria, from the University of Cambridge’s Scott Polar Research Institute.

However, the researchers recognise that there can be other reasons for planting trees, such as timber self-sufficiency, but these cases do not come with bonuses for climate mitigation.

“Forestry in the far North should be viewed like any other production system and compensate for its negative impact on the climate and biodiversity,” said Macias-Fauria. “You can’t have your cake and eat it, and you can’t deceive the Earth. By selling northern afforestation as a climate solution, we’re only fooling ourselves.”

So how can we moderate global warming at high latitudes? The researchers suggest that working with local communities to support sustainable populations of large herbivores, such as caribou, could be a more viable nature-based solution to climate change in Arctic and subarctic regions than planting millions of trees. 

“There is ample evidence that large herbivores affect plant communities and snow conditions in ways that result in net cooling,” said Macias-Fauria. “This happens both directly, by keeping tundra landscapes open, and indirectly, through the effects of herbivore winter foraging, where they modify the snow and decrease its insulation capacity, reducing soil temperatures and permafrost thaw.”

The researchers say it’s vital to consider biodiversity and the livelihoods of local communities in the pursuit of nature-based climate solutions.

“Large herbivores can reduce climate-driven biodiversity loss in Arctic ecosystems and remain a fundamental food resource for local communities,” said Macias-Fauria. “Biodiversity and local communities are not an added benefit to nature-based solutions: they are fundamental. Any nature-based solutions must be led by the communities who live at the front line of climate change.”

More about this story

Reference:
Jeppe Å Kristensen et al. ‘Tree planting is no climate solution at northern high latitudes.’ Nature Geoscience (2024). DOI: 10.1038/s41561-024-01573-4

Explore more discoveries, innovations and research on climate and nature at the University of Cambridge: www.cam.ac.uk/climate-and-nature

Tree planting has been widely touted as a cost-effective way of reducing global warming, due to trees’ ability to store large quantities of carbon from the atmosphere.

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On 5 November 2024, Greater Manchester’s Mayor Andy Burnham visited Cambridge to celebrate and further cement a groundbreaking partnership between the two cities' innovation ecosystems. The collaboration, which was officially launched in 2023, is aimed at leveraging the combined strengths of Manchester and Cambridge to fuel the growth of start-ups, attract investment, and foster inclusive economic development across the UK.

The visit marked an important step forward in this trailblazing collaboration, which is the first of its kind in the UK. Leading academic, business and civil figures from both cities were in attendance including: Dr Nik Johnson, Mayor of Cambridgeshire and Peterborough; Professor Deborah Prentice, Vice-Chancellor of the University of Cambridge; Professor Duncan Ivison, Vice-Chancellor of the University of Manchester; Professor Lou Cordwell, Professor of Innovation, University of Manchester; Dr Diarmuid O’Brien, Pro-Vice-Chancellor for Innovation, University of Cambridge and Dr Kathryn Chapman, Executive Director, Innovate Cambridge.

The delegation also included representatives from the business community, including AstraZeneca, which is deepening its support for entrepreneurial ventures through mentorship and collaboration.

Strengthening connections between two powerhouses

The day began with a tour of Cambridge’s West Innovation District, an area known for its cutting-edge facilities and academic institutions. The tour was led by Dr Diarmuid O’Brien, who highlighted the district’s role in driving forward innovation in areas ranging from aerospace to zero-carbon technologies. One key stop was the world-famous Whittle Laboratory, renowned for its work on decarbonising aviation, and the new Cavendish Laboratory, which hosts the University’s Physics department and supports the creation of innovative start-ups.

At the Cambridge Graphene Centre, Professor Andrea Ferrari, Director of the Centre, was joined by Manchester University colleagues to welcome Mayor Burnham and Dr Johnson for an in-depth session focused on graphene research and the ongoing collaboration with Manchester’s National Graphene Institute.

Discussions centred around the commercialisation of cutting-edge research from both institutions and the potential for scaling these innovations in both cities. Spinout companies Paragraf and Versarian spoke about the opportunities the partnership could unlock for future collaboration, talent exchange, and investment.

AstraZeneca expands mentorship programme to Manchester

Another highlight of the day was a visit to AstraZeneca’s Discovery Centre (DISC) in the Cambridge Biomedical Campus, where the company announced that its ‘AstraZeneca Exchange’ mentorship programme would be expanded to support entrepreneurs and start-ups in Greater Manchester. The programme, which is already active in Cambridge, connects start-ups with AstraZeneca’s network of scientific and business experts, providing invaluable support to early-stage ventures.

Inclusive innovation and regional growth

A key theme of the visit was ensuring that innovation-driven growth benefits all communities. This commitment to inclusive innovation was explored during a roundtable discussion, which included representatives from the Bennett Institute for Public Policy in Cambridge and The Productivity Institute in Manchester. The conversation centred around how innovation can be made more accessible to economically lagging regions and marginalised groups, and how to ensure that the fruits of innovation are equitably distributed.

Professor Andy Westwood, Policy Director at The Productivity Institute and Professor Mike Kenny, Director of the Bennett Institute for Public Policy both addressed the group, with Professor Kenny presenting a newly launched report, 'Townscapes: Making Innovation More Inclusive'. 

The report is the product of collaboration between the two Institutes and explores how innovation can address regional disparities.“An inclusive approach to innovation focuses not only on the process and outcomes of innovation, but also considers who is involved in it, what are the social and economic conditions that foster it, and perhaps most importantly, keeps in mind which places and communities benefit from innovation” said Professor Kenny.

This commitment to inclusive innovation was further reflected in the opening of The Glasshouse, a new facility from Innovate Cambridge dedicated to supporting the next generation of entrepreneurs from diverse backgrounds. The Glasshouse will serve as a hub and incubator for new ideas and technologies, providing mentorship, resources, and networking opportunities for start-ups.

A partnership for the future

As the day concluded, Mayor Burnham reflected on the immense potential of the partnership between Greater Manchester and Cambridge. “Greater Manchester and Cambridge are two world-renowned centres of innovation. This partnership is breaking new ground, linking the North of England with the Golden triangle to drive regional and national economic growth. We also share an ambition for growth that benefits everyone, with more people and businesses able to access the opportunities created by innovation.

“Our two places have distinct identities and unique strengths, but we also have a lot in common – world-leading universities and dynamic, fast-growing economies. By working together, we can be greater than the sum of our parts.”

With both cities continuing to push the boundaries of scientific and technological advancements, the partnership between Greater Manchester and Cambridge is poised to play a pivotal role in shaping the UK’s future innovation landscape.The visit has underscored the shared commitment to advancing regional growth, fostering collaboration, and ensuring that the benefits of innovation are felt by all.

The Vice-Chancellor of Cambridge University, Professor Deborah Prentice said: "This collaboration between our two cities and universities is a testament to our shared ambition and the immense opportunities ahead. Over the past five years, we've seen thousands of co-publications as well as deep collaboration in graphene and materials research, showcasing the power of our joint efforts. This partnership isn’t just about what we’ve achieved; it’s about what we’re building—a dynamic platform to connect and strengthen our innovation ecosystems for the future."

This Cambridge x Manchester collaboration promises to be more than just a stepping stone—it's a foundation for the future of innovation in the UK.

Visit from Manchester Mayor signals a new era of collaboration between two UK innovation hubs with a focus on boosting regional economies and fostering inclusive growth.

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Cambridge Institute for Sustainability Leadership's Chief Innovation Officer, James Cole, looks back at what happened at COP16, and asks what comes next in this article. 

After two weeks of negotiations last week in Cali, Colombia, the COP16 biodiversity summit was suspended with no overall agreement on a path forward on “resource mobilisation."

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Researchers in the UK Dementia Research Institute at the University of Cambridge screened more than 1,400 clinically-approved drug compounds using zebrafish genetically engineered to make them mimic so-called tauopathies. They discovered that drugs known as carbonic anhydrase inhibitors – of which the glaucoma drug methazolamide is one – clear tau build-up and reduce signs of the disease in zebrafish and mice carrying the mutant forms of tau that cause human dementias.

Tauopathies are neurodegenerative diseases characterised by the build-up in the brain of tau protein ‘aggregates’ within nerve cells. These include forms of dementia, Pick's disease and progressive supranuclear palsy, where tau is believed to be the primary disease driver, and Alzheimer’s disease and chronic traumatic encephalopathy (neurodegeneration caused by repeated head trauma, as has been reported in football and rugby players), where tau build-up is one consequence of disease but results in degeneration of brain tissue.

There has been little progress in finding effective drugs to treat these conditions. One option is to repurpose existing drugs. However, drug screening – where compounds are tested against disease models – usually takes place in cell cultures, but these do not capture many of the characteristics of tau build-up in a living organism.

To work around this, the Cambridge team turned to zebrafish models they had previously developed. Zebrafish grow to maturity and are able to breed within two to three months and produce large numbers of offspring. Using genetic manipulation, it is possible to mimic human diseases as many genes responsible for human diseases often have equivalents in the zebrafish.

In a study published today in Nature Chemical Biology, Professor David Rubinsztein, Dr Angeleen Fleming and colleagues modelled tauopathy in zebrafish and screened 1,437 drug compounds. Each of these compounds has been clinically approved for other diseases.

Dr Ana Lopez Ramirez from the Cambridge Institute for Medical Research, Department of Physiology, Development and Neuroscience and the UK Dementia Research Institute at the University of Cambridge, joint first author, said: “Zebrafish provide a much more effective and realistic way of screening drug compounds than using cell cultures, which function quite differently to living organisms. They also enable us to do so at scale, something that it not feasible or ethical in larger animals such as mice.”  

Using this approach, the team showed that inhibiting an enzyme known as carbonic anhydrase – which is important for regulating acidity levels in cells – helped the cell rid itself of the tau protein build-up. It did this by causing the lysosomes – the ‘cell’s incinerators’ – to move to the surface of the cell, where they fused with the cell membrane and ‘spat out’ the tau.

When the team tested methazolamide on mice that had been genetically engineered to carry the P301S human disease-causing mutation in tau, which leads to the progressive accumulation of tau aggregates in the brain, they found that those treated with the drug performed better at memory tasks and showed improved cognitive performance compared with untreated mice.

Analysis of the mouse brains showed that they indeed had fewer tau aggregates, and consequently a lesser reduction in brain cells, compared with the untreated mice.

Fellow joint author Dr Farah Siddiqi, also from the Cambridge Institute for Medical Research and the UK Dementia Research Institute, said: “We were excited to see in our mouse studies that methazolamide reduces levels of tau in the brain and protects against its further build-up. This confirms what we had shown when screening carbonic anhydrase inhibitors using zebrafish models of tauopathies.”

Professor Rubinsztein from the UK Dementia Research Institute and Cambridge Institute for Medical Research at the University of Cambridge, said: “Methazolamide shows promise as a much-needed drug to help prevent the build-up of dangerous tau proteins in the brain. Although we’ve only looked at its effects in zebrafish and mice, so it is still early days, we at least know about this drug’s safety profile in patients. This will enable us to move to clinical trials much faster than we might normally expect if we were starting from scratch with an unknown drug compound.

“This shows how we can use zebrafish to test whether existing drugs might be repurposed to tackle different diseases, potentially speeding up significantly the drug discovery process.”

The team hopes to test methazolamide on different disease models, including more common diseases characterised by the build-up of aggregate-prone proteins, such as Huntington’s and Parkinson’s diseases.

The research was supported by the UK Dementia Research Institute (through UK DRI Ltd, principally funded through the Medical Research Council), Tau Consortium and Wellcome.

Reference
Lopez, A & Siddiqi, FH et al. Carbonic anhydrase inhibition ameliorates tau toxicity via enhanced tau secretion. Nat Chem Bio; 31 Oct 2024; DOI: 10.1038/s41589-024-01762-7
 

A drug commonly used to treat glaucoma has been shown in zebrafish and mice to protect against the build-up in the brain of the protein tau, which causes various forms of dementia and is implicated in Alzheimer’s disease.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

The research team, led by the University of Cambridge, adapted an algorithm originally designed for humans and found it could automatically detect and grade heart murmurs in dogs, based on audio recordings from digital stethoscopes. In tests, the algorithm detected heart murmurs with a sensitivity of 90%, a similar accuracy to expert cardiologists.

Heart murmurs are a key indicator of mitral valve disease, the most common heart condition in adult dogs. Roughly one in 30 dogs seen by a veterinarian has a heart murmur, although the prevalence is higher in small breed dogs and older dogs.

Since mitral valve disease and other heart conditions are so common in dogs, early detection is crucial as timely medication can extend their lives. The technology developed by the Cambridge team could offer an affordable and effective screening tool for primary care veterinarians, and improve quality of life for dogs. The results are reported in the Journal of Veterinary Internal Medicine.

“Heart disease in humans is a huge health issue, but in dogs it’s an even bigger problem,” said first author Dr Andrew McDonald from Cambridge’s Department of Engineering. “Most smaller dog breeds will have heart disease when they get older, but obviously dogs can’t communicate in the same way that humans can, so it’s up to primary care vets to detect heart disease early enough so it can be treated.”

Professor Anurag Agarwal, who led the research, is a specialist in acoustics and bioengineering. “As far as we’re aware, there are no existing databases of heart sounds in dogs, which is why we started out with a database of heart sounds in humans,” he said. “Mammalian hearts are fairly similar, and when things go wrong, they tend to go wrong in similar ways.”

The researchers started with a database of heart sounds from about 1000 human patients and developed a machine learning algorithm to replicate whether a heart murmur had been detected by a cardiologist. They then adapted the algorithm so it could be used with heart sounds from dogs.

The researchers gathered data from almost 800 dogs who were undergoing routine heart examination at four veterinary specialist centres in the UK. All dogs received a full physical examination and heart scan (echocardiogram) by a cardiologist to grade any heart murmurs and identify cardiac disease, and heart sounds were recorded using an electronic stethoscope. By an order of magnitude, this is the largest dataset of dog heart sounds ever created.

“Mitral valve disease mainly affects smaller dogs, but to test and improve our algorithm, we wanted to get data from dogs of all shapes, sizes and ages,” said co-author Professor Jose Novo Matos from Cambridge’s Department of Veterinary Medicine, a specialist in small animal cardiology. “The more data we have to train it, the more useful our algorithm will be, both for vets and for dog owners.”

The researchers fine-tuned the algorithm so it could both detect and grade heart murmurs based on the audio recordings, and differentiate between murmurs associated with mild disease and those reflecting advanced heart disease that required further treatment.  

“Grading a heart murmur and determining whether the heart disease needs treatment requires a lot of experience, referral to a veterinary cardiologist, and expensive specialised heart scans,” said Novo Matos. “We want to empower general practitioners to detect heart disease and assess its severity to help owners make the best decisions for their dogs.”

Analysis of the algorithm’s performance found it agreed with the cardiologist’s assessment in over half of cases, and in 90% of cases, it was within a single grade of the cardiologist’s assessment. The researchers say this is a promising result, as it is common for there to be significant variability in how different vets grade heart murmurs.

“The grade of heart murmur is a useful differentiator for determining next steps and treatments, and we’ve automated that process,” said McDonald. “For vets and nurses without as much stethoscope skill, and even those who are incredibly skilled with a stethoscope, we believe this algorithm could be a highly valuable tool.”

In humans with valve disease, the only treatment is surgery, but for dogs, effective medication is available. “Knowing when to medicate is so important, in order to give dogs the best quality of life possible for as long as possible,” said Agarwal. “We want to empower vets to help make those decisions.”

“So many people talk about AI as a threat to jobs, but for me, I see it as a tool that will make me a better cardiologist,” said Novo Matos. “We can’t perform heart scans on every dog in this country  – we just don’t have enough time or specialists to screen every dog with a murmur. But tools like these could help vets and owners, so we can quickly identify those dogs who are most in need of treatment.”

The research was supported in part by the Kennel Club Charitable Trust, the Medical Research Council, and Emmanuel College Cambridge.

Reference:
Andrew McDonald et al. ‘A machine learning algorithm to grade canine heart murmurs and stage preclinical myxomatous mitral valve disease.’ Journal of Veterinary Internal Medicine (2024). DOI: 10.1111/jvim.17224

Researchers have developed a machine learning algorithm to accurately detect heart murmurs in dogs, one of the main indicators of cardiac disease, which affects a large proportion of some smaller breeds such as King Charles Spaniels.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

The research team, led by the University of Cambridge, adapted an algorithm originally designed for humans and found it could automatically detect and grade heart murmurs in dogs, based on audio recordings from digital stethoscopes. In tests, the algorithm detected heart murmurs with a sensitivity of 90%, a similar accuracy to expert cardiologists.

Heart murmurs are a key indicator of mitral valve disease, the most common heart condition in adult dogs. Roughly one in 30 dogs seen by a veterinarian has a heart murmur, although the prevalence is higher in small breed dogs and older dogs.

Since mitral valve disease and other heart conditions are so common in dogs, early detection is crucial as timely medication can extend their lives. The technology developed by the Cambridge team could offer an affordable and effective screening tool for primary care veterinarians, and improve quality of life for dogs. The results are reported in the Journal of Veterinary Internal Medicine.

“Heart disease in humans is a huge health issue, but in dogs it’s an even bigger problem,” said first author Dr Andrew McDonald from Cambridge’s Department of Engineering. “Most smaller dog breeds will have heart disease when they get older, but obviously dogs can’t communicate in the same way that humans can, so it’s up to primary care vets to detect heart disease early enough so it can be treated.”

Professor Anurag Agarwal, who led the research, is a specialist in acoustics and bioengineering. “As far as we’re aware, there are no existing databases of heart sounds in dogs, which is why we started out with a database of heart sounds in humans,” he said. “Mammalian hearts are fairly similar, and when things go wrong, they tend to go wrong in similar ways.”

The researchers started with a database of heart sounds from about 1000 human patients and developed a machine learning algorithm to replicate whether a heart murmur had been detected by a cardiologist. They then adapted the algorithm so it could be used with heart sounds from dogs.

The researchers gathered data from almost 800 dogs who were undergoing routine heart examination at four veterinary specialist centres in the UK. All dogs received a full physical examination and heart scan (echocardiogram) by a cardiologist to grade any heart murmurs and identify cardiac disease, and heart sounds were recorded using an electronic stethoscope. By an order of magnitude, this is the largest dataset of dog heart sounds ever created.

“Mitral valve disease mainly affects smaller dogs, but to test and improve our algorithm, we wanted to get data from dogs of all shapes, sizes and ages,” said co-author Professor Jose Novo Matos from Cambridge’s Department of Veterinary Medicine, a specialist in small animal cardiology. “The more data we have to train it, the more useful our algorithm will be, both for vets and for dog owners.”

The researchers fine-tuned the algorithm so it could both detect and grade heart murmurs based on the audio recordings, and differentiate between murmurs associated with mild disease and those reflecting advanced heart disease that required further treatment.  

“Grading a heart murmur and determining whether the heart disease needs treatment requires a lot of experience, referral to a veterinary cardiologist, and expensive specialised heart scans,” said Novo Matos. “We want to empower general practitioners to detect heart disease and assess its severity to help owners make the best decisions for their dogs.”

Analysis of the algorithm’s performance found it agreed with the cardiologist’s assessment in over half of cases, and in 90% of cases, it was within a single grade of the cardiologist’s assessment. The researchers say this is a promising result, as it is common for there to be significant variability in how different vets grade heart murmurs.

“The grade of heart murmur is a useful differentiator for determining next steps and treatments, and we’ve automated that process,” said McDonald. “For vets and nurses without as much stethoscope skill, and even those who are incredibly skilled with a stethoscope, we believe this algorithm could be a highly valuable tool.”

In humans with valve disease, the only treatment is surgery, but for dogs, effective medication is available. “Knowing when to medicate is so important, in order to give dogs the best quality of life possible for as long as possible,” said Agarwal. “We want to empower vets to help make those decisions.”

“So many people talk about AI as a threat to jobs, but for me, I see it as a tool that will make me a better cardiologist,” said Novo Matos. “We can’t perform heart scans on every dog in this country  – we just don’t have enough time or specialists to screen every dog with a murmur. But tools like these could help vets and owners, so we can quickly identify those dogs who are most in need of treatment.”

The research was supported in part by the Kennel Club Charitable Trust, the Medical Research Council, and Emmanuel College Cambridge.

Reference:
Andrew McDonald et al. ‘A machine learning algorithm to grade canine heart murmurs and stage preclinical myxomatous mitral valve disease.’ Journal of Veterinary Internal Medicine (2024). DOI: 10.1111/jvim.17224

Researchers have developed a machine learning algorithm to accurately detect heart murmurs in dogs, one of the main indicators of cardiac disease, which affects a large proportion of some smaller breeds such as King Charles Spaniels.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

The treatment – known as repetitive transcranial magnetic stimulation (TMS) – involves placing an electromagnetic coil against the scalp to relay a high-frequency magnetic field to the brain.

Around one in 20 adults is estimated to suffer from depression. Although treatments exist, such as anti-depressant medication and cognitive behavioural therapy (‘talking therapy’), they are ineffective for just under one in three patients.

One of the key characteristics of depression is under-activity of some regions (such as the dorsolateral prefrontal cortex) and over-activity of others (such as the orbitofrontal cortex (OFC)).

Repetitive transcranial magnetic stimulation applied to the left side of the dorsolateral prefrontal cortex (an area at the upper front area of the brain) is approved for treatment of depression in the UK by NICE and in the US by the FDA. It has previously been shown to lead to considerable improvements among patients after a course of 20 sessions, but because the sessions usually take place over 20-30 days, the treatment is not ideal for everyone, particularly in acute cases or where a person is suicidal.

In research published in Psychological Medicine, scientists from Cambridge, UK, and Guiyang, China, tested how effective an accelerated form of TMS is. In this approach, the treatment is given over 20 sessions, but with four sessions per day over a period of five consecutive days.

The researchers also tested a ‘dual’ approach, whereby a magnetic field was additionally applied to the right-hand side of the OFC (which sits below the dorsolateral prefrontal cortex).

Seventy-five patients were recruited to the trial from the Second People’s Hospital of Guizhou Province in China. The severity of their depression was measured on a scale known as the Hamilton Rating Scale of Depression.

Participants were split randomly into three groups: a ‘dual’ group receiving TMS applied first to the right- and then to the left-hand sides of the brain; a ‘single’ group receiving sham TMS to the right-side followed by active TMS applied to the left-side; and a control group receiving a sham treatment to both sides. Each session lasted in total 22 minutes.

There was a significant improvement in scores assessed immediately after the final treatment in the dual treatment group compared to the other two groups. When the researchers looked for clinically-relevant responses – that is, where an individual’s score fell by at least 50% – they found that almost half (48%) of the patients in the dual treatment group saw such a reduction, compared to just under one in five (18%) in the single treatment group and fewer than one in 20 (4%) in the control group.

Four weeks later, around six in 10 participants in both the dual and single treatment groups (61% and 59% respectively) showed clinically relevant responses, compared to just over one in five (22%) in the control group.

Professor Valerie Voon from the Department of Psychiatry at the University of Cambridge, who led the UK side of the study, said: “Our accelerated approach means we can do all of the sessions in just five days, rapidly reducing an individual’s symptoms of depression. This means it could be particularly useful in severe cases of depression, including when someone is experiencing suicidal thoughts. It may also help people be discharged from hospital more rapidly or even avoid admission in the first place.

“The treatment works faster because, by targeting two areas of the brain implicated in depression, we’re effectively correcting imbalances in two import processes, getting brain regions ‘talking’ to each other correctly.”

The treatment was most effective in those patients who at the start of the trial showed greater connectivity between the OFC and the thalamus (an area in the middle of the brain responsible for, among other things, regulation of consciousness, sleep, and alertness). The OFC is important for helping us make decisions, particularly in choosing rewards and avoiding punishment. Its over-activity in depression, particularly in relation to its role in anti-reward or punishment, might help explain why people with depression show a bias towards negative expectations and ruminations.

Dr Yanping Shu from the Guizhou Mental Health Centre, Guiyang, China, said: “This new treatment has demonstrated a more pronounced – and faster – improvement in response rates for patients with major depressive disorder. It represents a significant step forward in improving outcomes, enabling rapid discharge from hospitals for individuals with treatment-resistant depression, and we are hopeful it will lead to new possibilities in mental health care.”

Dr Hailun Cui from Fudan University, a PhD student in Professor Voon’s lab at the time of the study, added: “The management of treatment-resistant depression remains one of the most challenging areas in mental health care. These patients often fail to respond to standard treatments, including medication and psychotherapy, leaving them in a prolonged state of severe distress, functional impairment, and increased risk of suicide.

