The Women’s Health Initiative was established in response to a growing realization that very little medical research existed to inform health care that was specifically relevant to women. In the U.S. in the 1970s, for example, almost 40% of postmenopausal women were taking estrogen, but no large clinical trials had studied the risks and benefits. In 1985 an NIH task force outlined the need for long-term research on women’s health.
Between 1993 and 1998, the project enrolled 161,808 postmenopausal women ages 50 to 79 to participate in four randomized clinical trials. Two of them investigated how menopausal hormone therapy affects the risk of heart disease, breast cancer, hip fractures and cognition. Another examined the effects of a low-fat, high-fiber diet on breast and colorectal cancers as well as heart disease. The fourth looked at whether taking calcium plus vitamin D supplements helps prevent hip fractures and colorectal cancer.
Women could participate in just one or in multiple trials. More than 90,000 also took part in a long-term observational study that used medical records and surveys to probe the link between risk factors and disease outcomes over time.
Clarifying the effects of hormone therapy
Some of the most important findings from the Women’s Health Initiative addressed the effects of menopausal hormone therapy.
The hormone therapy trial testing a combination of estrogen and progesterone was set to run until 2005. However, it was terminated early, in 2002, when results showed an increased risk in heart disease, stroke, blood clotting disorders and breast cancer, as well as cognitive decline and dementia. The trial of estrogen alone also raised safety concerns, though both types of therapy reduced the risk of bone fractures.
Although the Women’s Health Initiative’s four original clinical trials ended by 2005, researchers have continued to follow participants, collect new data and launch spinoff studies that shape health recommendations for women over 65.
One of the Women’s Health Initiative’s biggest yields is its vast repository of health data collected annually from tens of thousands of women over more than 30 years. The data consists of survey responses on topics such as diet, physical activity and family history; information on major health outcomes such as heart disease, diabetes, cancer and cause of death, verified using medical records; and a trove of biological samples, including 5 million blood vials and genetic information from 50,000 participants.
The Women’s Health Initiative set out to prevent heart disease, cancer and osteoporosis in menopausal women.
Any researcher can access this repository to explore associations between blood biomarkers, disease outcomes, genes, lifestyle factors and other health features. More than 300 such studies are investigating health outcomes related to stroke, cancer, diabetes, eye diseases, mental health, physical frailty and more. Thirty are currently running.
What does the future hold?
In addition to data amassed by the Women’s Health Initiative until now, about 42,000 participants from all 50 states, now ages 78 to 108, are still actively contributing to the study. This cohort is a rare treasure: Very few studies have collected such detailed, long-term information on a broad group of women of this age. Meanwhile, the demographic of older women is growing quickly.
Continuing to shed light on aging, disease risk and prevention in this population is vital. The questions guiding the project’s ongoing and planned research directly address the chronic diseases that Health Secretary Robert F. Kennedy Jr. has announced as national priorities.
So I hope that the Women’s Health Initiative can continue to generate discoveries that support women’s health well into the future.
Jean Wactawski-Wende receives funding from the NIH.
Source: United Kingdom – Executive Government & Departments
Case study
Molly Bartlet – UKRI Internship
During her PhD, Molly Bartlett took on a 3-month UKRI internship with the Government Office for Science (GO-Science), leading a high-profile project evaluating the impact of the UK’s Chief Scientific Advisers (CSAs).
Molly Bartlet, UKRI intern
Delivering real results
Molly co-led a high-level project to evaluate the impact of CSAs and the CSA Network in influencing government decision-making. She supported GO-Science in designing and conducting surveys and interviews with senior officials, leading to the production of a detailed report. The findings highlighted the crucial role of CSAs in ensuring that expert advice is embedded at the heart of policymaking which was then used to communicate the importance of the CSAs role following the change of government.
But Molly’s impact went beyond her main project. She also played a key role in organising several events and publishing a biweekly newsletter for the CSA network, enhancing collaboration across departments.
Building skills and broadening perspectives
Determined to get the most out of her placement, Molly completed Civil Service online courses in project management. These courses expanded her understanding of government structures and operations, while equipping her with valuable transferable skills for future roles.
Reflecting on her experience, Molly described her time at GO-Science as engaging. The supportive environment and meaningful projects expanded her perspective beyond academia, revealing career paths in science policy and public engagement.