“This new TMS approach offers a beacon of hope in this difficult landscape. Patients frequently reported experiencing ‘lighter and brighter’ feelings as early as the second day of treatment. The rapid improvements, coupled with a higher response rate that could benefit a broader depressed population, mark a significant breakthrough in the field.”

Just under a half (48%) of participants in the dual treatment group reported local pain where the dual treatment was applied, compared to just under one in 10 (9%) of participants in the single treatment group. However, despite this, there were no dropouts.

For some individuals, this treatment may be sufficient, but for others ‘maintenance therapy’ may be necessary, with an additional day session if their symptoms appear to be worsening over time. It may also be possible to re-administer standard therapy as patients can then become more able to engage in psychotherapy. Other options include using transcranial direct current stimulation, a non-invasive form of stimulation using weak electrical impulses that can be delivered at home.

The researchers are now exploring exactly which part of the orbitofrontal cortex is most effective to target and for which types of depression.

The research was supported by in the UK by the Medical Research Council and by the National Institute for Health and Care Research Cambridge Biomedical Research Centre.*

Reference
Cui, H, Ding, H & Hu, L et al. A novel dual-site OFC-dlPFC accelerated repetitive transcranial magnetic stimulation for depression: a pilot randomized controlled study. Psychological Medicine; 23 Oct 2024; DOI: 10.1017/S0033291724002289

*A full list of funders is available in the journal paper.

A type of therapy that involves applying a magnetic field to both sides of the brain has been shown to be effective at rapidly treating depression in patients for whom standard treatments have been ineffective.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

Election to the Academy is considered one of the highest honours in the fields of health and medicine and recognises individuals who have demonstrated outstanding professional achievement and commitment to service.

“It is a great honour to have been elected to the National Academy of Medicine,”  said Professor Rowitch.

Professor Rowitch obtained his PhD from the University of Cambridge. His research in the field of developmental neurobiology has focused on glial cells that comprise the ‘white matter’ of the human brain. It has furthered understanding human neonatal brain development as well as white matter injury in premature infants, multiple sclerosis and leukodystrophy. Amongst numerous awards, he was elected a Fellow of the Academy of Medical Sciences in 2018 and Fellow of the Royal Society in 2021.

Professor Rowitch’s current interest focuses on functional genomic technologies to better diagnose and treat rare neurogenetic disorders in children. He is academic lead for the new Cambridge Children’s Hospital, developing integrated paediatric physical-mental healthcare and research within the NHS and University of Cambridge.

NAM President Victor J. Dzau said: “This class of new members represents the most exceptional researchers and leaders in health and medicine, who have made significant breakthroughs, led the response to major public health challenges, and advanced health equity.

“Their expertise will be necessary to supporting NAM’s work to address the pressing health and scientific challenges we face today. It is my privilege to welcome these esteemed individuals to the National Academy of Medicine.”

Professor Rowitch is one of 90 regular members and 10 international members announced during the Academy’s annual meeting. New members are elected by current members through a process that recognises individuals who have made major contributions to the advancement of the medical sciences, health care, and public health. 

Professor David Rowitch, Head of the Department of Paediatrics at the University of Cambridge, has been elected to the prestigious National Academy of Medicine in the USA.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

Latest research has revealed a ‘positive association’ between the number of properties listed as Airbnb rentals and police-reported robberies and violent crimes in thousands of London neighbourhoods between 2015 and 2018.

In fact, the study led by the University of Cambridge suggests that a 10% increase in active Airbnb rentals in the city would correspond to an additional 1,000 robberies per year across London.*

Urban sociologists say the rapid pace at which crime rises in conjunction with new rentals suggests that the link is related more to opportunities for crime, rather than loss of cohesion within communities – although both are likely contributing factors.  

“We tested for the most plausible alternative explanations, from changes in police patrols to tourist hotspots and even football matches,” said Dr Charles Lanfear from Cambridge’s Institute of Criminology, co-author of the study published today in the journal Criminology.

“Nothing changed the core finding that Airbnb rentals are related to higher crime rates in London neighbourhoods.”

“While Airbnb offers benefits to tourists and hosts in terms of ease and financial reward, there may be social consequences to turning large swathes of city neighbourhoods into hotels with little regulation,” Lanfear said.

Founded in 2008, Airbnb is a giant of the digital economy, with more than 5 million property hosts now active on the platform in some 100,000 cities worldwide.

However, concerns that Airbnb is contributing to unaffordable housing costs has led to a backlash among residents of cities such as Barcelona, and calls for greater regulation.

London is one of the most popular Airbnb markets in the world. An estimated 4.5 million guests stayed in a London Airbnb during the period covered by the study.

Lanfear and his University of Pennsylvania co-author Professor David Kirk used masses of data from AirDNA: a site that scrapes Airbnb to provide figures, trends and approximate geolocations for the short-term letting market.

They mapped AirDNA data from 13 calendar quarters (January 2015 to March 2018) onto ‘Lower Layer Super Output Areas’, or LSOAs.

These are designated areas of a few streets containing around two thousand residents, used primarily for UK census purposes. There are 4,835 LSOAs in London, and all were included in the study.

Crime statistics from the UK Home Office and Greater London Authority for 6 categories – robbery, burglary, theft, anti-social behaviour, any violence, and bodily harm – were then mapped onto LSOAs populated with AirDNA data. 

The researchers analysed all forms of Airbnb lets, but found the link between active Airbnbs and crime is primarily down to entire properties for rent, rather than spare or shared rooms.

The association between active Airbnb rentals and crime was most significant for robbery and burglary, followed by theft and any violence. No link was found for anti-social behaviour and bodily harm.

On average across London, an additional Airbnb property was associated with a 2% increase in the robbery rate within an LSOA. This association was 1% for thefts, 0.9% for burglaries, and 0.5% for violence.

“While the potential criminogenic effect for each Airbnb rental is small, the accumulative effect of dozens in a neighbourhood, or tens of thousands across the city, is potentially huge,” Lanfear said.

He points out that London had an average of 53,000 active lettings in each calendar-quarter of the study period, and an average of 11 lettings per LSOA.

At its most extreme, one neighbourhood in Soho, an area famed for nightlife, had a high of 318 dedicated Airbnbs – some 30% of all households in the LSOA.  

The data models suggest that a 3.2% increase in all types of Airbnb rentals per LSOA would correspond to a 1% increase in robberies city-wide: 325 additional robberies based on the figure of 32,500 recorded robberies in London in 2018.

Lanfear and Kirk extensively stress-tested the association between Airbnb listings and London crime rates.

This included factoring in ‘criminogenic variables’ such as property prices, police stops, the regularity of police patrols, and even English Premier League football games (by both incorporating attendance into data modelling, and removing all LSOAs within a kilometre of major games).

The duo re-ran their data models excluding all the 259 LSOAs in central London’s Zone One, to see if the association was limited to high tourism areas with lots of Airbnb listings. The data models even incorporated the seasonal ‘ebb and flow’ of London tourism. Nothing changed the overall trends. 

Prior to crunching the numbers, the researchers speculated that any link might be down to Airbnbs affecting ‘collective efficacy’: the social cohesion within a community, combined with a willingness to intervene for the public good.

The study measured levels of collective efficacy across the city using data from both the Metropolitan Police and the Mayor of London’s Office, who conduct surveys on public perceptions of criminal activity and the likely responses of their community.    

Collective efficacy across London is not only consistently high, but did not explain the association between Airbnbs and crime in the data models.

Moreover, when Airbnb listings rise, the effect on crime is more immediate than one caused by a slow erosion of collective efficacy. “Crime seems to go up as soon as Airbnbs appear, and stays elevated for as long as they are active,” said Lanfear.

The researchers conclude it is likely driven by criminal opportunity. “A single Airbnb rental can create different types of criminal opportunity,” said Lanfear.

“An Airbnb rental can provide an easy potential victim such as a tourist unfamiliar with the area, or a property that is regularly vacant and so easier to burgle. A very temporary occupant may be more likely to cause criminal damage.”

“Offenders may learn to return to areas with more Airbnbs to find unguarded targets,” said Lanfear. “More dedicated Airbnb properties may mean fewer long-term residents with a personal stake in the area who are willing to report potential criminal activity.”

Airbnb has taken steps to prevent crime, including some background checks as well as requirements for extended bookings on occasions popular for one-night parties, such as New Year’s Eve. “The fact that we still find an increase in crime despite Airbnb’s efforts to curtail it reveals the severity of the predicament,” said Kirk.

Added Lanfear: “Short-term letting sites such as Airbnb create incentives for landlords that lead to property speculation, and we can see the effect on urban housing markets. We can now see that the expansion of Airbnb may contribute to city crime rates.”

“It is not the company or even the property owners who experience the criminogenic side effects of Airbnb, it is the local residents building their lives in the neighbourhood.”   

Notes:

*Above 2018 levels, which is when the study data ends. 

Rising numbers of houses and flats listed as short-term lets on Airbnb are associated with higher rates of crimes such as burglaries and street robberies right across London, according to the most detailed study of its kind.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

Writing in the journal Science Robotics, the research team, led by the University of Cambridge, outline how ‘palaeo-inspired robotics’ could provide a valuable experimental approach to studying how the pectoral and pelvic fins of ancient fish evolved to support weight on land.

“Since fossil evidence is limited, we have an incomplete picture of how ancient life made the transition to land,” said lead author Dr Michael Ishida from Cambridge’s Department of Engineering. “Palaeontologists examine ancient fossils for clues about the structure of hip and pelvic joints, but there are limits to what we can learn from fossils alone. That’s where robots can come in, helping us fill gaps in the research, particularly when studying major shifts in how vertebrates moved.”

Ishida is a member of Cambridge’s Bio-Inspired Robotics Laboratory, led by Professor Fumiya Iida. The team is developing energy-efficient robots for a variety of applications, which take their inspiration from the efficient ways that animals and humans move.

With funding from the Human Frontier Science Program, the team is developing palaeo-inspired robots, in part by taking their inspiration from modern-day ‘walking fish’ such as mudskippers, and from fossils of extinct fish. “In the lab, we can’t make a living fish walk differently, and we certainly can’t get a fossil to move, so we’re using robots to simulate their anatomy and behaviour,” said Ishida.

The team is creating robotic analogues of ancient fish skeletons, complete with mechanical joints that mimic muscles and ligaments. Once complete, the team will perform experiments on these robots to determine how these ancient creatures might have moved.

“We want to know things like how much energy different walking patterns would have required, or which movements were most efficient,” said Ishida. “This data can help confirm or challenge existing theories about how these early animals evolved.”

One of the biggest challenges in this field is the lack of comprehensive fossil records. Many of the ancient species from this period in Earth’s history are known only from partial skeletons, making it difficult to reconstruct their full range of movement.

“In some cases, we’re just guessing how certain bones connected or functioned,” said Ishida. “That’s why robots are so useful—they help us confirm these guesses and provide new evidence to support or rebut them.”

While robots are commonly used to study movement in living animals, very few research groups are using them to study extinct species. “There are only a few groups doing this kind of work,” said Ishida. “But we think it’s a natural fit – robots can provide insights into ancient animals that we simply can’t get from fossils or modern species alone.”

The team hopes that their work will encourage other researchers to explore the potential of robotics to study the biomechanics of long-extinct animals. “We’re trying to close the loop between fossil evidence and real-world mechanics,” said Ishida. “Computer models are obviously incredibly important in this area of research, but since robots are interacting with the real world, they can help us test theories about how these creatures moved, and maybe even why they moved the way they did.”

The team is currently in the early stages of building their palaeo-robots, but they hope to have some results within the next year. The researchers say they hope their robot models will not only deepen understanding of evolutionary biology, but could also open up new avenues of collaboration between engineers and researchers in other fields.

The research was supported by the Human Frontier Science Program. Fumiya Iida is a Fellow of Corpus Christi College, Cambridge. Michael Ishida a Postdoctoral Research Associate at Gonville and Caius College, Cambridge.

Reference:
Michael Ishida et al. ‘Paleo-inspired robotics as an experimental approach to the history of life.’ Science Robotics (2024). DOI: 10.1126/scirobotics.adn1125

The transition from water to land is one of the most significant events in the history of life on Earth. Now, a team of roboticists, palaeontologists and biologists is using robots to study how the ancestors of modern land animals transitioned from swimming to walking, about 390 million years ago.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

The researchers, from the University of Cambridge, studied the chemical composition of the Venusian atmosphere and inferred that its interior is too dry today for there ever to have been enough water for oceans to exist at its surface. Instead, the planet has likely been a scorching, inhospitable world for its entire history.

The results, reported in the journal Nature Astronomy, have implications for understanding Earth’s uniqueness, and for the search for life on planets outside our Solar System. While many exoplanets are Venus-like, the study suggests that astronomers should narrow their focus to exoplanets which are more like Earth.

From a distance, Venus and Earth look like siblings: it is almost identical in size and is a rocky planet like Earth. But up close, Venus is more like an evil twin: it is covered with thick clouds of sulfuric acid, and its surface has a mean temperature close to 500°C.

Despite these extreme conditions, for decades, astronomers have been investigating whether Venus once had liquid oceans capable of supporting life, or whether some mysterious form of ‘aerial’ life exists in its thick clouds now.

“We won’t know for sure whether Venus can or did support life until we send probes at the end of this decade,” said first author Tereza Constantinou, a PhD student at Cambridge’s Institute of Astronomy. “But given it likely never had oceans, it is hard to imagine Venus ever having supported Earth-like life, which requires liquid water.”

When searching for life elsewhere in our galaxy, astronomers focus on planets orbiting their host stars in the habitable zone, where temperatures are such that liquid water can exist on the planet’s surface. Venus provides a powerful limit on where this habitable zone lies around a star.

“Even though it’s the closest planet to us, Venus is important for exoplanet science, because it gives us a unique opportunity to explore a planet that evolved very differently to ours, right at the edge of the habitable zone,” said Constantinou.

There are two primary theories on how conditions on Venus may have evolved since its formation 4.6 billion years ago. The first is that conditions on the surface of Venus were once temperate enough to support liquid water, but a runaway greenhouse effect caused by widespread volcanic activity caused the planet to get hotter and hotter. The second theory is that Venus was born hot, and liquid water has never been able to condense at the surface.

“Both of those theories are based on climate models, but we wanted to take a different approach based on observations of Venus’ current atmospheric chemistry,” said Constantinou. “To keep the Venusian atmosphere stable, then any chemicals being removed from the atmosphere should also be getting restored to it, since the planet’s interior and exterior are in constant chemical communication with one another.”

The researchers calculated the present destruction rate of water, carbon dioxide and carbonyl sulphide molecules in Venus’ atmosphere, which must be restored by volcanic gases to keep the atmosphere stable.

Volcanism, through its supply of gases to the atmosphere, provides a window into the interior of rocky planets like Venus. As magma rises from the mantle to the surface, it releases gases from the deeper portions of the planet.

On Earth, volcanic eruptions are mostly steam, due to our planet’s water-rich interior. But, based on the composition of the volcanic gases necessary to sustain the Venusian atmosphere, the researchers found that volcanic gases on Venus are at most six percent water. These dry eruptions suggest that Venus’s interior, the source of the magma that releases volcanic gases, is also dehydrated.

At the end of this decade, NASA’s DAVINCI mission will be able to test and confirm whether Venus has always been a dry, inhospitable planet, with a series of flybys and a probe sent to the surface. The results could help astronomers narrow their focus when searching for planets that can support life in orbit around other stars in the galaxy.

“If Venus was habitable in the past, it would mean other planets we have already found might also be habitable,” said Constantinou. “Instruments like the James Webb Space Telescope are best at studying the atmospheres of planets close to their host star, like Venus. But if Venus was never habitable, then it makes Venus-like planets elsewhere less likely candidates for habitable conditions or life.

“We would have loved to find that Venus was once a planet much closer to our own, so it’s kind of sad in a way to find out that it wasn’t, but ultimately it’s more useful to focus the search on planets that are mostly likely to be able to support life – at least life as we know it.”

The research was supported in part by the Science and Technology Facilities Council (STFC), part of UK Research and Innovation (UKRI).

Reference:
Tereza Constantinou, Oliver Shorttle, and Paul B Rimmer. ‘A dry Venusian interior constrained by atmospheric chemistry.’ Nature Astronomy (2024). DOI: 10.1038/s41550-024-02414-5

A team of astronomers has found that Venus has never been habitable, despite decades of speculation that our closest planetary neighbour was once much more like Earth than it is today.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

Writing in the journal Science Robotics, the research team, led by the University of Cambridge, outline how ‘palaeo-inspired robotics’ could provide a valuable experimental approach to studying how the pectoral and pelvic fins of ancient fish evolved to support weight on land.

“Since fossil evidence is limited, we have an incomplete picture of how ancient life made the transition to land,” said lead author Dr Michael Ishida from Cambridge’s Department of Engineering. “Palaeontologists examine ancient fossils for clues about the structure of hip and pelvic joints, but there are limits to what we can learn from fossils alone. That’s where robots can come in, helping us fill gaps in the research, particularly when studying major shifts in how vertebrates moved.”

Ishida is a member of Cambridge’s Bio-Inspired Robotics Laboratory, led by Professor Fumiya Iida. The team is developing energy-efficient robots for a variety of applications, which take their inspiration from the efficient ways that animals and humans move.

With funding from the Human Frontier Science Program, the team is developing palaeo-inspired robots, in part by taking their inspiration from modern-day ‘walking fish’ such as mudskippers, and from fossils of extinct fish. “In the lab, we can’t make a living fish walk differently, and we certainly can’t get a fossil to move, so we’re using robots to simulate their anatomy and behaviour,” said Ishida.

The team is creating robotic analogues of ancient fish skeletons, complete with mechanical joints that mimic muscles and ligaments. Once complete, the team will perform experiments on these robots to determine how these ancient creatures might have moved.

“We want to know things like how much energy different walking patterns would have required, or which movements were most efficient,” said Ishida. “This data can help confirm or challenge existing theories about how these early animals evolved.”

One of the biggest challenges in this field is the lack of comprehensive fossil records. Many of the ancient species from this period in Earth’s history are known only from partial skeletons, making it difficult to reconstruct their full range of movement.

“In some cases, we’re just guessing how certain bones connected or functioned,” said Ishida. “That’s why robots are so useful—they help us confirm these guesses and provide new evidence to support or rebut them.”

While robots are commonly used to study movement in living animals, very few research groups are using them to study extinct species. “There are only a few groups doing this kind of work,” said Ishida. “But we think it’s a natural fit – robots can provide insights into ancient animals that we simply can’t get from fossils or modern species alone.”

The team hopes that their work will encourage other researchers to explore the potential of robotics to study the biomechanics of long-extinct animals. “We’re trying to close the loop between fossil evidence and real-world mechanics,” said Ishida. “Computer models are obviously incredibly important in this area of research, but since robots are interacting with the real world, they can help us test theories about how these creatures moved, and maybe even why they moved the way they did.”

The team is currently in the early stages of building their palaeo-robots, but they hope to have some results within the next year. The researchers say they hope their robot models will not only deepen understanding of evolutionary biology, but could also open up new avenues of collaboration between engineers and researchers in other fields.

The research was supported by the Human Frontier Science Program. Fumiya Iida is a Fellow of Corpus Christi College, Cambridge. Michael Ishida a Postdoctoral Research Associate at Gonville and Caius College, Cambridge.

Reference:
Michael Ishida et al. ‘Paleo-inspired robotics as an experimental approach to the history of life.’ Science Robotics (2024). DOI: 10.1126/scirobotics.adn1125

The transition from water to land is one of the most significant events in the history of life on Earth. Now, a team of roboticists, palaeontologists and biologists is using robots to study how the ancestors of modern land animals transitioned from swimming to walking, about 390 million years ago.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

• The Cambridge-GSK Translational Immunology Collaboration (CG-TIC) combines University and GSK expertise in the science of the immune system, AI and clinical development with access to patients and their data provided by Cambridge University Hospitals.
• GSK is investing more than £50 million in CG-TIC, further strengthening Cambridge’s position as Europe’s leading life sciences cluster.

GSK plc is making this investment to establish the Cambridge-GSK Translational Immunology Collaboration (CG-TIC), a five-year collaboration with the University of Cambridge and Cambridge University Hospitals. The collaboration is focused on understanding the onset of a disease, its progression, how patients respond to therapies and on developing biomarkers for rapid diagnosis. Ultimately, the goal is to trial more effective, personalised medicines.

The collaboration will focus on kidney and respiratory diseases, both of which affect large numbers of people worldwide. Kidney disease is estimated to affect 850 million people (roughly 10% of the world’s population) (International Society of Nephrology) and chronic respiratory diseases around 545 million (The Lancet).

Many types of kidney disease remain poorly understood and treatments, where they exist, tend to have limited efficacy. Chronic kidney disease is particularly unpleasant and debilitating for patients, often leading to end-stage disease. Treatments such as transplant and dialysis involve complex medical regimes and frequent hospital visits, making effective prevention and treatment the aim.

To make progress in treating these challenging disease areas, CG-TIC will apply an array of new techniques, including the use of cutting-edge single cell technologies to characterise how genes are expressed in individual cells. AI and machine learning have a critical role to play in transforming how data is combined and interrogated.

Using these techniques, the ambition is to be able to initiate new studies and early phase trials of new therapies for a number of hard-to-treat diseases which affect the kidneys. The same techniques will be applied to respiratory diseases and findings will be shared across the disease areas potentially to help identify and share better treatments across these different targets.

Peter Kyle, Secretary of State for Science, Innovation and Technology, welcomed the collaboration: "The UK's life sciences industry is thriving, driving innovation and improving lives. This collaboration between GSK and the University of Cambridge demonstrates our country's leading research and development capabilities.

“By focusing on cutting-edge research and harnessing the power of AI, this has the potential to advance the treatment of immune-related diseases, which could benefit patients both here in the UK and internationally. It's a clear example of how collaboration between industry, academia, and healthcare can deliver tangible results and strengthen the UK's position in healthcare innovation."

Tony Wood, Chief Scientific Officer, GSK, added: “Collaboration is at the heart of scientific progress and is fundamental to how we do R&D at GSK. We’re excited to build on our existing work with the University of Cambridge to further this world-leading scientific and technological capability in the UK. By bringing together Cambridge’s expertise and our own internal capabilities, including understanding of the immune system and the use of AI to accelerate drug development, we have an opportunity to help patients struggling with complex disease.”

The aim of CG-TIC is to improve outcomes for patients and Cambridge provides a unique environment in which to involve them, with Cambridge University Hospitals playing a pivotal role in the collaboration and Royal Papworth Hospital NHS Foundation Trust, the UK’s leading heart and lung hospital, a likely future partner.

Home to the hospitals and to much of the collaboration’s research activity, the Cambridge Biomedical Campus provides a unique environment where academia, industry and healthcare can come together and where human translational research is supported by the National Institute for Health and Care Research (NIHR) Cambridge Biomedical Research Centre.

Professor Deborah Prentice, Vice-Chancellor of the University of Cambridge, said: “The University sits at the heart of Europe’s leading life sciences cluster, where excellent research and the NHS’s clinical resources combine with the talent generated by the many innovative bioscience companies that call Cambridge home. Through this very important collaboration with GSK, Cambridge will be able to drive economic growth for the UK while improving the health of people in this country and around the world.”

Roland Sinker, CEO of Cambridge University Hospitals NHS Foundation Trust, also welcomed the collaboration, saying: “We are very excited to be part of this important partnership, which is another example of Cambridge experts working together to develop transformational new therapies, and use existing ones more precisely, to improve outcomes for patients with chronic and debilitating conditions.”

The Cambridge-GSK Translational Immunology Collaboration will be co-led by Nicolas Wisniacki, VP, Clinical Research Head, GSK (above left) and David Thomas, Professor of Renal Medicine, University of Cambridge and principal investigator at the Cambridge Institute for Therapeutic Immunology and Infectious Diseases.

The ambition of the partnership is to treat immune-related diseases more precisely with existing therapies and to rapidly develop new ones.

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It is Nobel prize-giving season and last week alumni of Cambridge University were awarded four of them for their brilliant work. In a leading article last week, The Times pointed out that if it were a country, Cambridge’s total of 125 would place it third for Nobel laureates behind only the UK and the US. This is a tribute to outstanding work which changes lives.

As an American who took over the role of vice-chancellor a little over a year ago, I am struck by how often the value of world-class research universities — to our economy, and to society and our daily lives — is underestimated here in Britain. Two of the top five in the world are British and in higher education terms this country punches well above its weight. This week we will announce a huge new investment in transformative research focused on a common foe: cancer. It will bring global benefits.

Our world-class, research-intensive universities are national assets. They can be genuine drivers of economic growth. Cambridge research contributes a staggering £30 billion to the UK economy each year. By contrast, no single US university plays such a national role.

And yet some UK research universities are in a precarious financial state. They are vital to their local and regional communities, as well as to Britain as a whole. They need more than just recognition if they are to drive future sustainable growth: they need investment, yes, but also support to innovate so they can continue to break new research frontiers and to serve their communities.

In Cambridge, we plan to launch an innovation hub that attracts and hosts the best researchers from around the world, plus entrepreneurs, funders and philanthropists. Under one roof, ideas will be driven forward, before they are spun out. The US and France have successfully pointed the way in these hothouses for innovation, in Boston and Paris. The UK must catch up — and fast.

With the budget looming, even — or perhaps especially — in tough times, the government must see our research universities as key allies and partners in its mission to drive economic growth. They are one of the main advantages this country enjoys in the global race for economic success.

At the start of a new academic year, thousands of students and researchers have arrived in Cambridge and at other British universities. We should invest in our world-class institutions and their contributions to tackling society’s greatest challenges so that in the decades to come we will have more Nobel laureates to celebrate.

This article first appeared in The Times on 14 October 2024.

Professor Deborah Prentice, Vice-Chancellor of the University of Cambridge, writes in The Times about how universities can drive UK growth - but they need more than just recognition.

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The significant funding commitment will enable world-class discovery science, unlocking new insights into how cancers develop, grow and spread, as well as examining how the immune system can be harnessed to combat the disease.  

Research at the CRUK Cambridge Institute focuses on understanding every stage of the cancer life cycle – how tumours grow and spread and how this is impacted by the characteristics of each individual patient.  By studying how tumours develop, adapt, and interact with their surroundings, scientists aim to uncover crucial insights into their behaviour. 

Vice-Chancellor of the University of Cambridge, Professor Deborah Prentice, said: “From understanding and detecting cancer at its very earliest stages, to developing kinder treatments to building Cambridge Cancer Research Hospital, a transformative new cancer research hospital for the region, Cambridge is changing the story of cancer. For many years now, Cancer Research UK has played a vital role in enabling this world-leading work. Today’s announcement will ensure our researchers continue to find new ways to transform the lives of patients locally, nationally and internationally.”

Today’s £173 million announcement further boosts CRUK’s unwavering commitment towards its mission to beat cancer. The charity is investing in exciting new research programmes, forging new partnerships and is on track to invest more than £1.5bn on research over the five-year period 2021/22 to 2025/26.   

Director of the CRUK Cambridge Institute, Professor Greg Hannon, said: “In a golden era for life sciences, this funding bolsters Cambridge as a major global hub for cancer research on an increasingly competitive worldwide stage and will greatly aid the recruitment of top-tier international talent.   

“Research from the Institute has already made a positive impact for patients and their families, from the development of innovative technologies, diagnostic tests, and advanced imaging methods to the roll out of personalised medicine programmes for those with brain, breast, pancreatic, and ovarian cancers. We believe that only by embracing the complexity of cancer and how the disease interacts with the normal cells of patients can we move the needle on the hardest to treat cancers.” 

The Institute is dedicated to improving cancer patients’ lives through discovery science and clinical translational research and has over 300 scientists working on groundbreaking discoveries taking research from laboratory bench to bedside.  

Established in 2007, it was the first major new cancer research centre in the UK for over 50 years. In 2013, it became a department of the University of Cambridge School of Clinical Medicine, strengthening links with researchers across the University and at Addenbrooke's Hospital,  and further enhancing its position as a world leader with research transitioning into clinical trials, and ultimately new and better cancer treatments. 

Professor Hannon added: "The Institute serves as a foundation for the entire Cambridge cancer research community through access to cutting-edge equipment and technical expertise. Only through understanding all aspects of the disease can we prevent, detect and treat cancer so that everybody can lead longer, better lives, free from fear of cancer.

“With this new funding, the Institute aims to accelerate its impact for patients, with new schemes to integrate clinicians into every aspect of our research and to embrace new technologies, including the promise of machine learning and artificial intelligence to enhance our discovery portfolio.”  

The award, which will support the Institute over the next seven years, follows a comprehensive review of the facility led by an independent panel of international cancer experts who recognised research innovation.  

CRUK Chief Executive, Michelle Mitchell, said: “We are delighted to confirm this incredible investment which is a reflection of  the world-leading research community at the CRUK Cambridge Institute. The funding will underpin long-term cutting-edge discovery research, as well as supporting researchers to find new ways to improve cancer prevention and treatment, while creating innovative solutions to diagnose the disease earlier. 

“This kind of funding would not be possible without the generosity of Cancer Research UK supporters and philanthropists."

Work undertaken at the Institute includes: 

• Understanding cancer: By gaining a deeper understanding of how tumours grow, adapt, and interact with their surroundings, scientists hope to uncover why some cells become cancerous and learn how each tumour's lifecycle can affect a patient’s response to treatment and prognosis.  Professor Greg Hannon's team developed a diagnostic tool using virtual reality to explore every cell and aspect of breast tumours in unprecedented detail.
• Unravelling tumour interactions: Researchers are investigating a tumours’ ‘microenvironment' – which includes the surrounding cells, blood vessels, and immune cells and how they interact. This is helping scientists to predict how well immunotherapy treatments will work.
• Cancer detection: Scientists are finding new ways to detect cancer earlier, predict the best course of treatments and tailor therapies to individual needs, to improve survival.  Using tumour DNA, scientists can monitor the effectiveness of treatments and catch signs of cancer returning.  Cambridge scientists are also working on a simple at-home test for future patients to regularly monitor their progress. 
• Personalised medicine: Looking at the unique genetic mutations of a person’s tumour, including how it behaves and responds to treatment, allows treatments to be developed and matched to the specific genetic change.  For example, Professor James Brenton's team discovered a specific mutation in the most common form of ovarian cancer which is now used across the NHS as a cancer marker to measure treatment response for the disease. 

Thanks to research, cancer death rates have fallen by 10% percent in the UK over the past decade. But in the East of England, around 37,400 people are still diagnosed, and around 15,700 lose their lives to the disease every year - underlining the vital need for new and better treatments. 

Major studies seeking more accurate treatments for the deadliest cancers like ovarian and oesophageal cancer will also be supported at the Institute.  Research undertaken by Professor Florian Markowetz and his team includes predicting cancer weaknesses to treatment, and spotting cancers as early as possible using AI technology. 

There are 17 research groups based at the Institute – based on the largest biomedical campus in Europe - studying a range of cancer and technologies to support improved cancer treatments. 

Find out how Cambridge is changing the story of cancer

Adapted from a press release from Cancer Research UK

Cancer Research UK (CRUK) has today announced a £173 million investment in its institute at the University of Cambridge - the largest single grant ever awarded by the charity outside of London.  

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From Tuesday 15 October the University of Cambridge’s Museum of Zoology is offering visitors a unique experience: the chance to chat with the animals on display – whether skeletal, taxidermy, or extinct.

In a collaboration with the company Nature Perspectives, the Museum’s Assistant Director Jack Ashby has chosen a range of animal specimens to bring back to life using generative Artificial Intelligence.

Visitors can pose their questions to thirteen specimens - including dodo and whale skeletons, a taxidermied red panda, and a preserved cockroach - by scanning QR codes that open a chat-box on their mobile phone. In two-way conversations, which can be voice- or text-based, the specimens will answer as if they are still alive.

This is believed to be the first time a museum has used generative Artificial Intelligence to enable visitors to chat with objects on display in this way.

By analysing data from the conversations, the team hopes that the month-long experiment will help them learn more about how AI can help the public to better engage with nature, and about the potential for AI in museums. It will also provide the museum with new insights into what visitors really want to know about the specimens on display.

Nature Perspectives uses AI to enable cultural institutions like the Museum of Zoology to engage the public through these unique conversational experiences. The company aims to reverse a growing apathy towards biodiversity loss by enabling new ways to engage with the natural world.

“This is an amazing opportunity for people to test out an emerging technology in our inspiring Museum setting, and we also hope to learn something about how our visitors see the animals on display,” said Jack Ashby, Assistant Director of the University of Cambridge’s Museum of Zoology.

He added: “Our whole purpose is to get people engaged with the natural world. So we're curious to see whether this will work, and whether chatting to the animals will change people’s attitudes towards them - will the cockroach be better liked, for example, as a result of having its voice heard?”

“By using AI to simulate non-human perspectives, our technology offers a novel way for audiences to connect with the natural world,” said Gal Zanir, co-founder of the company Nature Perspectives, which developed the AI technology for the experience.

He added: “One of the most magical aspects of the simulations is that they’re age-adaptive. For the first time, visitors of all ages will be able to ask the specimens anything they like.”

The technology brings together all available information on each animal involved – including details particular to the individual specimens such as where they came from and how they were prepared for display in the museum. This is all repackaged from a first-person perspective, so that visitors can experience realistic, meaningful conversations.

The animals will adjust their tone and language to suit the age of the person they’re talking to. And they’re multi-lingual - speaking over 20 languages including Spanish and Japanese so that visitors can chat in their native languages.

The team has chosen a range of specimens that include skeletons, taxidermy, models, and whole preserved animals. The specimens are: dodo skeleton, narwhal skeleton, brain coral, red admiral butterfly, fin whale skeleton, American cockroach, huia taxidermy (a recently extinct bird from New Zealand), red panda taxidermy, freeze-dried platypus, giant sloth fossil skeleton, giant deer skull and antlers, mallard taxidermy, and Ichthyostega model (an extinct ancestor of all animals with four legs).

Nature Perspectives was created by a team of graduates from the University of Cambridge’s Masters in Conservation Leadership programme, who noticed that people seem to feel more connected to machines when they can talk to them. This inspired the team to apply the same principle to nature - giving nature a voice to promote its agency and foster deeper, more personal connections between people and the natural world.

“Artificial Intelligence is opening up exciting new opportunities to connect people with non-human life, but the impacts need to be carefully studied. I’m delighted to be involved in exploring how the Nature Perspectives pilot affects the way people feel about and understand the species they ‘meet’ in the Museum of Zoology,” said Professor Chris Sandbrook, Director of the University of Cambridge’s Masters in Conservation Leadership programme.

“Enabling museums to engage visitors with the simulated perspectives of exhibits is only the first step for Nature Perspectives. We aim to apply this transformative approach widely, from public engagement and education to scientific research, to representing nature in legal processes, policy-making and beyond," said Zanir.

The Nature Perspectives AI experiment runs for one month, from 15th October to 15th of November 2024. For visiting times see www.museum.zoo.cam.ac.uk/visit-us 

Explore more discoveries, innovations and research on climate and nature at the University of Cambridge.

Specimens in a Cambridge museum will be brought to life through the power of Artificial Intelligence, by a team aiming to strengthen our connection with the natural world and reverse apathy towards biodiversity loss.

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Volatiles are elements or compounds that change into vapour at relatively low temperatures. They include the six most common elements found in living organisms, as well as water. The zinc found in meteorites has a unique composition, which can be used to identify the sources of Earth’s volatiles.

The researchers, from the University of Cambridge and Imperial College London, have previously found that Earth’s zinc came from different parts of our Solar System: about half came from beyond Jupiter and half originated closer to Earth.

“One of the most fundamental questions on the origin of life is where the materials we need for life to evolve came from,” said Dr Rayssa Martins from Cambridge’s Department of Earth Sciences. “If we can understand how these materials came to be on Earth, it might give us clues to how life originated here, and how it might emerge elsewhere.”

Planetesimals are the main building blocks of rocky planets, such as Earth. These small bodies are formed through a process called accretion, where particles around a young star start to stick together, and form progressively larger bodies.

But not all planetesimals are made equal. The earliest planetesimals that formed in the Solar System were exposed to high levels of radioactivity, which caused them to melt and lose their volatiles. But some planetesimals formed after these sources of radioactivity were mostly extinct, which helped them survive the melting process and preserved more of their volatiles.

In a study published in the journal Science Advances, Martins and her colleagues looked at the different forms of zinc that arrived on Earth from these planetesimals. The researchers measured the zinc from a large sample of meteorites originating from different planetesimals and used this data to model how Earth got its zinc, by tracing the entire period of the Earth’s accretion, which took tens of millions of years.

Their results show that while these ‘melted’ planetesimals contributed about 70% of Earth’s overall mass, they only provided around 10% of its zinc.

According to the model, the rest of Earth’s zinc came from materials that didn’t melt and lose their volatile elements. Their findings suggest that unmelted, or ‘primitive’ materials were an essential source of volatiles for Earth.

“We know that the distance between a planet and its star is a determining factor in establishing the necessary conditions for that planet to sustain liquid water on its surface,” said Martins, the study’s lead author. “But our results show there’s no guarantee that planets incorporate the right materials to have enough water and other volatiles in the first place – regardless of their physical state.”

The ability to trace elements through millions or even billions of years of evolution could be a vital tool in the search for life elsewhere, such as on Mars, or on planets outside our Solar System.

“Similar conditions and processes are also likely in other young planetary systems,” said Martins. “The roles these different materials play in supplying volatiles is something we should keep in mind when looking for habitable planets elsewhere.”

The research was supported in part by Imperial College London, the European Research Council, and UK Research and Innovation (UKRI).

Reference:
Rayssa Martins et al. ‘Primitive asteroids as a major source of terrestrial volatiles.’ Science Advances (2024). DOI: 10.1126/sciadv.ado4121

Researchers have used the chemical fingerprints of zinc contained in meteorites to determine the origin of volatile elements on Earth. The results suggest that without ‘unmelted’ asteroids, there may not have been enough of these compounds on Earth for life to emerge.

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The Cambridge Conservation Initiative and the University of Cambridge Institute for Sustainability Leadership (CISL) co-hosted a panel discussion featuring key industry leaders in the run-up to the 16th Conference of the Parties to the Convention on Biological Diversity (CBD COP16). Please read more about the panel here

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This galaxy is one hundred times smaller than the Milky Way, but is surprisingly mature for so early in the universe. Like a large city, this galaxy has a dense collection of stars at its core but becomes less dense in the galactic ‘suburbs’. And like a large city, this galaxy is starting to sprawl, with star formation accelerating in the outskirts.

This is the earliest-ever detection of inside-out galactic growth. Until Webb, it had not been possible to study galaxy growth so early in the universe’s history. Although the images obtained with Webb represent a snapshot in time, the researchers, led by the University of Cambridge, say that studying similar galaxies could help us understand how they transform from clouds of gas into the complex structures we observe today. The results are reported in the journal Nature Astronomy.

“The question of how galaxies evolve over cosmic time is an important one in astrophysics,” said co-lead author Dr Sandro Tacchella from Cambridge’s Cavendish Laboratory. “We’ve had lots of excellent data for the last ten million years and for galaxies in our corner of the universe, but now with Webb, we can get observational data from billions of years back in time, probing the first billion years of cosmic history, which opens up all kinds of new questions.”

The galaxies we observe today grow via two main mechanisms: either they pull in, or accrete, gas to form new stars, or they grow by merging with smaller galaxies. Whether different mechanisms were at work in the early universe is an open question which astronomers are hoping to address with Webb.

“You expect galaxies to start small as gas clouds collapse under their own gravity, forming very dense cores of stars and possibly black holes,” said Tacchella. “As the galaxy grows and star formation increases, it’s sort of like a spinning figure skater: as the skater pulls in their arms, they gather momentum, and they spin faster and faster. Galaxies are somewhat similar, with gas accreting later from larger and larger distances spinning the galaxy up, which is why they often form spiral or disc shapes.”

This galaxy, observed as part of the JADES (JWST Advanced Extragalactic Survey) collaboration, is actively forming stars in the early universe. It has a highly dense core, which despite its relatively young age, is of a similar density to present-day massive elliptical galaxies, which have 1000 times more stars. Most of the star formation is happening further away from the core, with a star-forming ‘clump’ even further out.

The star formation activity is strongly rising toward the outskirts, as the star formation spreads out and the galaxy grows. This type of growth had been predicted with theoretical models, but with Webb, it is now possible to observe it.

“One of the many reasons that Webb is so transformational to us as astronomers is that we’re now able to observe what had previously been predicted through modelling,” said co-author William Baker, a PhD student at the Cavendish. “It’s like being able to check your homework.”

Using Webb, the researchers extracted information from the light emitted by the galaxy at different wavelengths, which they then used to estimate the number of younger stars versus older stars, which is converted into an estimate of the stellar mass and star formation rate.

Because the galaxy is so compact, the individual images of the galaxy were ‘forward modelled’ to take into account instrumental effects. Using stellar population modelling that includes prescriptions for gas emission and dust absorption, the researchers found older stars in the core, while the surrounding disc component is undergoing very active star formation. This galaxy doubles its stellar mass in the outskirts roughly every 10 million years, which is very rapid: the Milky Way galaxy doubles its mass only every 10 billion years.

The density of the galactic core, as well as the high star formation rate, suggest that this young galaxy is rich with the gas it needs to form new stars, which may reflect different conditions in the early universe.

“Of course, this is only one galaxy, so we need to know what other galaxies at the time were doing,” said Tacchella. “Were all galaxies like this one? We’re now analysing similar data from other galaxies. By looking at different galaxies across cosmic time, we may be able to reconstruct the growth cycle and demonstrate how galaxies grow to their eventual size today.”

Reference:
William M. Baker, Sandro Tacchella, et al. ‘A core in a star-forming disc as evidence of inside-out growth in the early Universe.’ Nature Astronomy (2024). DOI: 10.1038/s41550-024-02384-8

Astronomers have used the NASA/ESA James Webb Space Telescope (JWST) to observe the ‘inside-out’ growth of a galaxy in the early universe, only 700 million years after the Big Bang.

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The collaboration, which includes researchers from the University of Cambridge, aims to accelerate progress on new neuro-technologies, including miniaturised brain implants designed to treat depression, dementia, chronic pain, epilepsy and injuries to the nervous system.

Neurological and mental health disorders will affect four in every five people in their lifetimes, and present a greater overall health burden than cancer and cardiovascular disease combined. For example, 28 million people in the UK are living with chronic pain and 1.3 million people with traumatic brain injury.

Neuro-technology – where technology is used to control the nervous system - has the potential to deliver new treatments for these disorders, in much the same way that heart pacemakers, cochlear implants and spinal implants have transformed medicine in recent decades.

The technology can be in the form of electronic brain implants that reset abnormal brain activity or help deliver targeted drugs more effectively, brain-computer interfaces that control prosthetic limbs, or technologies that train the patient’s own cells to fight disease. ARIA’s Scalable Neural Interfaces opportunity space is exploring ways to make the technology more precise, less invasive, and applicable to a broader range of diseases.

Currently, an implant can only interact with large groups of neurons, the cells that transmit information around the brain. Building devices that interact with single neurons will mean a more accurate treatment. Neuro-technologies also have the potential to treat autoimmune disorders, including rheumatoid arthritis, Crohn’s disease and type-1 diabetes.

The science of building technology small enough, precise enough and cheap enough to make a global impact requires an environment where the best minds from across the UK can collaborate, dream up radical, risky ideas and test them without fear of failure.

Professor George Malliaras from the University of Cambridge’s Department of Engineering is one of the project leaders. “Miniaturised devices have the potential to change the lives of millions of people currently suffering from neurological conditions and diseases where drugs have no effect,” he said. “But we are working at the very edge of what is possible in medicine, and it is hard to find the support and funding to try radical, new things. That is why the partnership with ARIA is so exhilarating, because it is giving brilliant people the tools to turn their original ideas into commercially viable devices that are cheap enough to have a global impact.”

Cambridge’s partnership with ARIA will create a home for original thinkers who are struggling to find the funding, space and mentoring needed to stress-test their radical ideas. The three-year partnership is made up of two programmes:

The Fellowship Programme (up to 18 fellowships)

Blue Sky Fellows – a UK-wide offer - we will search the UK for people from any background, with a radical idea in this field and the plan and personal skills to develop it. The best people will be offered a fellowship with the funding to test their ideas in Cambridge rapidly. These Blue Sky Fellows will receive mentorship from our best medical, scientific and business experts and potentially be offered accommodation at a Cambridge college. We will be looking for a specific type of person to be a Blue Sky Fellow. They must be the kind of character who thinks at the very edge of the possible, who doesn’t fear failure, and whose ideas have the potential to change billions of lives, yet would struggle to find funding from existing sources. Not people who think outside the box, more people who don’t see a box at all.

Activator Fellows - a UK-wide offer - those who have already proved that their idea can work, yet need support to turn it into a business, will be invited to become Activator Fellows. They will be offered training in entrepreneurial skills including grant writing, IP management and clinical validation, so their innovation can be ready for investment.

The Ecosystem Programme

The Ecosystem Programme is about creating a vibrant, UK-wide neurotechnology community where leaders from business, science, engineering, academia and the NHS can meet, spark ideas and form collaborations. This will involve quarterly events in Cambridge, road trip events across the UK and access to the thriving online Cambridge network, Connect: Health Tech.

“This unique partnership is all about turning radical ideas into practical, low-cost solutions that change lives,” said Kristin-Anne Rutter, Executive Director of Cambridge University Health Partners. “Cambridge is fielding its best team to make this work and using its networks to bring in the best people from all over the UK. From brilliant scientists to world-leading institutes, hospitals and business experts, everyone in this collaboration is committed to the ARIA partnership because, by working together, we all see an unprecedented opportunity to make a real difference in the world.”

“Physical and mental illnesses and diseases that affect the brain such as dementia are some of the biggest challenges we face both as individuals and as a society,” said Dr Ben Underwood, Associate Professor of Psychiatry at the University of Cambridge and Honorary Consultant Psychiatrist at Cambridgeshire and Peterborough NHS Foundation Trust. “This funding will bring together different experts doing things at the very limits of science and developing new technology to improve healthcare. We hope this new partnership with the NHS will lead to better care and treatment for people experiencing health conditions.”

Cambridge partners in the project include the Departments of Engineering and Psychiatry, Cambridge Neuroscience, the Milner Therapeutics Institute, the Maxwell Centre, Cambridge University Health Partners (CUHP), Cambridge Network, the Babraham Research Campus, Cambridgeshire and Peterborough NHS Foundation Trust, and Vellos. 

A team from across the Cambridge life sciences, technology and business worlds has announced a multi-million-pound, three-year collaboration with the Advanced Research and Invention Agency (ARIA), the UK government’s new research funding agency.

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In 2020, Hassabis and Jumper of Google DeepMind presented an AI model called AlphaFold2. With its help, they have been able to predict the structure of virtually all the 200 million proteins that researchers have identified.

Since their breakthrough, AlphaFold2 has been used by more than two million people from 190 countries. Among a myriad of scientific applications, researchers can now better understand antibiotic resistance and create images of enzymes that can decompose plastic.

The duo received the Nobel along with Professor David Baker of the University of Washington, who succeeded in using amino acids to design a new protein in 2003.

Sir Demis Hassabis read Computer Science as an undergraduate at Queens' College, Cambridge, matriculating in 1994. He went on to complete a PhD in cognitive neuroscience at University College London and create the videogame company Elixir Studios.

Hassabis co-founded DeepMind in 2010, a company that devel­oped masterful AI models for popular boardgames. The company was sold to Google in 2014 and, two years later, DeepMind came to global attention when the company achieved what many then believed to be the holy grail of AI: beating the champion player of one of the world’s oldest board­games, Go.

In 2014, Hassabis was elected as a Fellow Benefactor and, later, as an Honorary Fellow of Queens' College. In 2024, he was knighted by the King for services to artificial intelligence.

In 2018, the University announced the establishment of a DeepMind Chair of Machine Learning, thanks to a benefaction from Hassabis’s company, and appointed Professor Neil Lawrence to the position the following year.

“I have many happy memories from my time as an undergraduate at Cambridge, so it’s now a real honour for DeepMind to be able to contribute back to the Department of Computer Science and Technology and support others through their studies,” said Hassabis in 2018.   

“It is wonderful to see Demis’s work recognised at the highest level — his contributions have been really transformative across many domains. I’m looking forward to seeing what he does next!” said Professor Alastair Beresford, Head of the Department of Computer Science and Technology and Robin Walker Fellow in Computer Science at Queens' College.

In a statement released by Google DeepMind following the announcement by the Nobel committee, Hassabis said: "I’ve dedicated my career to advancing AI because of its unparalleled potential to improve the lives of billions of people... I hope we'll look back on AlphaFold as the first proof point of AI's incredible potential to accelerate scientific discovery."

Dr John Jumper completed an MPhil in theoretical condensed matter physics at Cambridge's famous Cavendish Laboratory in 2008, during which time he was a member of St Edmund’s College, before going on to receive his PhD in Chemistry from the University of Chicago.