Advice for future interns
Molly’s advice for future interns is simple: be proactive and open to new opportunities. Getting involved in different projects and engaging with various teams offers valuable insight into how research influences policy and decision-making. She believes skills in communication, event management, and stakeholder engagement are essential for success across a range of careers.
Lasting impact
Molly’s internship was more than just a learning experience, it was a chance to make a tangible difference. Her work strengthened CSA communication networks and demonstrated the importance of embedding expert advice within government. She recommends the internship for anyone interested in working in science but wanting an alternate path from academia or industry, the internship is a great opportunity to gain insights into many other science roles across government.
About the UKRI Policy Internship:
UK Research and Innovation (UKRI) offers internships that provide PhD students with the opporunity to see first-hand how science informs government decision-making at one of the selected group of influential policy organisations. These placements allow interns to contribute to policy-relevant projects, work with senior officials, and develop skills that bridge the gap between research and public policy. Currently, the scheme supports on average 125 internships per year across all host partners. Find out more information.
A new study by U.S. National Science Foundation-funded researchers on how members of the animal world sense and react to sounds provides insight into adaptations in communication that could be used in the development of adaptable hearing aids or limiting the impact of agricultural pests.
“By increasing our understanding of how animals perceive and respond to sounds — especially when those sounds are changing — this research could aid in developing hearing aids that automatically tune as a person walks from a movie theater to a crowded restaurant or other adaptive hearing and acoustics devices,” said Jodie Jawor, a program director in the NSF Directorate for Biological Sciences. “It also highlights how agricultural pests can move into an area and capitalize on a new host, harming society in the process — think about a parasite of honeybees that hurts their populations and our food supply.”
The study focused on the interactions between a species of fly (Ormia ochracea) and Pacific crickets, which are engaged in a sort of sound arms race. The fly can hear the mating chirps of the male cricket and uses the sounds to locate the male, in which the fly lays its eggs. The fly larvae feed on and develop inside of their cricket hosts, eventually killing them when they emerge. Some crickets in Hawaii have responded to this threat by changing the sounds they use to find mates — purring or rattling rather than chirping — but the flies still find them, and the researchers sought to understand how.
The research team, led by Norman Lee, an associate professor of biology at St. Olaf College, and Robin Tinghitella, an associate professor of biology at the University of Denver, used a series of lab experiments to test if this was a unique counteradaptation by flies in areas where both they and crickets have been introduced or if the flies had always been able to hear the alternative noises but not focused on them, as in their natural habitats such sounds would not have signaled a cricket. The researchers found that populations of flies from natural and non-natural habitats could hear the purrs, but the flies from areas where they have been introduced were more active in their response to the sounds. This represents a novel change caused by adaptation to a new environment, knowledge that could support advances in assistive hearing devices for humans and shows the growing number of interactions that drive how species communicate.
NEW YORK, May 02, 2025 (GLOBE NEWSWIRE) — Konik Capital Partners, LLC, a division of T.R. Winston & Co., a full-service boutique investment banking firm, is proud to announce its official launch. The firm, founded by Capital Markets veteran Ryan Konik, will take its relationship-first approach to financial advisory services, prioritizing clients’ needs and goals, while providing transparent, personalized guidance throughout the entire process. This commitment to putting clients first, always, forms the foundation of every client relationship and transaction.
“Konik Capital Partners was founded to address a structural inefficiency in today’s capital markets: the persistent undercapitalization of early-stage science and technology companies. Despite their potential to reshape entire industries, these innovators are often overlooked. Our mission is to correct this imbalance by providing the capital and partnership needed to help them reach critical inflection points. In doing so, we create value for our clients as well as contribute to the growth of the broader innovation ecosystem,” said Alden Carrere, Co-Founder & Partner, Konik Capital Partners.
With over 75 years of combined experience in Equity Capital Markets and institutional sales, Konik Capital Partners is exceptionally equipped to deliver comprehensive strategic financial advisory services to emerging growth businesses and their investors globally. The firm leverages its deep-rooted relationships with institutional investors and intimate understanding of capital markets to provide highly tailored solutions across underwriting, advisory, and trading.
“We are uniquely positioned to provide value-added, long-term capital markets partnerships to life sciences, technology, and other emerging growth companies, addressing a need in today’s market,” said Ryan Konik, Founder of Konik Capital Partners.