"Computational biology has long held tremendous promise for creating practical insights that could be put to use in real-world experiments," said Jumper, Director of Google DeepMind, in a statement released by the company. "AlphaFold delivered on this promise. Ahead of us are a universe of new insights and scientific discoveries made possible by the use of AI as a scientific tool." 

“The whole of the St Edmund’s community joins me in congratulating our former Masters student Dr John Jumper on this illustrious achievement – the most inspiring example imaginable to our new generation of students as they go through their matriculation this week,” said St Edmund’s College Master, Professor Chris Young.

Professor Deborah Prentice, Vice-Chancellor of the University of Cambridge: “I’d like to congratulate Demis Hassabis and John Jumper, who, alongside Geoffrey Hinton yesterday, are all alumni of our University. Together, their pioneering work in the development and application of machine learning is transforming our understanding of the world around us. They join an illustrious line-up of Cambridge people to have received Nobel Prizes – now totalling 125 individuals – for which we can be very proud.”

Article updated on 10 October 2024 to reflect that the number of Cambridge people to have received Nobel Prizes now totals 125.

Two University alumni, Sir Demis Hassabis and Dr John Jumper, have been jointly awarded this year’s Nobel Prize in Chemistry for developing an AI model to solve a 50-year-old problem: predicting the complex structures of proteins.

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Hinton (King’s 1967) and Hopfield were awarded the prize ‘for foundational discoveries and inventions that enable machine learning with artificial neural networks.’ Hinton, who is known as the ‘Godfather of AI’ is Emeritus Professor of Computer Science at the University of Toronto. 

This year’s two Nobel Laureates in Physics have used tools from physics to develop methods that are the foundation of today’s powerful machine learning. John Hopfield, a Guggenheim Fellow at the University of Cambridge in 1968-1969, created an associative memory that can store and reconstruct images and other types of patterns in data. Geoffrey Hinton invented a method that can autonomously find properties in data, and perform tasks such as identifying specific elements in pictures.

When we talk about artificial intelligence, we often mean machine learning using artificial neural networks. This technology was originally inspired by the structure of the brain. In an artificial neural network, the brain’s neurons are represented by nodes that have different values. These nodes influence each other through con­nections that can be likened to synapses and which can be made stronger or weaker. The network is trained, for example by developing stronger connections between nodes with simultaneously high values. This year’s laureates have conducted important work with artificial neural networks from the 1980s onward.

Geoffrey Hinton used a network invented by John Hopfield as the foundation for a new network: the Boltzmann machine. This can learn to recognise characteristic elements in a given type of data. Hinton used tools from statistical physics, the science of systems built from many similar components. The machine is trained by feeding it examples that are very likely to arise when the machine is run. The Boltzmann machine can be used to classify images or create new examples of the type of pattern on which it was trained. Hinton has built upon this work, helping initiate the current explosive development of machine learning.

Vice-Chancellor Professor Deborah Prentice said:

“Many congratulations to Professor Hinton on receiving the Nobel Prize. Our alumni are a vital part of the Cambridge community, and many of them, like Professor Hinton, have made discoveries and advances that have genuinely changed our world. On behalf of the University of Cambridge, I congratulate him on this enormous accomplishment.”

“The laureates’ work has already been of the greatest benefit. In physics we use artificial neural networks in a vast range of areas, such as developing new materials with specific properties,” says Ellen Moons, Chair of the Nobel Committee for Physics. Hinton and Hopfield are the 122nd and 123rd Members of the University of Cambridge to be awarded the Nobel Prize. 

From 1980 to 1982, Hinton was a Scientific Officer at the MRC Applied Psychology Unit (as the MRC Cognition and Brain Sciences Unit was then known), before taking up a position at Carnegie Mellon University in Pittsburgh.

In May 2023, Hinton gave a public lecture at the University's Centre for the Study of Existential Risk entitled 'Two Paths to Intelligence', in which he argued that "large scale digital computation is probably far better at acquiring knowledge than biological computation and may soon be much more intelligent than us". 

Geoffrey Hinton, an alumnus of the University of Cambridge, was awarded the 2024 Nobel Prize in Physics, jointly with John Hopfield of Princeton University.

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Using ultra-high-resolution scanners that can see the living brain in fine detail, researchers from the Universities of Cambridge and Oxford were able to observe the damaging effects Covid-19 can have on the brain.

The study team scanned the brains of 30 people who had been admitted to hospital with severe Covid-19 early in the pandemic, before vaccines were available. The researchers found that Covid-19 infection damages the region of the brainstem associated with breathlessness, fatigue and anxiety.

The powerful MRI scanners used for the study, known as 7-Tesla or 7T scanners, can measure inflammation in the brain. Their results, published in the journal Brain, will help scientists and clinicians understand the long-term effects of Covid-19 on the brain and the rest of the body. Although the study was started before the long-term effects of Covid were recognised, it will help to better understand this condition.

The brainstem, which connects the brain to the spinal cord, is the control centre for many basic life functions and reflexes. Clusters of nerve cells in the brainstem, known as nuclei, regulate and process essential bodily functions such as breathing, heart rate, pain and blood pressure.

“Things happening in and around the brainstem are vital for quality of life, but it had been impossible to scan the inflammation of the brainstem nuclei in living people, because of their tiny size and difficult position.” said first author Dr Catarina Rua, from the Department of Clinical Neurosciences. “Usually, scientists only get a good look at the brainstem during post-mortem examinations.”

“The brainstem is the critical junction box between our conscious selves and what is happening in our bodies,” said Professor James Rowe, also from the Department of Clinical Neurosciences, who co-led the research. “The ability to see and understand how the brainstem changes in response to Covid-19 will help explain and treat the long-term effects more effectively.”

In the early days of the Covid-19 pandemic, before effective vaccines were available, post-mortem studies of patients who had died from severe Covid-19 infections showed changes in their brainstems, including inflammation. Many of these changes were thought to result from a post-infection immune response, rather than direct virus invasion of the brain.  

“People who were very sick early in the pandemic showed long-lasting brain changes, likely caused by an immune response to the virus. But measuring that immune response is difficult in living people,” said Rowe. “Normal hospital-type MRI scanners can’t see inside the brain with the kind of chemical and physical detail we need.”

“But with 7T scanners, we can now measure these details. The active immune cells interfere with the ultra-high magnetic field, so that we’re able to detect how they are behaving,” said Rua. “Cambridge was special because we were able to scan even the sickest and infectious patients, early in the pandemic.”

Many of the patients admitted to hospital early in the pandemic reported fatigue, breathlessness and chest pain as troubling long-lasting symptoms. The researchers hypothesised these symptoms were in part the result of damage to key brainstem nuclei, damage which persists long after Covid-19 infection has passed.

The researchers saw that multiple regions of the brainstem, in particular the medulla oblongata, pons and midbrain, showed abnormalities consistent with a neuroinflammatory response. The abnormalities appeared several weeks after hospital admission, and in regions of the brain responsible for controlling breathing.

“The fact that we see abnormalities in the parts of the brain associated with breathing strongly suggests that long-lasting symptoms are an effect of inflammation in the brainstem following Covid-19 infection,” said Rua. “These effects are over and above the effects of age and gender, and are more pronounced in those who had had severe Covid-19.”

In addition to the physical effects of Covid-19, the 7T scanners provided evidence of some of the psychiatric effects of the disease. The brainstem monitors breathlessness, as well as fatigue and anxiety. “Mental health is intimately connected to brain health, and patients with the most marked immune response also showed higher levels of depression and anxiety,” said Rowe. “Changes in the brainstem caused by Covid-19 infection could also lead to poor mental health outcomes, because of the tight connection between physical and mental health.”

The researchers say the results could aid in the understanding of other conditions associated with inflammation of the brainstem, like MS and dementia. The 7T scanners could also be used to monitor the effectiveness of different treatments for brain diseases.

“This was an incredible collaboration, right at the peak of the pandemic, when testing was very difficult, and I was amazed how well the 7T scanners worked,” said Rua. “I was really impressed with how, in the heat of the moment, the collaboration between lots of different researchers came together so effectively.”

The research was supported in part by the NIHR Cambridge Biomedical Research Centre, the NIHR Oxford Biomedical Research Centre, and the University of Oxford COVID Medical Sciences Division Rapid Response Fund.

Reference:
Catarina Rua et al. ‘7-Tesla quantitative susceptibility mapping in COVID-19: brainstem effects and outcome associations.’ Brain (2024). DOI: 10.1093/brain/awae215

Damage to the brainstem – the brain’s ‘control centre’ – is behind long-lasting physical and psychiatric effects of severe Covid-19 infection, a study suggests.

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Cambridge aspires to create a positive research culture where all staff working in research, whether in academic, technical or support roles, feel welcomed, supported and able to give of their best. The Research Culture Celebration event aims to recognise and celebrate the good practice that is already happening, and to inspire further efforts across the University.

The original idea for the nominations and event (where those honoured are put forward by their colleagues) was part of the Action Research on Research Culture (ARRC) project’s study on researcher development. The ARRC project is one of several initiatives to nurture and promote positive research culture at Cambridge. 

See the full list of nominees

The event coincides with the launch of a wider programme of work being led by the University's Research Culture Team. Four priority areas have been identified. These are: 

- Precarity: how do we address the issues created by fixed-term contracts in early research careers? 

- Access & Participation: who gets to do research? Can everyone fully participate as is expected of them? 

- Challenging interpersonal and group dynamics: how do we support researchers who are struggling with difficult research dynamics? How do we support leaders to change? 

- Time & space: how do we ensure people have the time and space to embody and enact good research culture? 

This year the Research Steering Committee, which oversees the work, is expecting to allocate between £600,000 and £700,000 to facilitate research culture activities around the University. It will also contact individual departments to better understand the concerns they have around research culture. If you would like to be involved, please contact the research culture team. 

For more about the event, including a gallery of images, see the Staff Hub (Cambridge users only; University login required).

Colleagues from across the University were recognised for their contributions to research culture at the inaugural Research Culture Celebration event on 30 September.

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A Memorandum of Understanding – first signed between the institutions in 2009 to formally recognise their decades-long partnership – was renewed during a ceremony at the Belgian Embassy in London.

The relationship was first established in 1965 by the Belgian public interest organisation Fondation Wiener-Anspach (FWA), and since then students, researchers and academics have travelled across the Channel in both directions as part of academic exchanges.

The FWA promotes the development of scientific exchanges between the ULB and the universities of Oxford and Cambridge by awarding fellowships and grants, and by supporting research collaborations in all fields. It also organises conferences and encourages contacts between academics by funding short-term visits.

The ceremony was attended by Professor Deborah Prentice, Vice-Chancellor of Cambridge University; Professor Irene Tracey, Vice-Chancellor of Oxford University; Professor Anne Weyembergh, Vice-Rector for External Relations and Cooperation (ULB); Professor Didier Viviers, President of Fondation Wiener-Anspach, and Bruno van der Pluijm, Belgian Ambassador to the UK.

Speaking at the ceremony, Professor Prentice, said: “The partnership has allowed students and scholars in Brussels, in Cambridge and Oxford to find a firm footing in the world of academia and beyond. In the years ahead, I am confident that it will continue to enable new accomplishments and scientific breakthroughs, as well as the creation of innovative businesses and the nurturing of careers in public service on both sides of the Channel.”

The Vice-Chancellors of Cambridge and Oxford universities reaffirmed a triple partnership with Université Libre de Bruxelles (ULB) that has supported world-class research through cross-border collaborations for more than half a century.

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This landmark achievement has been conducted by the FlyWire Consortium, a large international collaboration including researchers from the University of Cambridge, the MRC Laboratory of Molecular Biology in Cambridge, Princeton University, and the University of Vermont. It is published today in two papers in the journal Nature.

The diagram of all 139,255 neurons in the adult fly brain is the first of an entire brain for an animal that can walk and see. Previous efforts have completed the whole brain diagrams for much smaller brains, for example a fruit fly larva which has 3,016 neurons, and a nematode worm which has 302 neurons.

The researchers say the whole fly brain map is a key first step to completing larger brains. Since the fruit fly is a common tool in research, its brain map can be used to advance our understanding of how neural circuits work.

Dr Gregory Jefferis, from the University of Cambridge and the MRC Laboratory of Molecular Biology, one of the co-leaders of the research, said: “If we want to understand how the brain works, we need a mechanistic understanding of how all the neurons fit together and let you think. For most brains we have no idea how these networks function. 

“Flies can do all kinds of complicated things like walk, fly, navigate, and the males sing to the females. Brain wiring diagrams are a first step towards understanding everything we’re interested in – how we control our movement, answer the telephone, or recognise a friend.”

Dr Mala Murthy from Princeton University, one of the co-leaders of the research, said: “We have made the entire database open and freely available to all researchers. We hope this will be transformative for neuroscientists trying to better understand how a healthy brain works. In the future we hope that it will be possible to compare what happens when things go wrong in our brains, for example in mental health conditions.” 

Dr Marta Costa from the University of Cambridge, who was also involved in the research, said “This brain map, the biggest so far, has only been possible thanks to technical advances that didn’t seem possible ten years ago. It is a true testament to the way that innovation can drive research forward. The next steps will be to generate even bigger maps, such as a mouse brain, and ultimately, a human one.”

The scientists found that there were substantial similarities between the wiring in this map and previous smaller-scale efforts to map out parts of the fly brain. This led the researchers to conclude that there are many similarities in wiring between individual brains – that each brain isn’t a unique structure.

When comparing their brain diagram to previous diagrams of small areas of the brain, the researchers also found that about 0.5% of neurons have developmental variations that could cause connections between neurons to be mis-wired. The researchers say it will be important to understand, through future research, if these changes are linked to individuality or brain disorders. 

Making the map

A whole fly brain is less than one millimetre wide. The researchers started with one female brain cut into seven thousand slices, each only 40 nanometres thick, that were previously scanned using high resolution electron microscopy in the laboratory of project co-leader Davi Bock at Janelia Research Campus in the US.

Analysing over 100 terabytes of image data (equivalent to the storage in 100 typical laptops) to extract the shapes of about 140,000 neurons and 50 million connections between them is too big a challenge for humans to complete manually. The researchers built on AI developed at Princeton University to identify and map neurons and their connections to each other.

However, the AI still makes many errors in datasets of this size. The Princeton University researchers established the FlyWire Consortium – made up of teams in more than 76 laboratories and 287 researchers around the world, as well as volunteers from the general public – which spent an estimated 33 person-years painstakingly proofreading all the data.

Dr Sebastian Seung, from Princeton University, who was one of the co-leaders of the research, said: “Mapping the whole brain has been made possible by advances in AI computing - it would have not been possible to reconstruct the entire wiring diagram manually. This is a display of how AI can move neuroscience forward. The fly brain is a milestone on our way to reconstructing a wiring diagram of a whole mouse brain.”

The researchers also annotated many details on the wiring diagram, such as classifying more than 8,000 cell types across the brain. This allows researchers to select particular systems within the brain for further study, such as the neurons involved in sight or movement. 

Dr Philipp Schlegel, the first author of one of the studies, from the MRC Laboratory of Molecular Biology, said: “This dataset is a bit like Google Maps but for brains: the raw wiring diagram between neurons is like knowing which structures on satellite images of the Earth correspond to streets and buildings. Annotating neurons is like adding the names for streets and towns, business opening times, phone numbers and reviews to the map – you need both for it to be really useful.”

Simulating brain function

This is also the first whole brain wiring map – often called a connectome – to predict the function of all the connections between neurons. 

Neurons use electrical signals to send messages. Each neuron can have hundreds of branches that connect it to other neurons. The points where these branches meet and transmit signals between neurons are called synapses. There are two main ways that neurons communicate across synapses: excitatory (which promotes the continuation of the electrical signal in the receiving neuron), or inhibitory (which reduces the likelihood that the next neuron will transmit signals).

Researchers from the team used AI image scanning technology to predict whether each synapse was inhibitory or excitatory.

Dr Gregory Jefferis added: “To begin to simulate the brain digitally, we need to know not only the structure of the brain, but also how the neurons function to turn each other on and off.”

“Using our data, which has been shared online as we worked, other scientists have already started trying to simulate how the fly brain responds to the outside world. This is an important start, but we will need to collect many different kinds of data to produce reliable simulations of how a brain functions.”

Associate Professor Davi Bock, one of the co-leaders of the research from the University of Vermont, said: “The hyper-detail of electron microscopy data creates its own challenges, especially at scale. This team wrote sophisticated software algorithms to identify patterns of cell structure and connectivity within all that detail. 

“We now can make precise synaptic level maps and use these to better understand cell types and circuit structure at whole-brain scale. This will inevitably lead to a deeper understanding of how nervous systems process, store and recall information. I think this approach points the way forward for the analysis of future whole-brain connectomes, in the fly as well as in other species."

This research was conducted using a female fly brain. Since there are differences in neuronal structure between male and female fly brains, the researchers also plan to characterise a male brain in the future. 

The principal funders were the National Institutes of Health BRAIN Initiative, Wellcome, Medical Research Council, Princeton University and National Science Foundation.

References

Schlegel, P. et al: Whole-brain annotation and multi-connectome cell typing of Drosophila. Nature, Oct 2024. DOI: 10.1038/s41586-024-07686-5

Dorkenwald, S. et al: Neuronal wiring diagram of an adult brain. Nature, Oct 2024. DOI: 10.1038/s41586-024-07558-y

The first wiring diagram of every neuron in an adult brain and the 50 million connections between them has been produced for a fruit fly.

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Events in Cambridge for Black History Month

Cambridge's Race Equality Lecture

Jesus College, Thursday 31 October

It may seem odd, but we start at the end of the month because this year’s Race Equality Lecture will take place on Thursday 31 October. The lecture is titled “Racism without racists – how racism works in the USA and the western world.” It will be delivered by Eduardo Bonilla-Silva, Professor of Sociology at Duke University and former President of the American Sociological Association. It will take place in the Frankopan Hall at Jesus College and will be available to view online.

Book your place at the Race Equality Lecture

Olaudah Equiano Annual Lecture on Race Justice

Anglia Ruskin University, Wednesday 9 October

Lord Simon Woolley, Principal of Homerton College and co-founder of Operation Black Vote, will deliver the Olaudah Equiano Annual Lecture on Race Justice at Anglia Ruskin University on Wednesday 9 October. The event will take place at the Cambridge campus and starts at 6pm. Lord Woolley is a tireless campaigner for equality, not just for Black communities but all under-represented or marginalised groups. During the event he will discuss the fight for racial equality drawing on his own personal experiences.

Book tickets for the Olaudah Equiano Annual Lecture on Race Justice

Moving beyond stereotypes surrounding Black women

King's College, Thursday 10 October

On the evening of Thursday 10 October, celebrated authors Kelechi Okafor and Afua Hirsch will discuss the challenges and opportunities they have faced when calling out social injustices in their work, with a focus on how their own identities have shaped their activism. They will share insights on the creative processes involved in their writing and how it has impacted on conversations about race, womanhood and justice. 

Reserve a place for the discussion at King's

Collaborative art workshops

Robinson College, Wednesday 16 and Saturday 19 October

For those interested in modern art Robinson College is hosting two collaborative art workshops. The first, on Wednesday 16 October, will be hosted by London artist, Shem, on the theme ‘Black present now’. And then, on Saturday 19 October, the College will host Joshua Obichere, a Cambridge alumnus.

Register your interest in the art workshops

Panel discussion: Black excellence, health and wellness

St Edmund's College, Wednesday 16 October

Also on the afternoon of Wednesday 16 October, St Edmund’s College will be hosting a panel discussion on the themes of Black excellence, health and wellness. Speakers include economist and entrepreneur Ebenezer Ademisoye, clinical scientist, Dr Rafia Al-Lamki and Mastercard Scholar, Godspower Major.

Reserve your ticket for the panel discussion at St Edmund's College

Fireside chat at the Business School

Cambridge Judge Business School, Thursday 17 October

Lord Woolley will participate in a ‘fireside chat’ at the Business School on the afternoon of Thursday 17 October. The event will be chaired by Kamiar Mohaddes and will also include Tabitha Mwangi, Programme Director of the Mastercard Foundation, and Orobosa Isokpan from the Cambridge Africa Business Network. There will be networking opportunities as well but registration is essential.  

Register for the fireside chat at Judge Business School

An exhibition and events at St Catharine's College

St Catharine's College, throughout October

During the entire month of October, St Catharine’s College is hosting an exhibition showcasing the achievements of two prominent Black alumni. The pioneering doctor and civil rights activist Dr Cecil Clarke matriculated in 1914 in the first months of the First World War. Wendell Mottley was an Olympic athlete and economist who served as Trinidad and Tobago’s Finance Minister between 1991 and 1995. The exhibition commemorating them is being held in the Shakeshaft Library.

See the full programme of Black History Month events at St Catharine's College

The Blacktionary Show

Wolfson College, Saturday 19 October

On Saturday 19 October Wolfson College hosts the ‘Blacktionary Show’. Authors Dr Maggie Semple and Jane Oremosu will be discussing their new work ‘My Little Book: A Blacktionary - The pocket guide to the language of race’. The book aims to help break down barriers when it comes to engaging in conversations on race. The event will be introduced by Dr Kenny Monrose, from the University’s Department of Sociology.

Register for the Blacktionary Show

Panel discussion: how organisations promote equality and diversity in the face of a cultural backlash

Homerton College, Tuesday 22 October

On Tuesday 22 October Lord Woolley will again be participating in a discussion being held at Homerton College looking at how companies and other organisations promote equality and diversity in the face of a cultural backlash. Other prominent speakers include the successful businesswomen, Olu Orugboh and Yemi Jackson.

Register for a panel discussion with Lord Woolley

The Trevelyan Lecture: 'Black Genius: Science, Race and the Extraordinary Portrait of Francis Williams'

Bateman Auditorium, Gonville and Caius College 5 pm Friday 25 October (Faculty of History)

Francis Williams was a Jamaican polymath who was born into slavery but ended his life as a gentleman and a scholar. His portrait, dating from the 1740s, shows him surrounded by books and scientific instruments. Was he Cambridge's first Black student? And who commissioned the portrait, and why? Princeton historian, Fara Dabhoiwala, will tackle these questions when he presents new research on the painting and its intriguing sitter. 

Black History Month Academic Seminar

Hughes Hall, Monday 28 October

An opportunity to hear from the College's Black staff and PhD students and celebrate their achievements but also to hear about the challenges facing Black students at Cambridge. One of the main subjects for discussion will be the low numbers of Black academics in the UK. 

More details about the seminar here

The Really Popular Book Club: Mr Loverman by Bernardine Evaristo

Online, Tuesday 29 October

On Tuesday 29 October the University Library’s Really Popular Book Club will be discussing Bernardine Evaristo’s ‘Mr Loverman’. The book follows an Antiguan born immigrant living in Hackney, London, who leads a double life. The discussion will be hosted by Yvonne Battle Felton, Academic Director of Creative Writing at Cambridge’s Institute of Continuing Education. This is an online event.

Sign up for the Really Popular Book Club

Black Advisory Hub events

St John's College, Wednesday 30 October

During the afternoon of Wednesday 30 October, the Black Advisory Hub is hosting a social and afternoon tea for Black students at St John’s College. It's one of many events the Hub is hosting. These include induction sessions for both undergraduates and postgraduates and the prizegiving ceremony for the Bridgetower essay competition.

Visit the Black Advisory Hub to register

Cambridge Students' Union events

St John's College, Thursday 3 October

The Cambridge Students' Union is also hosting several events to mark Black History Month. This opens with a screening of the documentary 'Educationally Subnormal: a British scandal' on Thursday 3 October.

Visit the Cambridge SU to see what's on

Black History Month in Cambridge brings an opportunity to take part in topical discussions, appreciate art and hear from a range of engaging speakers. 

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Celebrating Cambridge’s most recent achievements – and looking ahead to the opportunities and challenges of the future – she emphasised both the University’s “extraordinary significance” in the UK, and the importance of its global outlook.

Professor Prentice used the speech, in Senate House, to announce the Collegiate University’s milestone success in reaching its £500m student support fundraising target, set in 2018.

This vital philanthropic support was transformative, said Professor Prentice, and had already enabled a number of Cambridge widening participation programmes and initiatives – including the Cambridge Foundation Year and scholarships for specific under-represented groups – to ensure the University continues to welcome students with the potential to thrive here, regardless of background. Student health and wellbeing services at Cambridge had also been transformed with generous gifts to the student support fundraising initiative, she said.

The Vice-Chancellor told Senate House: “I have met the students in many of these programmes, so for me, the student support initiative has names, faces, and life stories attached. It’s a thrilling achievement.”

Describing the University as a “national asset”, Professor Prentice went on to highlight Cambridge’s contribution to the rest of the UK, and its economy – estimated at approximately £30 billion a year.

The Vice-Chancellor said Cambridge’s reputation for expertise and world-class research meant it was uniquely placed to become the “go-to location for the world’s leading innovators”, and pointed to the University’s ambitious plans for Cambridge West and for an innovation hub to bring together researchers, entrepreneurs, spin-outs, and funders under one roof to “help solve the world’s biggest challenges”.

Her address also highlighted other significant milestones and initiatives, including the completion of the Ray Dolby Centre, the groundbreaking of the new Whittle Lab, the expansion of the Bennett Institute for Public Policy, and the advanced planning stages of two new hospitals on the Cambridge Biomedical Campus – the Cambridge Cancer Research Hospital and the Cambridge Children’s Hospital.

Professor Prentice finished the address by paying tribute to the University’s current Chancellor, Lord Sainsbury of Turville, who announced last year that he will step down. She expressed the University’s gratitude for “his unwavering service and his commitment to Cambridge.”

Read the full address

Professor Deborah Prentice marked the start of the academic year by delivering the Vice-Chancellor’s annual address to the University.

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The Global Innovation Index (GII) 2024 – which captures the innovation ecosystem performance of 133 economies and tracks the global innovation trends – has ranked Cambridge as the world’s leading science and technological (S&T) cluster by intensity, in relation to its size, for the third consecutive year. San Jose, San Franciso (USA) was named second, unchanged from the 2023 Index, with Eindhoven, (Kingdom of the Netherlands) third.

S&T clusters are established by analysing patent-filing activity and scientific article publication relative to population, and documenting the geographical areas around the world with the highest density of inventors and scientific authors.

According to the Index, the Cambridge cluster filed 6,379 Patent Cooperation Treaty (PCT) patent applications and published 35,000 scientific articles, both per 1 million inhabitants, over the past 5 years.

The University of Cambridge sits at the heart of this cluster, powering world-leading research, driving a vibrant innovation ecosystem, and cultivating a thriving environment for collaboration, services and investment. The University contributes nearly £30 billion to the UK economy annually, including over £23 billion from commercialisation and innovation activities.

According to the Global Innovation Index 2024: “S&T clusters – which can be entire regions or cities – serve as the backbone of a robust national innovation ecosystem. Situated in areas such as San Francisco’s Silicon Valley, Cambridge, Munich and Paris in Europe, or Bengaluru, Seoul, Shenzhen and Tokyo in Asia, these S&T clusters are home to renowned universities, brilliant scientists, R&D-intensive companies, and prolific inventors. It is the collaboration among these entities that results in the groundbreaking scientific advancements.”

Earlier this year, a report by Dealroom revealed that the Cambridge tech ecosystem has a combined value of $191 billion, representing 18% of the entire UK’s tech ecosystem and reinforcing Cambridge’s reputation as Europe’s deep tech leader.

Dr Diarmuid O’Brien, Pro-Vice-Chancellor for Innovation, University of Cambridge, commented:

“It’s great to see this continued recognition of Cambridge as the world’s most intensive science and technological cluster. With its exceptional research and science, people and partners, companies and commitment, Cambridge drives innovation that fuels local, national, and global growth, tackling global challenges and delivering life-changing impact.”

Release first published by Cambridge Enterprise

Cambridge has once again been named as the most intensive science and technological cluster in the world, according to a new report ranking innovation around the globe.

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Sir David said of visiting CCI that he felt “an undercurrent of joy” whenever he came to the conservation campus, which is housed in the building bearing his own name.

The campus was opened in 2016 and is the first of its kind, with over 500 conservation professionals and researchers, from 10 different organisations and the University of Cambridge, all collaborating to stop the biodiversity crisis and build more hopeful futures for people and nature.

Read the full story: 'An Undercurrent of Joy'

Sir David Attenborough spoke of how he feels during visits to the Cambridge Conservation Initiative (CCI) when he stopped by the CCI conservation campus at the University of Cambridge this week.

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Representatives of the Semiconductors Point of Contact Group from the G7 group of nations met in Cambridge on 26 September. The meeting was held at ARM, which designs over 95% of the processors in the world. Representatives from the University of Cambridge, as well as representatives from local semiconductor companies, participated in the events.

Semiconductors underpin nearly every electrical, optical and quantum device, from mobile phones and medical equipment to electric vehicles. They are of global strategic significance due to the integral role they play in net zero, artificial intelligence and quantum technology.

The G7 Semiconductor Points of Contact group is dedicated to facilitating information exchange and sharing best practices among G7 members. The PoC Group plans to exchange information on issues impacting the semiconductor industry, including pre-competitive industrial research and development priorities, sustainable manufacturing, the effect of non-market policies and practices, and crisis coordination channels.

Cambridge was chosen for the meeting in part because of its strong innovation ecosystem, which has produced more ‘unicorns’ – privately held startup companies valued at over US$1 billion – than anywhere else in the UK.

A 2023 report found that the University of Cambridge contributes nearly £30 billion to the UK economy annually and supports more than 86,000 jobs across the UK, including 52,000 in the East of England.

For every £1 the University spends, it creates £11.70 of economic impact, and for every £1 million of publicly-funded research income it receives, it generates £12.65 million in economic impact across the UK.

The National Quantum Strategy (2023) and the National Semiconductor Strategy (2023) highlight the UK’s national strengths in quantum and photonic technologies and compound semiconductors. These sectors foster growth and create high-skilled jobs, and position the UK as a hub of global innovation. 

Dr Diarmuid O’Brien, Pro-Vice-Chancellor for Innovation at the University of Cambridge, said: “Semiconductors are a vital technology for the UK’s economic growth, and Cambridge is a leader in semiconductor research and development. Working with our partners in academia, industry and government, we can develop next-generation semiconductor technologies and companies, and train the next generation of semiconductor scientists and engineers.” 

Professor Andrea Ferrari, Director of the Cambridge Graphene Centre, hosted, on behalf of the University, a formal dinner in Pembroke College for the attendees of the G7 Semiconductors group. He stated that: “Cambridge played a key foundational role in the development of electronics. The electron was discovered here in 1897, by JJ Thomson. In 1961, electron beam lithography, a key method for integrated circuit fabrication, was invented in Cambridge. These early achievements were followed by many advances in circuit design, innovative advanced materials, photonic and quantum communications. It is thus fitting that the G7 Semiconductors representatives met at the heart of where all started.”

Science Minister Lord Vallance said: "Semiconductors are an unseen but vital component in so many of the technologies we rely on in our lives and backing UK innovators offers a real opportunity to growth these firms into industry leaders, strengthening our £10 billion sector and ensuring it drives economic growth. Hosting the G7 semiconductors Points of Contact group is also a chance to showcase the UK’s competitive and growing sector and make clear our commitment to keeping the UK at the forefront of advancing technology."

Representatives from the G7 have met in Cambridge to discuss the main priorities for the future development of semiconductors and their impact on the global economy.

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Archaeological fieldwork in Morocco has discovered the earliest, previously unknown 3400–2900 BC farming society from a poorly understood period of north-west African prehistory. This is the earliest and largest agricultural complex yet found in Africa beyond the Nile.

This study, published in the journal Antiquity, reveals for the first time the importance of the Maghreb (north-west Africa) in the emergence of complex societies in the wider Mediterranean during the fourth and third millennia BC.

With a Mediterranean environment, a border with the Sahara desert and the shortest maritime crossing between Africa and Europe, the Maghreb is perfectly located as a hub for major cultural developments and intercontinental connections in the past.

Whilst the region’s importance during the Palaeolithic, Iron Age and Islamic periods is well known, there is a significant gap in knowledge of the archaeology of the Maghreb between c. 4000 and 1000 BC, a period of dynamic change across much of the Mediterranean.

To tackle this, a team of archaeologists led by Prof Cyprian Broodbank from the University of Cambridge, Prof Youssef Bokbot from INSAP, and Prof Giulio Lucarini from CNR-ISPC and ISMEO, have carried out collaborative, multidisciplinary archaeological fieldwork at Oued Beht, Morocco.

"For over thirty years I have been convinced that Mediterranean archaeology has been missing something fundamental in later prehistoric north Africa," said Broodbank. "Now, at last, we know that was right, and we can begin to think in new ways that acknowledge the dynamic contribution of Africans to the emergence and interactions of early Mediterranean societies."

"For more than a century the last great unknown of later Mediterranean prehistory has been the role played by the societies of Mediterranean’s southern, Africa shores west of Egypt," say the authors of the new study. "Our discoveries prove that this gap has been due not to any lack of major prehistoric activity, but to the relative lack of investigation, and publishing. Oued Beht now affirms the central role of the Maghreb in the emergence of both Mediterranean and wider African societies."

These results reveal that the site was the largest agricultural complex from this period in Africa outside of the Nile region. All of the evidence points to the presence of a large-scale farming settlement—similar in size to Early Bronze Age Troy.

The team recovered unprecedented domesticated plant and animal remains, pottery and lithics, all dating to the Final Neolithic period. Excavation also revealed extensive evidence for deep storage pits.

Importantly, contemporaneous sites with similar pits have been found on the other side of the Strait of Gibraltar in Iberia, where finds of ivory and ostrich egg have long pointed to African connections. This suggests that the Maghreb was instrumental in wider western Mediterranean developments during the fourth millennium BC.

Oued Beht and the north-west Maghreb were clearly integral parts of the wider Mediterranean region. As such, these discoveries significantly change our understanding of the later prehistory of the Mediterranean and Africa.

As the authors of the Antiquity article state: “It is crucial to consider Oued Beht within a wider co-evolving and connective framework embracing peoples both sides of the Mediterranean-Atlantic gateway during the later fourth and third millennia BC - and, for all the likelihood of movement in both directions, to recognise it as a distinctively African-based community that contributed substantially to the shaping of that social world.”

arch.jpg

Multi-disciplinary archaeological survey at the site of Oued Beht, Morocco, reveals a previously unknown 3400–2900 BC farming society, shedding new light on North Africa’s role in Mediterranean prehistory. 

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A global conservation effort to reintroduce a tiny snail to the wild is celebrating a momentous milestone: for the first time in 40 years, conservationists have found born-in-the-wild adult Partula tohiveana – meaning the precious molluscs have successfully established themselves in French Polynesia.

This year Cambridge’s Dr Justin Gerlach helped restore over 6,000 of the snails to Moorea, their French Polynesian island home as part of an annual reintroduction of zoo-bred ‘Extinct in the Wild’ and ‘Critically Endangered’ snail species – carried out through collaboration with zoos around the world.

During their work the team found unmarked Partula tohiveana: proof that previously reintroduced snails have successfully bred in the area.

The momentous discovery means Partula tohiveana can now be considered as established – an incredibly rewarding result for 40 years of dedication and collaboration. Conservationists will now begin the process of downlisting the snails from ‘Extinct-in-the-Wild’ to ‘Critically Endangered’ on the IUCN’s Red List.

Very few species have been reintroduced successfully having been completely extinct in the wild. This is also the very first invertebrate species where this has been achieved.

Ten species and sub-species of the tropical snails, reared at London Zoo, Bristol Zoological Society, Detroit Zoological Society, Marwell Wildlife, the Royal Zoological Society of Scotland, Saint Louis Zoo, Sedgwick County Zoo, Woodland Park Zoo and Zoo Schwerin, travelled more than 15,000km to Tahiti at the beginning of September. Before making the two-day journey to the islands of Tahiti, Moorea and Huahine, the incredibly rare snails, which each measure a tiny 1-2cm in length, were individually counted and marked with a dot of red UV reflective paint. The ‘snail varnish’ glows under UV torchlight, helping conservationists in the field to spot and monitor the nocturnal snails at night, when they’re most active.

London Zoo’s Senior Curator of Invertebrates, Paul Pearce-Kelly, who leads the Partula conservation programme, said: “Though little, these snails have great cultural, scientific and conservation value. Partula snails have always been part of Polynesia’s rich cultural heritage and play an important role in the ecological health of their forest habitats. They’ve also been studied for over a century for the insights they give into how species evolve in isolated environments. Most recently, they’re providing a valuable conservation model for helping hundreds of endangered island species.”

He added: “This collaborative conservation effort is playing a crucial role in saving these species from extinction. It’s a powerful example of how conservation zoos can combat biodiversity loss. At a time when nature faces unprecedented challenges, these small snails are a symbol of hope for global wildlife.”

Partula snails - also known as Polynesian tree snails - eat decaying plant tissue and fungi, so play an important role in maintaining forest health. Returning these rare snails back to the wild helps to restore the ecological balance in these islands.

Dr Justin Gerlach of Peterhouse, University of Cambridge and an Academic Associate at the University's Museum of Zoology, said: “Discovering wild-born adult snails was a great moment. Very few animal species have been re-established back in the wild so this is a fantastic achievement for the programme – the fruit of a vast amount of work.”

Conservation zoos are working with the French Polynesian Government’s Direction de l’environnement, to save Partula snails from extinction. In the 1980s and early 1990s, these snails faced a critical threat after the invasive rosy wolf snail (Euglandina rosea) was introduced to control the African giant land snail (Lissachatina fulica). Unfortunately, the predatory species targeted the native snails instead, leading to the extinction or near-extinction of many Partula species across the region.

In the early 1990s, the last remaining individuals of several Partula species were rescued by London and Edinburgh Zoos, launching an international conservation breeding programme. This collaboration between 15 zoos cares for 15 species and subspecies, most of which are classified as ‘Extinct-in-the-Wild’. These rescued snails, along with those already being studied at universities in the UK and North America, became the foundation for reintroducing the species back onto their native island homes.

Paul said: “After decades of caring for these species in conservation zoos and working with the Direction de l’environnement to prepare the islands, we started reintroducing Partula snails back into their lowland tropical forests almost 10 years ago. Since then, we’ve reintroduced over 30,000 snails, including 10 Extinct-in-the-Wild species and subspecies, with this year’s release being the largest so far, thanks to our international team and collaborators, including mollusc specialist Dr Justin Gerlach of Peterhouse, University of Cambridge.”

London Zoo’s coordination of the Partula snail reintroduction project is made possible due to funding from supporters including the Players of the People’s Postcode Lottery, who have enabled London Zoo to continue bringing species back from the brink of extinction.

Adapted from a press release by the Zoological Society of London.

A species of tropical tree snail is no longer extinct in the wild following a successful reintroduction project.

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The ongoing war in Gaza will set children and young people’s education back by up to 5 years and risks creating a lost generation of permanently traumatised Palestinian youth, a new study warns.

The report, by a team of academics working in partnership with the United Nations Relief and Works Agency for Palestinian Refugees in the Near East (UNRWA), is the first to comprehensively quantify the war’s toll on learning since it began in October 2023. It also details the devastating impact on children, young people and teachers, supported by new accounts from frontline staff and aid workers.

The study was a joint undertaking involving researchers at the Faculty of Education, University of Cambridge and the Centre for Lebanese Studies, in partnership with UNRWA. It shows that Gaza’s children have already lost 14 months of education since 2019 due to COVID-19, earlier Israeli military operations, and the current war.

On this basis and using information such as global post-COVID-19 education recovery data, the researchers model several potential futures for Gaza’s younger generation, depending on when the war ends and how quickly the education system is restored.

The most optimistic prediction – assuming an immediate ceasefire and rapid international effort to rebuild the education system – is that students will lose 2 years of learning. If the fighting continues until 2026, the losses could stretch to 5 years. This does not account for the additional effects of trauma, hunger and forced displacement, all of which are deepening Gaza’s education crisis.

Without urgent, large-scale international support for education, the researchers suggest that there is a significant threat not just to students’ learning, but their overall faith in the future and in concepts such as human rights. Despite this, the study shows that education has been deprioritised in international aid efforts, in favour of other areas. “Education, simply put, is not seen as lifesaving,” the report warns.

Professor Pauline Rose, Director of the Research for Equitable Access and Learning (REAL) Centre, University of Cambridge, said: “Palestinian education is under attack in Gaza. Israeli military operations have had a significant effect on learning.”

“As well as planning for how we rebuild Gaza’s shattered education system, there is an urgent need to get educational support for children now. Education is a right for all young people. We have a collective responsibility to protect it.”

According to the United Nations Office for the Coordination of Humanitarian Affairs, more than 10,600 children and 400 teachers had been killed in Israeli military operations by August 2024, and more than 15,300 students and 2,400 teachers injured. Hundreds of thousands of young people have been displaced and are living in shelters.

Satellite images analysed by the Occupied Palestinian Territory Education Cluster have verified that over 90 per cent of schools have been damaged, many beyond repair. Since August, UNRWA has provided education in the shelters, reaching about 8,000 children, but the study warns that much more is needed to mitigate lost learning, which was already considerable following COVID-19.

The researchers calculate that 14 months of lost schooling so far have increased ‘learning poverty’ – the proportion of children unable to read a basic text by age 10 – by at least 20 percentage points. The accurate figure may be even higher, as the calculation does not account for the wider impacts of the war on children and teachers.

The study draws together information from different sources and includes a comprehensive involvement of the Education Cluster and Cluster partners sharing their inputs, challenges and progress to enrich the report. The report provides a comprehensive overview of those broader effects. It highlights the devastating psychological consequences for Palestinian children who were already living ‘in constant fear and lack of hope’ after 17 years of blockade, according to a 2022 report by Save The Children.

Professor Maha Shuayb, Director of the Centre for Lebanese Studies, said: “Young people’s prospects in Gaza are being extinguished and our findings show that with it they are losing hope. Education is central to stabilising that spiral of decline. If it is simply erased, the consequences will be far-reaching.”

Save The Children has estimated that more than 10 children per day have lost limbs since the war began. The report warns of rising numbers of less visible disabilities, which will put further strain on an education system ill-equipped to support children with special needs.

The study suggests that continuous shock and suffering are now shaping children’s outlook and world views. Interviewees reported some children questioning values such as equality, human rights and tolerance when these are taught in the shelters. “This is a full generation of trauma,” one humanitarian aid official said; “it will take a generation to overcome it.”

The report highlights the immense suffering teachers and counsellors have endured physically and mentally. The killings, displacement and daily realities of life during war have taken a tremendous toll on their ability to engage meaningfully in education and will, it says, adversely affect reconstruction efforts.

Professor Yusuf Sayed, from the University of Cambridge, said: “It is important to recognise teachers and counsellors have, like the rest of the population, suffered immensely. There is evidence of extraordinary commitment from educators striving to maintain learning, but inevitably the deprivation, killings and hardship are affecting their ability to do so.”

Despite a flash appeal from the United Nations Office for the Coordination of Humanitarian Affairs (OCHA), the analysis shows that just 3.5 per cent of aid for Gaza has been invested in education. Major donors like the US and Germany have neglected education in their aid packages, and blockades continue to hinder the delivery of resources on the ground.

Without more funding and access to learning, structured play and other forms of support, the report warns, the long-term repercussions for Gaza’s next generation will only worsen.

It calls for immediate steps focusing on the resumption of education, which include providing counselling, safe learning spaces, and support for students and educators with disabilities. It also calls for an immediate and permanent ceasefire and an end to occupation, in line with the International Court of Justice advisory opinion and UN recently-adopted resolution, as only then can Gaza’s education system be rebuilt. This will require a focus on recruiting more teachers and counsellors to cope with the scale of learning loss and trauma suffered by children and young people.

“Education is the only asset the Palestinian people have not been dispossessed of. They have proudly invested in the education of their children in the hope for a better future. Today, more than 625,000 deeply traumatised school-aged children are living in the rubble in Gaza. Bringing them back to learning should be our collective priority. Failing to do that will not only lead to a lost generation but also sow the seeds for more extremism, hatred and violence”, said Philippe Lazzarini, UNRWA Commissioner General.

The study also stresses that Palestinians themselves must lead the education recovery. “A ceasefire is the key for the success of any human development activity in Gaza, including education,” the authors write. “Children have seen that the international community will sit idly by as they are killed. This has left them with questions about values that schools and learning aim to instil around humanitarian principles that teachers will have to navigate.”

The full report, Palestinian Education Under Attack in Gaza: Restoration, Recovery, Rights and Responsibilities in and through Education, is now available online. 

Ongoing war in Gaza will set children and young people’s education back by up to 5 years, report suggests.

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The study, published in Energy Research & Social Science, was completed shortly before the Winter Fuel Payment vote was taken, by researchers from the University of Cambridge and Delft University of Technology (TU Delft).

The researchers raise particular concerns about the impact of the policy on pensioners with annual incomes of between £11,300–£15,000 for single pensioners and £17,300–£22,000 for couples.

Drawing on data from the English Housing Survey, which sampled nearly 12,000 households across all income groups, the study investigated how income, energy efficiency, home size, household type, and tenure status impacted on energy expenditure.

The researchers found that an increase of £1 per year in income (after housing costs, tax and welfare payments) was associated with a marginal increase in heating spending of about one-tenth of a penny.

The study also found that just a small energy efficiency improvement – a one-point increase in the SAP12 rating (The Government's Standard Assessment Procedure for Energy Rating of Dwellings – had a major impact on households in energy poverty, offering an average reduction in annual heating costs of £21.59 per year.

Floor area also had an impact. The researchers found that a one square metre increase was associated with an annual increase in heating spend of £5.04 per year, for households facing energy poverty, making this the worst affected group. This compares with £4.18 per year for high-income households, £3.65 per year for low-income households, and £2.99 per year for very low-income households not in energy poverty.

“When low-income households receive more income, they generally spend a little more to warm their homes. But these households often have to spread any extra money they have across other essential needs including food,” said lead author, Dr Ray Galvin, affiliated with Cambridge Institute for Sustainability Leadership (CISL).

“A reduction in income like the loss of the Winter Fuel Payment could force low-income pensioners to cut back not only on heating but also on other basic necessities. This poses a significant risk to people who are particularly vulnerable to the effects of living in cold homes.”

Energy efficiency

Across all household types, the researchers found that the energy efficiency of the dwelling had by far the biggest impact on heating expenditure.

“The most effective strategy to warm up the homes of people living energy poverty is to increase the energy performance of their dwellings,” said Professor Minna Sunikka-Blank, from Cambridge’s Department of Architecture.

Specifically, the authors advise that the SAP12 rating of homes need to be increased to at least 72.

Each increase in SAP12 energy efficiency rating corresponds to a reduction in heating costs of around £20 per year, meaning that for households in energy poverty, with an average SAP12 rating of 59.48, increasing the rating to the level of low-income households not in energy poverty, 71.45, could reduce heating costs by about £240 per year.

The authors make clear that energy savings would not be sufficient to pay for these energy-efficiency upgrades. They would require targeted financial support.

Dr Galvin said: “Government and society may well find that these costs are paid back to the country through co-benefits of fewer days off work, longer lives and less strain on the health service.”

While this would not improve the finances of households in energy poverty as much as the direct monetary allowances such as the Winter Fuel Payment, it would, the authors argue, make a substantial, direct impact on cold, unhealthy homes.

Dr Galvin said: “There needs to be extra focus on developing policies for the long-term solution of retrofitting energy-inefficient homes. This can provide enduring reductions in energy bills while also improving thermal comfort. This approach may also align better with the goal of reducing carbon emissions and tackling climate change.”

Prof Minna Sunikka-Blank said: “Without retrofit initiatives, energy poverty will persist in the UK, because in low-income households immediate needs often take precedence over thermal comfort, even when incomes increase.”

Home size

The study found that households in energy poverty have a 7.3% larger average floor area than low-income households not in energy poverty, and that floor area makes a substantial difference to heating energy costs (about half to two-thirds the impact that the SAP12 energy efficiency rating has).

Tijn Croon, from TU Delft said: “These findings suggest that inability to downsize may be a significant driver of energy poverty in the United Kingdom. Low-income households can save money and stay warmer living in smaller homes but downsizing is not always easy for older households whose dependants have left home and who find themselves with a large, older home that is very expensive to keep warm.”

One-person households spend less on heating

A surprising finding in the study is that across all income groups, one-person households tend to spend less on energy. And for households in energy poverty the reduction (£36.77 per year) was twice as large as for low-income households not in energy poverty (£15.65 per year).

Tijn Croon, from TU Delft, said: “This might suggest that many one-person households are able to control their energy consumption more strategically than a multi-person household can.”

Dr Galvin said: “Our study controlled for other factors so this is not just a case of low-income households living in smaller homes. Further research could survey one-person households to find out if they have skills and practices that could be transferred to multi-person households.”

Mitigating impact of Winter Fuel Payment cuts

The authors suggest several potential solutions. Expanding Pension Credit eligibility to align with the government's low-income threshold would be the most comprehensive fix, though this may be financially unfeasible. Alternative measures could include a temporary application process for the Winter Fuel Payment for those just above the Pension Credit threshold or providing tax credits or rebates for low-income pensioners, which could be more easily managed since HMRC already holds income data.