About Konik Capital Partners Konik Capital Partners is a boutique investment bank delivering strategic and financial advisory services to emerging growth businesses and their investors. With over 75 years of combined industry experience, we leverage our deep market knowledge with personalized attention to provide comprehensive solutions for our clients’ needs. Globally, we deliver end-to-end strategic, financial advisory, and capital markets services. Our distinctive approach and commitment to excellence drive client success in today’s dynamic market environment.
About T.R. Winston & Co. T.R. Winston & Company is a merchant, corporate and investment banking firm. We commit to long-term relationship banking based on value creation, integrity and measurable performance. We work with operating companies, institutional investors, family offices, and ultra-high net worth individuals. We seek to partner with management teams who are pursuing sound business models with the potential for growth. In addition to our merchant, corporate and investment banking activities, we maintain prime services and institutional trading capabilities.
The men’s cricket World Cup final match between Australia and India on Nov. 19, 2023, had a peak of 59 million concurrent streaming viewers.AP Photo/Rafiq Maqbool
Live and on-demand video constituted an estimated 66% of global internet traffic by volume in 2022, and the top 10 days for internet traffic in 2024 coincided with live streaming events such as the Jake Paul vs. Mike Tyson boxing match and coverage of the NFL. Streaming enables seamless, on-demand access to video content, from online gaming to short videos like TikToks, and longer content such as movies, podcasts and NFL games.
The defining aspect of streaming is its on-demand nature. Consider the global reach of a Joe Rogan podcast episode or the live coverage of the SpaceX Crew Dragon spacecraft launch – both examples demonstrate how streaming connects millions of viewers to real-time and on-demand content worldwide.
I’m a computer scientist whose research includes cloud computing, which is the distribution of computing resources such as video servers across the internet.
Netflix claimed that it supported 65 million concurrent streams for the Jake Paul vs. Mike Tyson boxing match on Nov. 15, 2024, though many users reported technical issues.
‘Chunks’ of video
When it comes to video content – whether it’s a live stream or a prerecorded video – there are two major challenges to address. First, video data is massive in size, making it time-consuming to transmit from the source to devices such as TVs, computers, tablets and smartphones.
Second, streaming must be adaptive to accommodate differences in users’ devices and internet capabilities. For instance, viewers with lower-resolution screens or slower internet speeds should still be able to watch a given video, albeit in lower quality, while those with higher-resolution displays and faster connections enjoy the best possible quality.
To tackle these challenges, video providers implement a series of optimizations. The first step involves fragmenting videos into smaller pieces, commonly referred to as “chunks.” These chunks then undergo a process called “encoding and compression,” which optimizes the video for different resolutions and bitrates to suit various devices and network conditions.
When a user requests an on-demand video, the system dynamically selects the appropriate stream of chunks based on the capabilities of the user’s device, such as screen resolution and current internet speed. The video player on the user’s device assembles and plays these chunks in sequence to create a seamless viewing experience.
For users with slower internet connections, the system delivers lower-quality chunks to ensure smooth playback. This is why you might notice a drop in video quality when your connection speed is reduced. Similarly, if the video pauses during playback, it’s usually because your player is waiting to buffer additional chunks from the provider.
Video streams come to users at different quality levels based on the user’s device and internet connection. Chetan Jaiswal
Dealing with distance and congestion
Delivering video content on a large scale, whether prerecorded or live, poses a significant challenge when extrapolated to the immense number of videos consumed globally. Streaming services like YouTube, Hulu and Netflix host enormous libraries of on-demand content, while simultaneously managing countless live streams happening worldwide.
A seemingly straightforward approach to delivering video content would involve building a massive data center to store all the videos and related content, then streaming them to users worldwide via the internet. However, this method isn’t favored because it comes with significant challenges.
One major issue is geographic latency, where a user’s location relative to the data center affects the delay they experience. For instance, if a data center is located in Virginia, a user in Washington, D.C., would experience minimal delay, while a user in Australia would face much longer delays due to the increased distance and the need for the data to traverse multiple interconnected networks. This added travel time slows down content delivery.
Another problem is network congestion. As more users worldwide connect to the central data center, the interconnecting networks become increasingly busy, resulting in frustrating delays and video buffering. Additionally, when the same video is sent simultaneously to multiple users, duplicate data traveling over the same internet links wastes bandwidth and further congests the network.