While much attention has been given to the risk of energy poverty among pensioners, the authors also note that families with children and young adults are often equally vulnerable and may face even greater challenges in the housing market compared to pensioners.

The authors are currently working on a follow-up research paper that will explore the recent reforms to the government’s Warm Home Discount scheme.

Reference

R. Galvin, M. Sunikka-Blank, T. Croon, ‘Juggling the Basics: How Much Does an Income Increase Affect Energy Spending of Low-Income Households in England?’, Energy Research & Social Science (2024). DOI: 10.1016/j.erss.2024.103766

The UK Government’s policy to scrap Winter Fuel Payments could disproportionately affect low-income pensioners in England, new analysis suggests. But the same study argues that the energy inefficiency of homes and challenges involved in downsizing will have an even more harmful effect this winter.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

Alcohol consumption is the fifth largest contributor to premature death and disease worldwide. In 2016 it was estimated to have caused approximately 3 million deaths worldwide.

Professor Dame Theresa Marteau and colleagues at the Behaviour and Health Research Unit have shown previously that serving wine in smaller glasses is associated with a decrease in sales.

To see if this effect was seen with other alcoholic drinks, they approached venues in England and asked them to remove the pint serving size and instead offer two-thirds as the largest option for four weeks, with four-week non-intervention periods before and after as a comparison.

In a study published in PLOS Medicine, the team found that removing the pint reduced the daily mean volume of beer, lager and cider sold by 9.7%, although there was a slight increase in the amount of wine purchased, with one pub contributing to half of the increase of wine sales. They report that although customers did not complain, fewer than 1% of venues approached agreed to participate and the intervention involved only 12 establishments.

Professor Marteau said: “Alcohol harms our health, increasing the risk of injury and many diseases including heart disease, bowel, breast and liver cancers. While we may all enjoy a drink, the less we drink the better our health.

“As we’ve shown is the case with wine, removing the largest serving size for beer, lager and cider – in this case, the pint – could encourage people to drink less. This could be beneficial both to the nation’s health and the health of individuals.”

Further assessment is needed, particularly into whether people fully compensated for reduced beer consumption by drinking other alcoholic drinks, but the intervention merits consideration for inclusion in alcohol control policies. Smaller serving sizes could contribute towards reducing alcohol consumption across populations and thereby decrease the risk of seven cancers and other diseases.

Reference
Mantzari, E et al. Impact on beer sales of removing the pint serving size: An A-B-A reversal trial in pubs, bars, and restaurants in England. PLOS Medicine; 17 Sept 2024; DOI: 10.1371/journal.pmed.1004442

Adapted from a press release by PLOS Medicine

Cambridge researchers have shown that reducing the serving size for beer, lager and cider reduces the volume of those drinks consumed in pubs, bars and restaurants, which could have wider public health benefits.

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A team lead by researchers at the University of Cambridge has developed a monoclonal antibody drug, using a technique involving genetically engineered mice, that may help prevent infection from Acinetobacter baumannii, a bacteria associated with hospital-acquired infections, which is particularly common in Asia.

A. baumannii bacteria can cause life-threatening respiratory illness and sepsis in vulnerable individuals, particularly in newborn babies whose immune systems have not fully developed. It is usually spread through contaminated surfaces, medical equipment and via contact with others. In recent years infections with strains of this bacteria that are resistant to almost every antibiotic available have become common.

Professor Stephen Baker from the Cambridge Institute of Therapeutic Immunology and Infectious Disease at the University of Cambridge said “A. baumannii is good at sticking to medical equipment, and if people are vulnerable or don't have a particularly well-developed immune system, they can succumb to this infection and get aggressive pneumonia requiring ventilation – and in many cases, the patients can acquire the infection from the ventilation itself.

“The bacteria are naturally resistant to many antimicrobials, but as they’re now found in hospitals, they’ve acquired resistance to almost everything we can use. In some hospitals in Asia, where the infections are most common, there isn't a single antibiotic that will work against them. They’ve become impossible to treat.”

In a study published today in Nature Communications, the team produced monoclonal antibodies using transgenic mice – mice that have been genetically-engineered to have a human-like immune system, producing human antibodies instead of mouse antibodies. They went on to show that these monoclonal antibodies were able prevent infection with A. baumannii derived from clinical samples.

Monoclonal antibodies are a growing area of medicine, commonly used to treat conditions including cancer (for example, Herceptin for treating some breast cancers) and autoimmune disease (for example, Humira for treating rheumatoid arthritis, psoriasis, Crohn's disease, and ulcerative colitis).

Usually, monoclonal antibodies are developed from the antibodies of patients who have recovered from an infection, or they are designed to recognise and target a particular antigen. For example, monoclonal antibodies targeting the ‘spike protein’ of the SARS-CoV-2 coronavirus were explored as a way of treating COVID-19.

In the approach taken by the Cambridge team, however, transgenic mice were exposed to the outer membrane of A. baumannii bacteria, triggering an immune response. The researchers then isolated almost 300 different antibodies and tested which of these was the most effective at recognising live bacteria, identifying the single monoclonal antibody mAb1416 as the best.

Professor Baker said: “Using this method, we don't infect the mice with the live bacteria, but we instead immunise them using multiple different elements and let the mouse’s immune system work out which ones to develop antibodies against. Because these mice have ‘humanised’ immune systems, we wouldn’t then need to reengineer the antibodies to work in humans.”

The team treated mice with mAb1416, and 24 hours later exposed them to A. baumannii isolated from a child with sepsis in an intensive care unit. They found that those mice treated with the drug saw a significant reduction in bacterial load in their lungs a further 24 hours later, compared to mice that were not treated.

All of the isolates used to produce and test the monoclonal antibodies were from patients in Ho Chi Minh City, Vietnam, but the isolate used to test mAb1416 was taken from a patient ten years later than the other isolates. This is important because it shows that mAb1416 was protective against A. baumannii bacteria that may have evolved over time.

Professor Baker said: “Using this technique, you can take any bacterial antigen or cocktail of antigens, rather than waiting for somebody that's recovered from a particular infection – who you assume has developed an appropriate antibody response – give it to the mice and extract the antibodies you think are the most important.”

More work is now needed to understand the mechanism by which mAb1416 protects against infection, as this could allow the team to develop an even more effective treatment. Any potential new drug will then need to be tested in safety trials in animals before being trialled in patients.

Professor Baker added: “We know that monoclonal antibodies are safe and that they work, and the technology exists to produce them – what we have done is identify how to hit bacteria with them. Apart from the cost effectiveness, there's no reason why this couldn’t become a medicine within a few years. Given the emergency presented by antimicrobial resistance, this could become a powerful new weapon to fight back.”

The research was funded by the Bill & Melinda Gates Foundation, the UK Medical Research Council Newton Fund, the Viet Nam Ministry of Science and Technology, and Wellcome.

Professor Baker is a fellow at Wolfson College, Cambridge.

Reference
Baker, S, Krishna, A & Higham, S. Exploiting human immune repertoire transgenic mice to identify protective monoclonal antibodies against an extensively antimicrobial resistant nosocomial bacterial pathogen. Nat Comms; 12 Sept 2024; DOI: 10.1038/s41467-024-52357-8

Monoclonal antibodies – treatments developed by cloning a cell that makes an antibody – could help provide an answer to the growing problem of antimicrobial resistance, say scientists.

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The international team, co-led by the University of Cambridge, used Webb to observe a galaxy roughly the size of the Milky Way in the early universe, about two billion years after the Big Bang. Like most large galaxies, it has a supermassive black hole at its centre. However, this galaxy is essentially ‘dead’: it has mostly stopped forming new stars.

“Based on earlier observations, we knew this galaxy was in a quenched state: it’s not forming many stars given its size, and we expect there is a link between the black hole and the end of star formation,” said co-lead author Dr Francesco D’Eugenio from Cambridge’s Kavli Institute for Cosmology. “However, until Webb, we haven’t been able to study this galaxy in enough detail to confirm that link, and we haven’t known whether this quenched state is temporary or permanent.”

This galaxy, officially named GS-10578 but nicknamed ‘Pablo’s Galaxy’ after the colleague who decided to observe it in detail, is massive for such an early period in the universe: its total mass is about 200 billion times the mass of our Sun, and most of its stars formed between 12.5 and 11.5 billion years ago.

“In the early universe, most galaxies are forming lots of stars, so it’s interesting to see such a massive dead galaxy at this period in time,” said co-author Professor Roberto Maiolino, also from the Kavli Institute for Cosmology. “If it had enough time to get to this massive size, whatever process that stopped star formation likely happened relatively quickly.”

Using Webb, the researchers detected that this galaxy is expelling large amounts of gas at speeds of about 1,000 kilometres per second, which is fast enough to escape the galaxy’s gravitational pull. These fast-moving winds are being ‘pushed’ out of the galaxy by the black hole.

Like other galaxies with accreting black holes, ‘Pablo’s Galaxy’ has fast outflowing winds of hot gas, but these gas clouds are tenuous and have little mass. Webb detected the presence of a new wind component, which could not be seen with earlier telescopes. This gas is colder, which means it’s denser and – crucially – does not emit any light. Webb, with its superior sensitivity, can see these dark gas clouds because they block some of the light from the galaxy behind them.

The mass of gas being ejected from the galaxy is greater than what the galaxy would require to keep forming new stars. In essence, the black hole is starving the galaxy to death. The results are reported in the journal Nature Astronomy.

“We found the culprit,” said D’Eugenio. “The black hole is killing this galaxy and keeping it dormant, by cutting off the source of ‘food’ the galaxy needs to form new stars.”

Although earlier theoretical models had predicted that black holes had this effect on galaxies, before Webb, it had not been possible to detect this effect directly.

Earlier models had predicted that the end of star formation has a violent, turbulent effect on galaxies, destroying their shape in the process. But the stars in this disc-shaped galaxy are still moving in an orderly way, suggesting that this is not always the case.

“We knew that black holes have a massive impact on galaxies, and perhaps it’s common that they stop star formation, but until Webb, we weren’t able to directly confirm this,” said Maiolino. “It’s yet another way that Webb is such a giant leap forward in terms of our ability to study the early universe and how it evolved.”

New observations with the Atacama Large Millimeter-Submillimiter Array (ALMA), targeting the coldest, darkest gas components of the galaxy, will tell us more about if and where any fuel for star formation is still hidden in this galaxy, and what is the effect of the supermassive black hole in the region surrounding the galaxy.

The research was supported in part by the Royal Society, the European Union, the European Research Council, and the Science and Technology Facilities Council (STFC), part of UK Research and Innovation (UKRI).

Reference:
Francesco D’Eugenio, Pablo G. Pérez-González et al. ‘A fast-rotator post-starburst galaxy quenched by supermassive black-hole feedback at z=3.’ Nature Astronomy (2024). DOI: 10.1038/s41550-024-02345-1

Astronomers have used the NASA/ESA James Webb Space Telescope to confirm that supermassive black holes can starve their host galaxies of the fuel they need to form new stars.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

The study, by researchers at the University of Cambridge’s Sainsbury Laboratory, also found that bees prefer larger bullseyes over small ones, and fly 25% faster between artificial flower discs with larger bullseyes – potentially boosting efficiency for both bees and blossoms.

Using the hibiscus plant as a model, the researchers selected plants with three differently sized bullseye patterns – H. richardsonii (small bullseye covering 4% of flower disc), H. trionum (medium bullseye covering 16%) and a transgenic line (mutation) of H. trionum (large bullseye covering 36%).

They found that petal pre-patterning is established very early in the flower’s formation long before the petal shows any visible colour. The petal acts like a 'paint-by-numbers' canvas, where different regions are predetermined to develop specific colours and textures long before they start looking different from one another.

The research also shows plants can precisely control and modify the shape and size of these patterns using multiple mechanisms, highlighting the evolutionary importance of the process. By fine-tuning these designs, plants may gain a competitive advantage in the contest to attract pollinators.

The findings are published today in the journal Science Advances.

Dr Edwige Moyroud, who leads a research team studying the mechanisms underlying pattern formation in petals, explained: “If a trait can be produced by different methods, it gives evolution more options to modify it and create diversity, similar to an artist with a large palette or a builder with an extensive set of tools. By studying how bullseye patterns change, what we are really trying to understand is how nature generates biodiversity.”

In the small hibiscus species Hibiscus trionum, a striking bullseye pattern is formed on the petals, featuring a dark purple centre surrounded by white.

Lead author Dr Lucie Riglet investigated the mechanism behind hibiscus petal patterning by analysing petal development in three hibiscus flowers that had the same total size but different bullseye sizes – small, medium and large.

She found that the pre-pattern begins as a small, crescent-shaped region long before the bullseye is visible on tiny petals less than 0.2mm in size.

Dr Riglet said: “At the earliest stage we could dissect, the petals have around 700 cells and are still greenish in colour, with no visible purple pigment and no difference in cell shape or size. When the petal further develops to 4000 cells, it still does not have any visible pigment, but we identified a specific region where the cells were larger than their surrounding neighbours. This was the pre-pattern.”

A computational model developed by Dr Argyris Zardilis provided further insights, and combining both computational models and experimental results, the researchers showed that hibiscus can vary bullseye dimensions very early during the pre-patterning phase or modulate growth in either region of the bullseye, by adjusting cell expansion or division, later in development.

Dr Riglet then compared the relative success of the bullseye patterns in attracting pollinators using artificial flower discs that mimicked the three different bullseye dimensions.

Dr Riglet explained: “The bees not only preferred the medium and larger bullseyes over the small bullseye, they were also 25% quicker visiting these larger flower discs. Foraging requires a lot of energy and so if a bee can visit four flowers rather than three flowers in the same time, then this is beneficial for the bee, and also the flower.”

The findings suggest that these pre-patterning strategies could have deep evolutionary roots, potentially influencing the diversity of flower patterns across different species. The next step for the research team is to identify the signals responsible for generating these early patterns and to explore whether similar pre-patterning mechanisms are used in other plant organs, such as leaves.

This research not only advances our understanding of plant biology but also highlights the intricate connections between plants and their environments, showing how precise natural designs can play a pivotal role in the survival and evolution of species.

For example, H. richardsonii, which has the smallest bullseye of the three hibiscus plants studied in this research, is a critically endangered plant native to New Zealand. H. trionum is also found in New Zealand, but not considered to be native, and is widely distributed across Australia and Europe and has become a weedy naturalised plant in North America. Additional research is needed to determine whether the larger bullseye size helps H. trionum attract more pollinators and enhance its reproductive success.

Patterns on the flowers of plants guide insects, like bees, to the centre of the flower, where nectar and pollen await, enhancing the plant's chances of successful pollination. Despite their importance, surprisingly little is known about how these petal patterns form and how they have evolved into the vast diversity we see today, including spots, stripes, veins, and bullseyes.

These findings pave the way for further research into how petal patterns influence the survival and evolution of flowering plant species.

Reference

Riglet, L. et al: 'Hibiscus bullseyes reveal mechanisms controlling petal pattern proportions that influence plant-pollinator interactions'. September 2024, Science Advances. DOI: 10.1126/sciadv.adp5574

Flowers like hibiscus follow an invisible blueprint established very early in petal formation that precisely dictates the size of their central bullseye – a crucial pattern that can significantly impact their ability to attract pollinating bees.

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

The study, by researchers at the University of Cambridge’s Sainsbury Laboratory also found that bees prefer larger bullseyes over smaller ones and fly 25% faster between artificial flower discs with larger bullseyes – potentially boosting efficiency for both bees and blossoms. 

Patterns on the flowers of plants guide insects, like bees, to the centre of the flower, where nectar and pollen await, enhancing the plant's chances of successful pollination. Despite their importance, surprisingly little is known about how these petal patterns form and how they have evolved into the vast diversity we see today, including spots, stripes, veins, and bullseyes. 

Using a small hibiscus plant as a model, researchers compared closely related plants with the same flower size but three differently sized bullseye patterns featuring a dark purple centre surrounded by white – H. richardsonii (small bullseye covering 4% of the flower disc), H. trionum (medium bullseye covering 16%) and a transgenic line (mutation) of H. trionum (large bullseye covering 36%). 

They found that a pre-pattern is set up on the petal surface very early in the flower’s formation long before the petal shows any visible colour. The petal acts like a 'paint-by-numbers' canvas, where different regions are predetermined to develop specific colours and textures long before they start looking different from one another. 

The research also shows plants can precisely control and modify the shape and size of these patterns using multiple mechanisms, with possible implications for plant evolution. By fine-tuning these designs, plants may gain a competitive advantage in the contest to attract pollinators or maybe start attracting different species of insects. 

These findings are published in Science Advances. 

Dr Edwige Moyroud, who leads a research team studying the mechanisms underlying pattern formation in petals, explained: “If a trait can be produced by different methods, it gives evolution more options to modify it and create diversity, similar to an artist with a large palette or a builder with an extensive set of tools. By studying how bullseye patterns change, what we are really trying to understand is how nature generates biodiversity.” 

Lead author Dr Lucie Riglet investigated the mechanism behind hibiscus petal patterning by analysing petal development in the three hibiscus flowers that had the same total size but different bullseye patterns. 

3_hibiscus_bullseyes-2-01-01_sml.jpg

She found that the pre-pattern begins as a small, crescent-shaped region long before the bullseye is visible on tiny petals less than 0.2mm in size. 

Dr Riglet said: “At the earliest stage we could dissect, the petals have around 700 cells and are still greenish in colour, with no visible purple pigment and no difference in cell shape or size. When the petal further develops to 4000 cells, it still does not have any visible pigment, but we identified a specific region where the cells were larger than their surrounding neighbours. This is the pre-pattern.” 

These cells are important because they mark the position of the bullseye boundary, the line on the petal where the colour changes from purple to white – without a boundary there is no bullseye! 

A computational model developed by Dr Argyris Zardilis provided further insights, and combining both computational models and experimental results, the researchers showed that hibiscus can vary bullseye dimensions very early during the pre-patterning phase or modulate growth in either region of the bullseye, by adjusting cell expansion or division, later in development. 

Dr Riglet then compared the relative success of the bullseye patterns in attracting pollinators using artificial flower discs that mimicked the three different bullseye dimensions. Dr Riglet explained: “The bees not only preferred the medium and larger bullseyes over the small bullseye, they were also 25% quicker visiting these larger flower discs. Foraging requires a lot of energy and so if a bee can visit 4 flowers rather than 3 flowers in the same time, then this is probably beneficial for the bee, and also the plants.” 

The researchers think that these pre-patterning strategies could have deep evolutionary roots, potentially influencing the diversity of flower patterns across different species. The next step for the research team is to identify the signals responsible for generating these early patterns and to explore whether similar pre-patterning mechanisms are used in other plant organs, such as leaves. 

This research not only advances our understanding of plant biology but also highlights the intricate connections between plants and their environments, showing how precise natural designs can play a pivotal role in the survival and evolution of species. 

For example, H. richardsonii, which has the smallest bullseye of the three hibiscus plants studied in this research, is a critically endangered plant native to New Zealand. H. trionum is also found in New Zealand, but not considered to be native, and is widely distributed across Australia and Europe and has become a weedy naturalised plant in North America. Additional research is needed to determine whether the larger bullseye size helps H. trionum attract more pollinators and enhance its reproductive success. 

Reference 
Lucie Riglet, Argyris Zardilis, Alice L M Fairnie, May T Yeo, Henrik Jönsson and Edwige Moyroud (2024) Hibiscus bullseyes reveal mechanisms controlling petal pattern proportions that influence plant-pollinator interactions. Science Advances. DOI: 10.1126/sciadv.adp5574 

Flowers like hibiscus use an invisible blueprint established very early in petal formation that dictates the size of their bullseyes – a crucial pre-pattern that can significantly impact their ability to attract pollinating bees.  

The text in this work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License. Images, including our videos, are Copyright ©University of Cambridge and licensors/contributors as identified. All rights reserved. We make our image and video content available in a number of ways – on our main website under its Terms and conditions, and on a range of channels including social media that permit your use and sharing of our content under their respective Terms.

The technology from Cancer Grand Challenges team IMAXT uses advanced spatial biology techniques to analyse tumours, some of which are based on technology originally developed to map the Milky Way and discover new planets. Now, other scientists will be able to access these technologies to create detailed tumour maps that could one day transform how we diagnose and treat cancer.

Led by Professor Greg Hannon and Dr Dario Bressan at the Cancer Research UK Cambridge Institute and Dr Nicholas Walton at the University of Cambridge’s Institute of Astronomy, SPACE will give other researchers the opportunity to study cancer in a way that wasn’t previously possible.

Dr Dario Bressan, Head of the SPACE Laboratory at the Cancer Research UK Cambridge Institute, said: “Tumours aren’t just a uniform mass of cells; they consist of a diverse ecosystem of cancer cells, immune cells, and other essential components that support their survival. Hidden within these intricate networks lies valuable information which could guide us in making more personalised treatment decisions for each patient. 

“With the SPACE platform, researchers can zoom into specific cell populations, highlight the complex connections between them, and even run virtual experiments to predict how the tumour might respond to different treatments. By unlocking these insights, we can transform the future of cancer care and uncover new opportunities for targeted therapies.” 

The IMAXT team was first awarded £20 million in 2017 by Cancer Research UK through Cancer Grand Challenges, a global research initiative co-founded by Cancer Research UK and the National Cancer Institute in the US.

Since then, the team has united experts from fields rarely brought together including medicine, Virtual Reality (VR), programming, molecular biology, chemistry, mathematics, and even astronomy, to create a completely immersive tool for studying tumours.

As well as enabling scientists to analyse 3D tumour maps, IMAXT created pioneering VR technology which allows the user to ‘step inside’ a tumour using a VR headset.

With the headset, scientists get to view vast amounts of detailed data about individual tumour cells in a 3D space. Instead of looking at this data on a computer screen, they can see all the information in real-time, as if they were inside the tumour itself.

Professor Greg Hannon, Director of the Cancer Research UK Cambridge Institute, said: "Cancer Grand Challenges offers a unique opportunity for international teams to address some of cancer’s biggest challenges. When we took on our particular challenge, much of what we proposed was science fiction.

“Over the past 7 years, our team has turned those early hopes and ideas into approaches that can now be made broadly available. In nature, biology unfolds in three dimensions, and we now finally have the tools to observe it that way—giving us a much deeper, more accurate view of cancer. We’re thrilled to share these breakthroughs with the broader cancer research community."

ioa-space-image_full.jpg

Director of Cancer Grand Challenges at Cancer Research UK, Dr David Scott, said: “IMAXT is changing what’s possible when it comes to cancer research.  

“We can glean important insights about a tumour by analysing its genetic makeup or its proteins, but no technology alone can give us the depth of understanding needed to truly understand this complex disease.  

“By combining state-of-the-art technology and vast expertise, IMAXT will change how cancers are classified, treated and managed, giving more people a better chance of surviving their disease.” 

The funding will support the SPACE hub laboratory, hosted at the CRUK Cambridge Institute, and the SPACE analysis and computing platform, developed and operated at the Institute of Astronomy, University of Cambridge. Together SPACE includes and combines most available technologies for the spatial molecular profiling of tumours. The continued collaboration between the cancer and astronomy teams from the IMAXT project will ensure the maintenance and development of all critical aspects of the platform – from technical and scientific expertise to instrumentation, computing, and data analysis – to allow SPACE to continue at the forefront research in the rapidly emerging spatial-omics field, and be a valuable centre of excellence to support new research in the Cancer Grand Challenge and cancer research communities.

SPACE is funded by Cancer Research UK through Cancer Grand Challenges. Additional support for the SPACE project has been provided by the UK Space Agency through their funding of the development of imaging and analysis techniques at the IoA, Cambridge for a range of space science missions. These have been successfully applied to spatial imaging data through IMAXT and are ready for wider use in SPACE.

Dr Paul Bate, Chief Executive Officer at UK Space Agency said: “Space is powering our daily lives, from satellite navigation to weather forecasts and climate monitoring. This collaboration between the cancer and astronomy teams in the IMAXT project is another real-world example of how space science and technology is bringing benefits to people here on Earth. 

“Thanks to this partnership, the same science and technology that mapped the Milky Way may soon have a positive impact on people battling cancer, and could support doctors to provide better, faster treatment." 

Going forward, a next-generation version of the VR technology will be further developed and commercialised by Suil Vision, a start-up company recently launched by IMAXT team members and Cancer Research UK’s innovation arm, Cancer Research Horizons. Suil Vision is the first start-up to emerge from the Cancer Grand Challenges programme. With a £500,000 investment from the Cancer Research Horizons Seed Fund, Suil Vision will create a market-ready version of their suite of VR technologies for analysing multiple types of biological data, rolling these out across research institutions and companies worldwide. 

Find out how Cambridge is changing the story of cancer

Image

Top: Lung with two metastatic lesions derived from a mouse primary triple-negative breast tumour. The figure shows how the registration of the different imaging modalities to a cellular level allow to segment individual cells and identify tumour cell populations, differentiate hypoxic areas, increased fibrosis, infiltration of immune cells and blood and lymphatic vessels by staining with a panel of 35 cell markers at the same time. Bottom: Sample in 3D depicts a tumour grown in the mammary gland of a mouse showing the power of the SPACE pipeline to produce and visualise large volumes (typically ~100,000 individual images registered and stitched and up to 500TB 500 GB of data). The orange fluorescence beads are clearly visible in the medium outside the biological tissue and prove to be crucial for all stages of multimodal registration.

Adapted from a press release by Cancer Research UK

A unique collaboration of astronomers and cancer researchers at Cambridge has been awarded more than £5m to establish the Spatial Profiling and Annotation Centre of Excellence (SPACE) to open up access to their groundbreaking cancer mapping technology and establish collaborations with other scientists to enable them to investigate tumours in 3D.

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Matthew Pennycook MP, who was accompanied by Peter Freeman, Chair of Homes England, joined the University’s Vice-Chancellor, Professor Deborah Prentice, the Pro-Vice-Chancellor for Innovation, Dr Diarmuid O’Brien, and members of the University Estates Division for a tour of the city’s new community.

During the fact-finding visit, Mr Pennycook heard about the innovative design and planning that has gone into Eddington, which is delivering homes, community facilities, and green space, and at the same time creating a vibrant and sustainable place to live.

Central to its planning has been the provision of affordable housing for key worker staff at the University, which will account for 50% of Eddington’s homes. By housing University staff in a purpose-built, high-quality neighbourhood, while also adding more homes to the open market, Eddington aims to relieve housing pressure on the city and support the highly successful Cambridge eco-system which provides long-term growth and jobs for the wider area and beyond.

The Minister also heard how Eddington and the nearby Cambridge West Innovation District are critical parts of the University’s plans for sustained economic growth in Cambridge. The University is driving forward the Cambridge West Innovation District and the Eddington housing development together, as part of a coherent vision for the future of the city.

Professor Deborah Prentice, Vice-Chancellor, said: “It was a pleasure to welcome the Housing and Planning Minister, and the Chair of Homes England, and to show them around our exciting new development. They were interested to hear how the neighbourhood has been designed with sustainability at its heart, and how it helps support Cambridge as a world-leading hub of innovation, benefiting the community and providing growth for the national economy.”

Mr Pennycook later visited Cambridge Biomedical Campus where he was joined by Lord Vallance, Minister for Science, in hosting a roundtable on infrastructure and growth in Cambridge.

Proposals for the future phases of the Eddington development will be discussed at the first round of public consultations this month. For dates and venue details visit the Eddington website.

The new Minister for Housing and Planning visited the University’s Eddington development to learn more about the new neighbourhood as an example of a high-quality, sustainable housing project that supports local economic growth.

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The smart choker, developed by researchers at the University of Cambridge, incorporates electronic sensors in a soft, stretchable fabric, and is comfortable to wear. The device could be useful for people who have temporary or permanent speech impairments, whether due to laryngeal surgery, or conditions such as Parkinson’s, stroke or cerebral palsy.

By incorporating machine learning techniques, the smart choker can also successfully recognise differences in pronunciation, accent and vocabulary between users, reducing the amount of training required.

The choker is a type of technology known as a silent speech interface, which analyses non-vocal signals to decode speech in silent conditions – the user only needs to mouth the words in order for them to be captured. The captured speech signals can then be transferred to a computer or speaker to facilitate conversation.

Tests of the smart choker showed it could recognise words with over 95% accuracy, while using 90% less computational energy than existing state-of-the art technologies. The results are reported in the journal npj Flexible Electronics.

“Current solutions for people with speech impairments often fail to capture words and require a lot of training,” said Dr Luigi Occhipinti from the Cambridge Graphene Centre, who led the research. “They are also rigid, bulky and sometimes require invasive surgery to the throat.”

The smart choker developed by Occhipinti and his colleagues outperforms current technologies on accuracy, requires less computing power, is comfortable for users to wear, and can be removed whenever it’s not needed. The choker is made from a sustainable bamboo-based textile, with strain sensors based on graphene ink incorporated in the fabric. When the sensors detect any strain, tiny, controllable cracks form in the graphene. The sensitivity of the sensors is more than four times higher than existing state of the art.

“These sensors can detect tiny vibrations, such as those formed in the throat when whispering or even silently mouthing words, which makes them ideal for speech detection,” said Occhipinti. “By combining the ultra-high sensitivity of the sensors with highly efficient machine learning, we’ve come up with a device we think could help a lot of people who struggle with their speech.”

Vocal signals are incredibly complex, so associating a specific signal with a specific word requires a high level of computational processing. “On top of that, every person is different in terms of the way they speak, and machine learning gives us the tools we need to learn and adapt the interpretation of signals from person to person,” said Occhipinti.

The researchers trained their machine learning model on a database of the most frequently used words in English, and selected words which are frequently confused with each other, such as ‘book’ and ‘look’. The model was trained with a variety of users, including different genders, native and non-native English speakers, as well as people with different accents and different speaking speeds.

Thanks to the device’s ability to capture rich dynamic signal characteristics, the researchers found it possible to use lightweight neural network architectures with simplified depth and signal dimensions to extract and enhance the speech information features. This resulted in a machine learning model with high computational and energy efficiency, ideal for integration in battery-operated wearable devices with real-time AI processing capabilities.

“We chose to train the model with lots of different English speakers, so we could show it was capable of learning,” said Occhipinti. “Machine learning has the capability to learn quickly and efficiently from one user to the next, so the retraining process is quick.”

Tests of the smart choker showed it was 95.25% accurate in decoding speech. “I was surprised at just how sensitive the device is,” said Occhipinti. “We couldn’t capture all the signals and complexity of human speech before, but now that we can, it unlocks a whole new set of potential applications.”

Although the choker will have to undergo extensive testing and clinical trials before it is approved for use in patients with speech impairments, the researchers say that their smart choker could also be used in other health monitoring applications, or for improving communication in noisy or secure environments.

The research was supported in part by the EU Graphene Flagship and the Engineering and Physical Sciences Research Council (EPSRC), part of UK Research and Innovation (UKRI).

Reference:
Chenyu Tang et al. ‘Ultrasensitive textile strain sensors redefine wearable silent speech interfaces with high machine learning efficiency.’ npj Flexible Electronics (2024). DOI: 10.1038/s41528-024-00315-1

Researchers have developed a wearable ‘smart choker’ that uses a combination of flexible electronics and artificial intelligence techniques to allow people with speech impairments to communicate by detecting tiny movements in the throat.

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They have just won an award to develop their technology, which aims to make hip surgery more precise and deliver better and longer-lasting outcomes – which is good for patients and the NHS.

The National Institute for Health and Care Research (NIHR) has awarded a £1.4 million Invention for Innovation (i4i) Product Development Award to advance work on the team’s “smart” joint “trial liner”.

The sensors measure forces passing through the hip joint to help the surgeon assess and balance the soft tissues, which aids the accurate positioning of the implant.

Once measurements are complete using the wireless surgical aid, the surgeon marks the ideal position for the implant, removes the smart trial liner, and completes the operation.

There are currently no technologies that can deliver such readings during an operation and in real-time, and instead surgeons balance the joint based on feel and anatomical landmarks.

This is despite over two million total hip replacements being performed annually, with the number constantly rising due to increasing lifespans. Younger patients are starting to need hip replacements as well, so implants need to withstand higher stresses and last longer, to avoid spiralling into a vicious circle of revision surgery and higher rates of dissatisfaction.

Driving this clinical initiative is the chief investigator from Cambridge University Hospitals (CUH) NHS Foundation Trust, Consultant orthopaedic surgeon, clinical and research lead of the Young Adult Hip Service, and Affiliate Associate Professor at the University of Cambridge Vikas Khanduja.

The technology development is being overseen by Professor Sohini Kar-Narayan from Cambridge’s Department of Materials Science and Metallurgy, together with Dr Jehangir Cama, who is leading on translational and commercialisation activities. They are joined by Consultant clinical scientist and CUH head of clinical engineering, Professor Paul White.

“We’re really looking forward to this next phase of product development that will see us move towards an actual product that is fit for clinical use, and that has the potential to revolutionise joint replacement surgery,” said Kar-Narayan.

“This funding will bring together wide-ranging expertise to help us further develop our prototype, bringing this technology closer to clinical use,” said Cama.

The team currently has a prototype version of the device, which has been validated in the laboratory and in other tests. However, the NIHR award is important for further development and finalisation of the design and compliance with regulations before it can be tested in a living patient.

The team’s underlying sensor technology intellectual property has been protected via a patent application filed by Cambridge Enterprise, the University’s commercialisation arm.

“This is a fantastic example of Cambridge’s entrepreneurial clinicians, academics and their institutions working together with forward-looking funders to create a positive impact for markets, society and importantly patients,” said Dr Terry Parlett, Commercialisation Director at Cambridge Enterprise.

Adapted from a CUH press release.

Technology that could transform the future of hip replacement surgery is being pioneered by a team of experts in Cambridge.

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An international group of researchers, led by the Copenhagen Business School, the University of Basel and the University of Cambridge, surveyed 4,000 people from Denmark, India, Nigeria and the United States about inequality in personal carbon footprints – the total amount of greenhouse gases produced by a person’s activities – within their own country.

Although it is well-known that there is a large gap between the carbon footprint of the richest and poorest in society, it’s been unclear whether individuals were aware of this inequality. The four countries chosen for the survey are all different in terms of wealth, lifestyle and culture. Survey participants also differed in their personal income, with half of participants belonging to the top 10% of income in their country.

The vast majority of participants across the four countries overestimated the average personal carbon footprint of the poorest 50% and underestimated those of the richest 10% and 1%.

However, participants from the top 10% were more likely to support certain climate policies, such as increasing the price of electricity during peak periods, taxing red meat consumption or subsidising carbon dioxide removal technologies such as carbon capture and storage.

The researchers say that this may reflect generally higher education levels among high earners, a greater ability to absorb price-based policies or a stronger preference for technological solutions to the climate crisis. The results are reported in the journal Nature Climate Change.

Although the concept of a personal carbon or environmental footprint has been used for over 40 years, it became widely popularised in the mid-2000s, when the fossil fuel company BP ran a large advertising campaign encouraging people to determine and reduce their personal carbon footprint.

“There are definitely groups out there who would like to push the responsibility of reducing carbon emissions away from corporations and onto individuals, which is problematic,” said co-author Dr Ramit Debnath, Assistant Professor and Cambridge Zero Fellow at the University of Cambridge. “However, personal carbon footprints can illustrate the profound inequality within and between countries and help people identify how to live in a more climate-friendly way.”

Previous research has shown widespread misperceptions about how certain consumer behaviours affect an individual's carbon footprint. For example, recycling, shutting off the lights when leaving a room and avoiding plastic packaging are lower-impact behaviours that are overestimated in terms of how much they can reduce one’s carbon footprint. On the other end, the impact of behaviours such as red meat consumption, heating and cooling homes, and air travel all tend to be underestimated.

However, there is limited research on whether these misperceptions extend to people’s perceptions of the composition and scale of personal carbon footprints and their ability to make comparisons between different groups.

The four countries selected for the survey (Denmark, India, Nigeria and the US) were chosen due to their different per-capita carbon emissions and their levels of economic inequality. Within each country, approximately 1,000 participants were surveyed, with half of each participant group from the top 10% of their country and the other half from the bottom 90%.

Participants were asked to estimate the average personal carbon footprints specific to three income groups (the bottom 50%, the top 10%, and the top 1% of income) within their country. Most participants overestimated the average personal carbon footprint for the bottom 50% of income and underestimated the average footprints for the top 10% and top 1% of income.

“These countries are very different, but we found the rich are pretty similar no matter where you go, and their concerns are different to the rest of society,” said Debnath. “There’s a huge contrast between billionaires travelling by private jet while the rest of us drink with soggy paper straws: one of those activities has a big impact on an individual carbon footprint, and one doesn’t.”

The researchers also looked at whether people’s ideas of carbon footprint inequality were related to their support for different climate policies. They found that Danish and Nigerian participants who underestimated carbon footprint inequality were generally less supportive of climate policies. They also found that Indian participants from the top 10% were generally more supportive of climate policies, potentially reflecting their higher education and greater resources.

“Poorer people have more immediate concerns, such as how they’re going to pay their rent, or support their families,” said first author Dr Kristian Steensen Nielsen from Copenhagen Business School. “But across all income groups, people want real solutions to the climate crisis, whether those are regulatory or technological. However, the people with the highest carbon footprints bear the greatest responsibility for changing their lifestyles and reducing their footprints.”

After learning about the actual carbon footprint inequality, most participants found it slightly unfair, with those in Denmark and the United States finding it the most unfair. However, people from the top 10% generally found the inequality fairer than the general population, except in India. “This could be because they’re trying to justify their larger carbon footprints,” said Debnath.

The researchers say that more work is needed to determine the best ways to promote fairness and justice in climate action across countries, cultures and communities.

“Due to their greater financial and political influence, most climate policies reflect the interests of the richest in society and rarely involve fundamental changes to their lifestyles or social status,” said Debnath.

“Greater awareness and discussion of existing inequality in personal carbon footprints can help build political pressure to address these inequalities and develop climate solutions that work for all,” said Nielsen.

The study also involved researchers from Justus-Liebig-University Giessen, Murdoch University and Oxford University. The research was supported in part by the Carlsberg Foundation, the Bill & Melinda Gates Foundation, the Quadrature Climate Foundation and the Swiss National Science Foundation.

Reference:
Kristian S Nielsen et al. ‘Underestimation of personal carbon footprint inequality in four diverse countries.’ Nature Climate Change (2024). DOI: 10.1038/s41558-024-02130-y 

The personal carbon footprint of the richest people in society is grossly underestimated, both by the rich themselves and by those on middle and lower incomes, no matter which country they come from. At the same time, both the rich and the poor drastically overestimate the carbon footprint of the poorest people.

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Currently cancer is usually diagnosed when tumours are already developed requiring, often significant, treatment to remove them and prevent further growth.

However, a research team at the University of Cambridge will receive over £1.5m from Cancer Research UK over the next six years to investigate how the immune system evolves, targets and kills cancer cells as tumours are developing.

They hope by detecting the trigger point when our own body starts to recognise cancerous cells, it may help find a way to spark our own immune system into action so it kills cancer cells before tumours can even begin.

This could vastly reduce the amount of treatment people diagnosed with cancer require, which can often have significant side effects. The pioneering work could benefit millions of cancer patients before the disease becomes life-threatening or spreads.

Dr Heather Machado is leading a team of scientists at the Department of Pathology, looking at the body's immune system's ability to fight cancer.  Dr Machado’s work on T cells – part of the immune system which fight infection and disease, including cancer – will provide an insight into how long before a diagnosis these cells recognize and respond to cancer.

The study will specifically examine how T cells respond to cancer when they first recognise and respond to a tumour in the kidneys or the liver.

The breakthrough study has the potential to unlock the mystery as to how our immune cells work to fight cancer.

Dr Machado said: “Using mutations that naturally accumulate in each of our cells as we age, we can essentially build a family tree of T-cells, and this family tree has information about when T-cells met cancer for the first time. This research is only now possible as a result of advancements in DNA sequencing technology.

“This research has the potential to give an entirely new perspective on the role of the immune system in cancer progression, findings that we hope to use to further improve lifesaving cancer immunotherapies.”

Her aim is to see if they could lead to specific immunotherapy treatments and ways of detecting the cancer earlier.

She added: “Most cancers are diagnosed years or decades after early tumour development, which can often be too late. Our methods will allow us to go back in the cancer’s timeline to understand the immune response in these early stages of cancer development. Beyond improving immunotherapies, we hope that this understanding helps us detect cancer earlier, at stages where survival rates are much higher.”

The body’s immune system is the first line of defence against cancer but previously it has been difficult to observe this early response in humans.

Dr Machado will use genome sequencing which determines the genetic makeup of an organism to study how a tumour and the immune cells co-evolve over the course of tumour development. 

She will time T cell clonal expansions using evolutionary trees built from the genomes of individual T cells, exploiting recent advancements in single-cell whole genome sequencing. Dr Machado will then perform these experiments using early-stage kidney and liver cancer resections and by sampling throughout the course of immunotherapy in metastatic kidney cancer.”

She added: “The study is believed to be the first of its kind in the world and it has the potential to be groundbreaking research as we have never been able to examine these evolutionary dynamics in humans before. How long before a tumour is diagnosed has the immune system been responding is an incredibly hard problem to solve because these immune dynamics play out years prior to diagnosis.

“Normal cells evolve into tumours, and we are blind to much of that process and yet the immune system is one of our best tools for fighting cancer.

Dr Machado studied for her PhD at Stanford University and completed her post doctorate research at the Wellcome Sanger Institute in Hinxton, UK. She added: “We are using cutting edge technology that is only available now and we are going to be able to discover how the immune system responds to tumours unlike we have ever seen before and that, is potentially life changing in terms of improving immunotherapies for better health and patient prognosis.”

Find out how Cambridge is changing the story of cancer

Adapted from a press release from Cancer Research UK

A new study aims, for the first time, to pinpoint the very moment the immune system recognises a tumour to try to stop the disease earlier than previously possible.

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The statistics for the University of Cambridge are available on our website as part of our ongoing commitment to transparency and openness around the use of animals in research.

This coincides with the publication of the Home Office’s report on the statistics of scientific procedures on living animals in Great Britain in 2023.

The 10 organisations carried out 1,435,009 procedures, 54% (over half) of the 2,681,686 procedures carried out on animals for scientific research in Great Britain in 2023. Of these 1,435,009 procedures, more than 99% were carried out on mice, fish and rats and 82% were classified as causing pain equivalent to, or less than, an injection.

The 10 organisations are listed below alongside the total number of procedures they carried out in 2023. This is the ninth consecutive year that organisations have come together to publicise their collective statistics and examples of their research.

In total, 69 organisations have voluntarily published their 2023 animal research statistics.

All organisations are committed to the ethical framework called the ‘3Rs’ of replacement, reduction and refinement. This means avoiding or replacing the use of animals where possible, minimising the number of animals used per experiment and optimising the experience of the animals to improve animal welfare. However, as institutions expand and conduct more research, the total number of animals used can rise even if fewer animals are used per study. 

All organisations listed are signatories to the Concordat on Openness on Animal Research in the UK, which commits them to being more open about the use of animals in scientific, medical and veterinary research in the UK. More than 125 organisations have signed the Concordat, including UK universities, medical research charities, research funders, learned societies and commercial research organisations.

Wendy Jarrett, Chief Executive of Understanding Animal Research, which developed the Concordat on Openness, said:

“Animal research remains a small but vital part of the quest for new medicines, vaccines and treatments for humans and animals. Alternative methods are gradually being phased in, but, until we have sufficient reliable alternatives available, it is important that organisations that use animals in research maintain the public’s trust in them. By providing this level of information about the numbers of animals used, and the experience of those animals, as well as details of the medical breakthroughs that derive from this research, these Concordat signatories are helping the public to make up their own minds about how they feel about the use of animals in scientific research in Great Britain.”   

Professor Anna Philpott, Head of the School of Biological Sciences at the University of Cambridge, said:

“Cambridge research is changing how we understand health and ageing, and how we treat disease. Animal research continues to play a small but vital role in this work and in the development of ground-breaking new medical devices and drug treatments. We are committed to using animals only where there is no alternative as a means of making progress.”

Story adapted from a press release by Understanding Animal Research.

CASE STUDY: Egging on vital research

The actin cytoskeleton is a system of long filaments, vital in embryonic development. Problems with its control have been linked to the kidney problems experienced by patients with the rare conditions called Lowe syndrome and Dent disease 2. But since the actin cytoskeleton is in all the cells of the body it has been very difficult to translate an understanding of it into a drug treatment.

Wellcome Trust Senior Research Fellow Dr Jenny Gallop at the University of Cambridge has created a simpler version of the actin cytoskeleton that she can study in the lab. A key component is cytoplasm extracted from frog eggs.

Gallop’s lab keeps around 120 female frogs that are induced to lay eggs in a way that matches their natural cycles. This requires a hormone injection - just a mild discomfort to the frogs - every three to four months to make them ovulate. Over time, Gallop has refined her methods so that only half the original number of frogs are now needed.

This has enabled her to understand what might be going wrong in Lowe syndrome and Dent disease 2 – and realise that an existing drug might be able to help. Alpelisib has already been approved to safely treat breast cancer, and Gallop is now applying for approval to test whether it works to treat the kidney problems in patients with Dent disease 2.

Repurposing an existing drug means the long drug-development process has already been done. Conversations with people affected by the diseases inspire Gallop’s team to keep going. And the frogs have played a vital role in this decade-long journey.

Read the full story

The 10 organisations in Great Britain that carry out the highest number of animal procedures - those used in medical, veterinary and scientific research – have released their annual statistics today.

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Of 3,500 proposals reviewed by the ERC, only 14% were selected for funding – Cambridge has the highest number of grants of any UK institution.

ERC Starting Grants – totalling nearly €780 million – support cutting-edge research in a wide range of fields, from life sciences and physics to social sciences and humanities.

The awards help researchers at the beginning of their careers to launch their own projects, form their teams and pursue their most promising ideas. Starting Grants amount to €1.5 million per grant for a period of five years but additional funds can be made available.

In total, the grants are estimated to create 3,160 jobs for postdoctoral fellows, PhD students and other staff at host institutions.

Cambridge’s recipients work in a wide range of fields including plant sciences, mathematics and medicine. They are among 494 laureates who will be leading projects at universities and research centres in 24 EU Member States and associated countries. This year, the UK has received grants for 50 projects, Germany 98, France 49, and the Netherlands 51.

Cambridge’s grant recipients for 2024 are:

Adrian Baez-Ortega (Dept. of Veterinary Medicine, Wellcome Sanger Institute) for Exploring the mechanisms of long-term tumour evolution and genomic instability in marine transmissible cancers

Claudia Bonfio (MRC Laboratory of Molecular Biology) for Lipid Diversity at the Onset of Life

Tom Gur (Dept. of Computer Science and Technology) for Sublinear Quantum Computation

Leonie Luginbuehl (Dept. of Plant Sciences) for Harnessing mechanisms for plant carbon delivery to symbiotic soil fungi for sustainable food production

Julian Sahasrabudhe (Dept. of Pure Mathematics and Mathematical Statistics) for High Dimensional Probability and Combinatorics

Richard Timms (Cambridge Institute for Therapeutic Immunology and Infectious Disease) for Deciphering the regulatory logic of the ubiquitin system

Hannah Übler (Dept. of Physics) for Active galactic nuclei and Population III stars in early galaxies

Julian Willis (Yusuf Hamied Department of Chemistry) for Studying viral protein-primed DNA replication to develop new gene editing technologies

Federica Gigante (Faculty of History) for Unveiling Networks: Slavery and the European Encounter with Islamic Material Culture (1580– 1700) – Grant hosted by the University of Oxford

Professor Sir John Aston FRS, Pro-Vice-Chancellor for Research at the University of Cambridge, said:

“Many congratulations to the recipients of these awards which reflect the innovation and the vision of these outstanding investigators. We are fortunate to have many exceptional young researchers across a wide range of disciplines here in Cambridge and awards such as these highlight some of the amazing research taking place across the university. I wish this year’s recipients all the very best as they begin their new programmes and can’t wait to see the outcomes of their work.”

Iliana Ivanova, European Commissioner for Innovation, Research, Culture, Education and Youth, said:

“The European Commission is proud to support the curiosity and passion of our early-career talent under our Horizon Europe programme. The new ERC Starting Grants winners aim to deepen our understanding of the world. Their creativity is vital to finding solutions to some of the most pressing societal challenges. In this call, I am happy to see one of the highest shares of female grantees to date, a trend that I hope will continue. Congratulations to all!”

President of the European Research Council, Prof. Maria Leptin, said:

“Empowering researchers early on in their careers is at the heart of the mission of the ERC. I am particularly pleased to welcome UK researchers back to the ERC. They have been sorely missed over the past years. With fifty grants awarded to researchers based in the UK, this influx is good for the research community overall.”

Nine Cambridge researchers are among the latest recipients of highly competitive and prestigious European Research Council (ERC) Starting Grants.

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Car travel contributes to air pollution, a major cause of heart and lung diseases including asthma attacks. Beyond this, it limits children's opportunities for physical activity, hindering their development and mental health, and increasing their risk of obesity and chronic illnesses.

Despite UK guidelines recommending a daily average of 60 minutes of moderate-to-vigorous physical activity for school-aged children and adolescents, less than half (45%) of children aged 5-16 met these levels in 2021. One in three children aged 10-11 in the UK are overweight or obese.

In April 2019, London introduced the ULEZ to help improve air quality by reducing the number of vehicles on the road that do not meet emissions standards. According to Transport for London, the central London ULEZ reduced harmful nitrogen oxides by 35% and particulate matter by 15% in central London within the first 10 months of its introduction.

In a study published on 5 September in the International Journal of Behavioral Nutrition and Physical Activity, a team led by researchers at the University of Cambridge and Queen Mary University of London examined the impact of the ULEZ on how children travelled to school. The research was part of the CHILL study (Children’s Health in London and Luton).

The study examined data from almost 2,000 children aged 6 to 9 years attending 84 primary schools in London and the control area, Luton. 44 schools were located with catchment areas within or bordering London’s ULEZ, and these were compared to a similar number in Luton and Dunstable (acting as a comparison group). The inclusion of the comparison site enabled the researchers to draw more robust conclusions and increased confidence in attributing the observed changes to the introduction of the ULEZ.

The researchers collected data from the period June 2018 to April 2019, prior to ULEZ implementation, and again in the period June 2019 to March 2020, the year after implementation of the ULEZ but prior to COVID-19-related school closures.

Among those children in London who travelled by car prior to the introduction of the ULEZ, 4 in 10 (42%) switched to active modes, while one in 20 (5%) switched from active to inactive modes.

In contrast, only one in 5 (20%) children in Luton swapped from car travel to active modes, while a similar number (21%) switched from active to car travel. This means that children in London within the ULEZ were 3.6 times as likely to shift from travelling by car to active travel modes compared to those children in Luton and far less likely (0.11 times) to switch to inactive modes.

The impact of the ULEZ on switching to active travel modes was strongest for those children living more than half a mile (0.78km) from school. This was probably because many children who live closer to school already walked or cycled to school prior to the ULEZ and therefore there was more potential for change in those living further away from their school.

The study’s first author, Dr Christina Xiao from the Medical Research Council (MRC) Epidemiology Unit at the University of Cambridge, said: “The introduction of the ULEZ was associated with positive changes in how children travelled to school, with a much larger number of children moving from inactive to active modes of transport in London than in Luton.

“Given children's heightened vulnerability to air pollution and the critical role of physical activity for their health and development, financial disincentives for car use could encourage healthier travel habits among this young population, even if they do not necessarily target them.”

Joint senior author Dr Jenna Panter from the MRC Epidemiology Unit, University of Cambridge, said: “The previous Government was committed to increasing the share of children walking to school by 2025 and we hope the new Government will follow suit. Changing the way children travel to school can have significant effects on their levels of physical activity at the same time as bringing other co-benefits like improving congestion and air quality, as about a quarter of car trips during peak morning hours in London are made for school drop-offs.”

After ULEZ was introduced in Central London, the total number of vehicles on the roads fell by 9%, and by one-third (34%) for vehicles that failed to meet the required exhaust emission standards, with no clear evidence of traffic moving instead to nearby areas.

Joint senior author Professor Chris Griffiths from the Wolfson Institute of Population Health, Queen Mary University of London, said: “Establishing healthy habits early is critical to healthy adulthood and the prevention of disabling long term illness, especially obesity and the crippling diseases associated with it. The robust design of our study, with Luton as a comparator area, strongly suggests the ULEZ is driving this switch to active travel. This is evidence that Clean Air Zone intervention programmes aimed at reducing air pollution have the potential to also improve overall public health by addressing key factors that contribute to illness.”

Due to the introduction of COVID-19 restrictions in late March 2020, the study was paused in 2020/2021 and results are only reported for the first year of follow-up. However, as both London and Luton, the study areas, were similarly affected, the researchers believe this disruption is unlikely to have affected the results. The study has restarted following up with the children to examine the longer-term impacts of the ULEZ. This will identify if the changes they observed in the year following the introduction of the ULEZ persist.

The study was conducted in collaboration with Queen Mary University of London, Imperial College, University of Bedfordshire, University of Edinburgh, University of Oxford and University of Southern California and funded by the National Institute for Health and Care Research Public Health Research (NIHR), NIHR Applied Research Collaboration North Thames, and Cambridge Trust. 

Reference
Xiao, C et al. Children’s Health in London and Luton (CHILL) cohort: A 12-month natural experimental study of the effects of the Ultra Low Emission Zone on children’s travel to school. IJBNPA; 5 Sept 2024; DOI: 10.1186/s12966-024-01621-7

Four in ten children in Central London who travelled to school by car switched to more active modes of transport, such as walking, cycling, or public transport, following the introduction of the Ultra-Low Emission Zone (ULEZ), according to new research. In the comparison area with no ULEZ, Luton, only two in ten children made this switch over the same period.

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The research also suggests that people who are taking lipid-lowering drugs such as statins to lower their cholesterol levels should remain on them, even if their cholesterol levels have fallen, as stopping treatment could increase their risk of atherosclerosis.

Atherosclerosis is one of the major causes of heart and circulatory disease. It involves the hardening and narrowing of the vessels that carry blood to and from the heart. It is caused by the build-up of abnormal material called plaques – collections of fat, cholesterol, calcium and other substances circulating in the blood.

Atherosclerosis is largely considered a disease of the elderly and so most screening, prevention and intervention programmes primarily target those with high cholesterol levels, generally after the age of 50.

But in a study published today in Nature, a team led by scientists at the University of Cambridge shows that high cholesterol levels at a younger age – particularly if those levels fluctuate – can be even more damaging than high cholesterol levels that only begin in later life.

To study the mechanisms that underlie atherosclerosis, scientists often use animal modes, such as mice. The mice will typically be fed a high fat diet for several weeks as adults to see how this leads to the build up of the plaques characteristic of the condition.

Professor Ziad Mallat and colleagues at the Victor Phillip Dahdaleh Heart and Lung Research Institute at the University of Cambridge decided to explore a different approach – to see whether giving mice the same amount of high fat food but spread over their lifetime changed their atherosclerosis risk.

“When I asked my group and a number of people who are experts in atherosclerosis, no one could tell me what the result would be,” said Professor Mallat, a British Heart Foundation (BHF) Professor of Cardiovascular Medicine.

“Some people thought it would make no difference, others thought it would change the risk. In fact, what we found was that an intermittent high fat diet starting while the mice were still young – one week on, a few weeks off, another week on, and so on – was the worst option in terms of atherosclerosis risk.”

Armed with this information, his team turned to the Cardiovascular Risk in Young Finns Study, one of the largest follow-up studies into cardiovascular risk from childhood to adulthood. Participants recruited in the 1980s returned for follow-up over the subsequent decades, and more than 2,000 of them had received ultrasound scans of their carotid arteries when they were aged around 30 years and again at around 50 years.

Analysing the data, the team found that those participants who had been exposed to high cholesterol levels as children tended to have the biggest build of plaques, confirming the findings in mice.

“What this means is that we shouldn’t leave it until later in life before we start to look at our cholesterol levels,” Professor Mallat said. “Atherosclerosis can potentially be prevented by lowering cholesterol levels, but we clearly need to start thinking about this much earlier on in life than we previously thought.”

The mouse studies showed that fluctuating levels of cholesterol appeared to cause the most damage. Professor Mallat says this could explain why some people who are on statins but do not take them regularly remain at an increased risk of heart attack.

“If you stop and start your statin treatment, your body is being exposed to a yo-yo of cholesterol, which it doesn’t like, and it seems this interferes with your body’s ability to prevent the build-up of plaques,” he added.

The reason why this is so damaging may come down to the effect that cholesterol has on specific types of immune cells known as ‘resident arterial macrophages’. These reside in your arteries, helping them to clear damaged cells and fatty molecules known as lipids, which include cholesterol, and stopping the build-up of plaques.

When the team examined these macrophages in their mouse models, they found that high cholesterol levels – and in particular, fluctuating cholesterol levels – changed them physically and altered the activity of their genes. This meant that the cells were no longer protective, but were instead detrimental, accelerating atherosclerosis.

The research was funded by the British Heart Foundation.

Reference
Takaoka, M et al. Early intermittent hyperlipidaemia alters tissue macrophages to boost atherosclerosis. Nature; 4 Sept 2024; DOI: 10.1038/s41586-024-07993-x

Our risk of developing atherosclerosis – ‘furring’ of the arteries – can begin much earlier in life than was previously thought, highlighting the need to keep cholesterol levels low even when we are young, new research has discovered.

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These are among the conclusions of Time to Care: findings from a nationally representative survey of experiences at the end of life in England and Wales, a new report funded by end-of-life charity Marie Curie and produced by King’s College London’s Cicely Saunders Institute, Hull York Medical School at University of Hull, and the University of Cambridge.

Time to Care aims to describe the outcomes, experiences, and use of care services by people affected by dying, death, and bereavement in England and Wales. It is the final report from the Marie Curie Better End of life programme.

The report found one in five dying people had no contact with their GP in the last three months of life.

Half of people surveyed (49%) said their dying loved one visited A&E at least once in their final three months of life, and one in eight people who died in hospital had been there less than 24 hours. 

Half of respondents (49%) in the study were also unhappy with at least one aspect of the care the person who died received and of those one in eight people made a formal complaint. Fewer than half of respondents said they had a key contact person to co-ordinate their care. This meant responsibility for care fell on informal carers (family and friends), who often felt unprepared and unsupported.

Professor Stephen Barclay, from the Department of Public Health & Primary Care at the University of Cambridge, a researcher on the project and a practicing GP, said: “GPs, Community Nurses and the wider Primary Care Team have a central and often under-recognised role in the care of people approaching and at the end of their lives. But they are under enormous pressure with increasing workloads, diminishing workforces and inadequate investment over recent years.

“Increasing numbers of people have been dying in the community during and following the COVID-19 pandemic, at home or in care homes. This important survey, undertaken at a time when the NHS was beginning to recover from the worst of the pandemic, reveals how clinical teams in all settings are struggling to meet the needs of this vulnerable patient group.

“The out-of-hours period, which comprises two-thirds of the week, is particularly difficult for patients and their families. Across the UK, GPs and Community Nurses want to provide excellent palliative and end of life care, but the necessary ‘time to care’ is currently often squeezed. The new UK Government’s focus on care close to home is welcome. This report highlights the need for a radical repurposing of NHS funding to resource primary care for that ambition to be achieved.”

The research report is based on a survey sent by the Office for National Statistics in 2023 to a nationally representative sample of people who had registered the death of a family member in the prior six to 10 months. Only non-sudden causes of death were included. Responses were received from 1179 people, making this the largest nationally representative post-bereavement survey in England and Wales for a decade.

Professor Katherine Sleeman, from King’s College London and lead researcher on the project, said:  “This study reveals patchy and inconsistent provision of care for people approaching the end of life. While there were examples of excellent care - including in the community, in care homes, and in hospitals - the overall picture is of services that are overstretched, and of health and care staff lacking the time they need to consistently provide high-quality care. This means that dying people miss out on treatment and care for their symptoms, and families are left feeling unprepared and unsupported which has lasting emotional repercussions into bereavement.

The researchers say the findings are concerning, considering the ageing population and the expected increase in palliative care needs across the UK. By 2048, there will be an additional 147,000 people in the UK who need palliative care before they die, an increase of 25%.

“Without a corresponding increase in capacity of primary and community care teams to support these people as they approach the end of life, the quality of care is likely to further suffer,” said Professor Sleeman. “It has never been more important to ensure high-quality palliative care for all who need it.”

Annette Weatherley, Marie Curie Chief Nursing Officer, added: “The findings are shocking.  Too many people are dying in avoidable pain, struggling with breathlessness and other debilitating symptoms because of the difficulties they face accessing the end-of-life care they need from overstretched GPs and other health and care workers.

“Without urgent action, gaps in access to palliative and end of life care will only grow.

“It is a critical time to improve palliative and end of life care. People at the end of life should be able to have the very best possible care. There is only one chance to get it right at the end of life.  Yet, as the evidence shows, too many people are being failed by a system faced with extreme financial and workforce pressures.  It’s time for Governments to step up and fix care of the dying.”

Professor Stephen Barclay is a fellow at Emmmanuel College, Cambridge.

Adapted from a press release by Marie Curie

One in three dying people in England and Wales was severely or overwhelmingly affected by pain in the last week of life, with bereaved people reporting how difficult it was to get joined-up support from health and care professionals at home.

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A cancer drug that unlocks the anti-inflammatory power of the immune system could help to reduce the risk of future heart attacks, according to research part-funded by the British Heart Foundation. By repurposing an existing drug, researchers hope it could soon become part of routine treatment for patients after a heart attack.

The findings will be presented at the European Society of Cardiology Congress in London by Dr Rouchelle Sriranjan, NIHR Clinical Lecturer in Cardiology at the University of Cambridge.

High levels of inflammation in blood vessels are linked to an increased risk of heart disease and heart attacks. After a heart attack, the body’s immune response can aggravate existing inflammation, causing more harm and increasing risk even further. However, NICE guidelines don’t currently recommend the use of any anti-inflammatory drugs to reduce future risk.

Now, a team of researchers, led by Dr Joseph Cheriyan from Cambridge University Hospitals NHS Foundation Trust, have found that low doses of an anti-inflammatory drug called aldesleukin, injected under the skin of patients after a heart attack, significantly reduces inflammation in arteries.

The researchers are currently following up patients to investigate the longer-term impact of this fall in inflammation. To date, in the two and a half years after their treatment, there have been no major adverse cardiac events in the group that received aldesleukin, compared to seven in the group that received the placebo.

Professor Ziad Mallat, BHF Professor of Cardiovascular Medicine at the University of Cambridge who developed the trial, said: “We associate inflammation with healing – an inbuilt response that protects us from infection and injury. But it’s now clear that inflammation is a culprit in many cardiovascular conditions.

“Early signs from our ongoing trial suggest that people treated with aldesleukin may have better long-term outcomes, including fewer heart attacks. If these findings are repeated in a larger trial, we’re hopeful that aldesleukin could become part of routine care after a heart attack within five to 10 years.”

Aldesleukin is already used to treat kidney cancer, as high doses stimulate the immune system to attack cancer cells. The Cambridge team previously found that doses one thousand times lower than those used in cancer treatment increased the number of regulatory T cells – a type of anti-inflammatory white blood cell – in patients’ blood compared to a placebo.

In the current trial at Addenbrooke's and Royal Papworth hospitals in Cambridge, 60 patients admitted to hospital with a heart attack or unstable angina received either low dose aldesleukin or placebo. Patients received an injection once a day for the first five days, then once per week over the next seven weeks. Neither the participants nor their doctors knew whether they had received the drug or placebo.

At the end of treatment, Positron Emission Tomography (PET) scans showed that inflammation in the artery involved in patients’ heart attack or angina was significantly lower in the group treated with aldesleukin, compared to those who received the placebo.

The anti-inflammatory effect of aldesleukin appeared even more striking in the most inflamed arteries, leading to a larger reduction in inflammation levels in these vessels and a bigger difference between the two groups by the end of the study.

Dr Sonya Babu-Narayan, Associate Medical Director at the British Heart Foundation and consultant cardiologist said: “Thanks to research, we have an array of effective treatments to help people avoid heart attacks and strokes and save lives. But, even after successful heart attack treatment, unwanted inflammation in the coronary arteries can remain, which can lead to life-threatening complications.

“A treatment to reduce inflammation after a heart attack could be a game-changer. It would help doctors to interrupt the dangerous feedback loop that exacerbates inflammation and drives up risk. This research is an important step towards that treatment becoming a reality.”

The study was predominantly funded by the Medical Research Council, with significant support from the BHF and National Institute for Health and Care Research Cambridge Biomedical Research Centre (NIHR-BRC).

Originally published by the British Heart Foundation. 

Repurposed cancer drug helps to calm inflammation in arteries.

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The sight of vineyards in Britain is becoming more common as hotter summers create increasingly suitable conditions for growing grapes. But behind this success story is a sobering one: climate change is shifting the regions of the world suitable for growing crops.

Researchers at the University of Cambridge have uncovered a looming issue: as the land suitable for producing our food moves northwards, it will put a squeeze on the land we need to grow trees. The timber these trees produce is the basis of much of modern life – from paper and cardboard to furniture and buildings.

They say that the increasing competition between land for timber production and food production due to climate change has, until now, been overlooked – but is set to be an emerging issue as our demand for both continues to increase.

Under the worst-case scenario for climate change, where no action is taken to decarbonise society, the study found that over a quarter of existing forestry land – around 320 million hectares, equivalent to the size of India – will become more suitable for agriculture by the end of the century.

Most forests for timber production are currently located in the northern hemisphere in the US, Canada, China and Russia. The study found that 90% of all current forestry land that will become agriculturally productive by 2100 will be in these 4 countries.

In particular, tens of millions of hectares of timber-producing land across Russia will become newly suitable for agriculture – more than in the US, Canada and China put together – with conditions becoming favourable for potato, soy, and wheat farming.

“There’s only a finite area of suitable land on the planet where we can produce food and wood - 2 critical resources for society. As climate change worsens and agriculture is forced to expand northwards, there’s going to be increasing pressure on timber production,” said Dr Oscar Morton, a researcher in the University of Cambridge’s Department of Plant Sciences who co-led the study.

“We’ve got to be thinking 50 years ahead because if we want timber in the future, we need to be planting it now. The trees that will be logged by the end of this century are already in the ground – they’re on much slower cycles than food crops,” said Dr Chris Bousfield, a postdoctoral researcher in the University of Cambridge’s Department of Plant Sciences and co-leader of the study.

Global food demand is projected to double by 2050 as the population grows and becomes more affluent. Global wood demand is also expected to double in the same timeframe, in large part because it is a low-carbon alternative to concrete and steel for construction.

Shifting timber production deeper into boreal or tropical forests are not viable options, because the trees in those regions have stood untouched for thousands of years and logging them would release huge amounts of carbon and threaten biodiversity.

“A major environmental risk of increasing competition for land between farming and forestry is that wood production moves into remaining areas of primary forest within the tropics or boreal zones. These are the epicentres of remaining global wilderness and untouched tropical forests are the most biodiverse places on Earth. Preventing further expansion is critical,” said David Edwards, Professor of Plant Ecology in the University of Cambridge’s Department of Plant Sciences and senior author of the study.

To get their results, the researchers took satellite data showing intensive forestry across the world and overlaid it with predictions of suitable agricultural land for the world’s key crops -including rice, wheat, maize, soy and potato - in the future under various climate change scenarios.

Even in the best-case scenario, where the world meets net-zero targets, the researchers say there will still be significant future changes in the regions suitable for timber and crop production.

The study is published in the journal Nature Climate Change.

Timber production contributes over US $1.5 trillion (about £1.1 trillion) per year to national economies globally. Heatwaves and associated wildfires have caused huge recent losses of timber forests around the world. Climate change is also driving the spread of pests like the Bark Beetle, which attacks trees.

Climate change is expected to cause areas in the tropics to become too hot and inhospitable for growing food and make large areas of southern Europe much less suitable for food and wood production.

“Climate change is already causing challenges for timber production. Now on top of that, there will be this increased pressure from agriculture, creating a perfect storm of problems,” said Bousfield.

“Securing our future wood supply might not seem as pressing as securing the food we need to eat and survive. But wood is just as integrated within our daily lives and we need to develop strategies to ensure both food and wood security into the future,” said Morton.

Reference

Bousfield, C G, et al, ‘Climate change will exacerbate land conflict between agriculture and timber production.’ Nature Climate Change (2024). DOI: 10.1038/s41558-024-02113-z

Climate change will move and reduce the land suitable for growing food and timber, putting the production of these 2 vital resources into direct competition, a new study has found.

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An analysis of a short programme teaching empathy in schools has found it had a positive impact on students’ behaviour and increased their emotional literacy within 10 weeks.

The findings come from an evaluation of the 'Empathy Programme': a term-long course developed by the UK-based Empathy Studios. The research was conducted with support from academics at the Faculty of Education, University of Cambridge.

Empathy Studios develops school-based, video-led programmes which aim to increase empathy in students aged 5 to 18. Students are shown thought-provoking films, then engage in approximately 30 minutes of activities and discussions about the issues raised. An annual flagship festival of films, resources and events, 'Empathy Week', is made available for free and has to date reached 1.3 million students worldwide.

Survey and interview data from 900 students and teachers at 10 participating schools in 6 countries, including the UK, revealed measurable, positive changes in students’ conduct, emotional awareness and curiosity about different cultures and the wider world.

Teachers rated students’ empathy, behaviour and other characteristics on a scale of one to 10 before the programme began, and 5 and 10 weeks later. The average empathy score rose from 5.55 to 7, while average behaviour scores increased from 6.52 to 7.89.

In follow-up interviews, one primary school teacher reflected: “I’ve definitely been able to resolve more issues within the classroom and not have parents called in.” A student told the interviewers: “I think that everyone in the class has become kinder.”

Empathy Studios defines empathy as: “the skill to understand others and the ability to create space for someone to reveal their authentic self while reserving judgement.” The company was founded 4 years ago by Ed Kirwan, a former science teacher from North London.

“The programme’s success lies in teaching students to celebrate difference, which changes their wellbeing and behaviour,” he said. “There’s never an excuse for poor behaviour, but often a reason, which greater mutual understanding can potentially address.”

“I think the social unrest we have seen in Britain this summer shows how urgently we need more empathy across society. It won’t solve everything, but it is the foundation for solutions, and it starts with education. If the new government is serious about curriculum reforms that prepare young people for life and work, we must ensure that school equips them to understand, be curious about, and listen to each other, even in moments of disagreement.”

The evaluation was supported by Dr Helen Demetriou, a specialist in empathy education at the University of Cambridge, who helped to design the research, and to collect, quality assure and interpret the data.

“The findings show that a fairly simple, film-based programme can raise pupils’ empathy levels, enhancing their understanding of themselves, others, and global issues,” she said. “That supports a more complete learning experience, developing social and emotional skills that we know contribute to improved behaviour and more engaged learning.”

Although it is often considered innate, evidence suggests that empathy can be taught. A 2021 study co-authored by Demetriou successfully trialled teaching empathy during design and technology lessons. More recently, researchers at the University of Virginia found that empathy between parents and children is 'paid forward' by the children to friends and, later, when they become parents themselves.

Empathy has been linked to better leadership and inclusion in workplaces; while a 2023 World Economic Forum White Paper highlighted the importance of socio-emotional skills to the future of work and argued for more education that emphasises interpersonal skills, including empathy.

Empathy Studios offers schools assembly and lesson plans built around films about the real-life stories of diverse people in other parts of the world. Its 2024/5 programme, for example, profiles 5 individuals from Mexico, including a Paralympian, a dancer, and a women’s rights activist.

Their framework focuses on 3 core concepts: 'Empathy for Myself', which develops students’ emotional literacy; 'Empathy for Others', which covers mutual understanding and interpersonal relations, and 'Empathy in Action', during which the students develop their own social action projects.

The new research builds on a 2022 pilot study with the University of Cambridge, which suggested that the programme makes students more responsive to each others’ feelings and improves self-esteem. The new evaluation involved over 900 students and 30 teachers, and took place during 2023.

The teacher surveys indicated that behaviour had improved by up to 10% in some schools, especially those new to empathy lessons. The average improvement in behaviour recorded by UK teachers corresponded to the overall trend, rising from 6.3/10 pre-programme to 7.7/10 post-programme. Empathy and behaviour also appeared to be closely linked: all schools reporting an overall improvement in student empathy also saw improvements in behaviour after five weeks, which was sustained in 80% of cases after 10.

The evaluation recorded small improvements in students’ overall emotional literacy and their 'affective empathy'; or their ability to share the feelings of others. A change that emerged strongly from interviews with teachers was that the Empathy Programme appeared to increase students’ interest in other cultures. In one primary school, for example, the proportion of students responding positively to the statement “I want to find out more about the world” rose from 86% to 96% after 10 weeks. This echoes Organisation for Economic Co-operation and Development (OECD) evidence linking empathy to civic engagement.

Many students said they had learned valuable lessons from the programme. Their reflections included: “Everyone struggles… I’m not the only one who finds it hard”, and “Although we are all different, we all have so much in common”.

“Empathy is the number one human skill we need to develop for the future,” Kirwan said. “It should not just be an add-on; it should be considered foundational.”

Further information is available from: https://www.empathystudios.com/

A study involving 900 students in 6 countries found that a short programme of empathy lessons led to measurable, positive changes in their conduct, emotional awareness and curiosity about different cultures.