A centralized data center also creates a single point of failure. If the data center experiences an outage, no users can access their content, leading to a complete service disruption.
Content delivery networks
To address these challenges, most content providers rely on content delivery networks. These networks distribute content through globally scattered points of presence, which are clusters of servers that store copies of high-demand content locally. This approach significantly reduces latency and improves reliability.
Content delivery network providers, such as Akamai and Edgio, implement two main strategies for deploying points of presence.
The first is the “Enter Deep” approach, where thousands of smaller point-of-presence nodes are placed closer to users, often within internet service provider networks. This ensures minimal latency by bringing the content as close as possible to the end user.
This diagram, with the internet backbone at the top and users at the bottom, shows the ‘Enter Deep’ approach to placing content delivery servers ‘deep’ in the network, close to users. Chetan Jaiswal
The second strategy is “Bring Home,” which involves deploying hundreds of larger point-of-presence clusters at strategic locations, typically where ISPs interconnect: internet exchange points. While these clusters are farther from users than in the Enter Deep approach, they are larger in capacity, allowing them to handle higher volumes of traffic efficiently.
This diagram, with the internet backbone at the top and users at the bottom, shows the ‘Bring Home’ approach to placing content delivery servers between backbone and regional internet service providers. Chetan Jaiswal
Infrastructure for a connected world
Both strategies aim to optimize video streaming by reducing delays, minimizing bandwidth waste and ensuring a seamless viewing experience for users worldwide.
The rapid expansion of the internet and the surge in video streaming – both live and on demand – have transformed how video content is delivered to users globally. However, the challenges of handling massive amounts of video data, reducing geographic latency and accommodating varying user devices and internet speeds require sophisticated solutions.
Content delivery networks have emerged as a cornerstone of modern streaming, enabling efficient and reliable delivery of video. This infrastructure supports the growing demand for high-quality video and highlights the innovative approaches needed to meet the expectations of a connected world.
Chetan Jaiswal does not work for, consult, own shares in or receive funding from any company or organization that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.
Source: The Conversation – USA – By Brady Thomas West, Research Professor of Survey and Data Science, University of Michigan
Demonstrators protest funding cuts outside of the U.S. National Institutes of Health in Bethesda, Md., on March 8, 2025.Michael Mathes/AFP via Getty Images
In its first 100 days, the Trump administration has terminatedmore than US$2 billion in federal grants, according to a public source database compiled by the scientific community, and it is proposing additional cuts that would reduce the $47 billion budget of the U.S. National Institutes of Health, also known as the NIH, by nearly half.
The effects of these cuts are being felt at top-tier public research institutions such as the University of Michigan. In fiscal year 2024, of the $2 billion in total research expenditures at the university, $1.2 billion came in through federal research grants, with $762 million from NIH alone.
Brady West is a research professor at the University of Michigan who has been writing federal grant proposals for more than two decades. The Conversation U.S. spoke with him about what these cuts could mean for the university and scientific research in the U.S. going forward.
The University of Michigan’s research arm includes “soft money” institutes. What does that mean?
Brady West: A soft money institute is one where the salaries are entirely funded by the research grants and contracts that they’re able to obtain. This is the case for most of the research arm of the University of Michigan, which includes the Institute for Social Research where I work. The university sets the salary amounts for these positions, and the people filling them − whether faculty, staff or graduate students − have to raise the money to fund their salary.
Teaching faculty, on the other hand, usually are paid from general university funds, which might come in from sources such as tuition, rather than grant funding.
What is involved in applying for a grant from a federal institution like NIH?
West: In my experience, it’s an extremely competitive and stressful process.
On average, I would estimate that it takes about a year to craft a research proposal from scratch. Applicants do background research, look at all the relevant work that has already been done in the field, summarize the articles that they’ve written, and sometimes do initial preliminary studies. They have to sell their research as connected to past work but still innovative, something that will move the science forward.
Meanwhile, they’re working with a team of research administrators, whose jobs at the university are funded by soft money, on things like creating a budget and determining what sort of supplies, equipment and additional personnel will be required for the research project. These administrators also help the applicant format and submit the proposal.
How does NIH determine what proposals receive funding?
West: Every proposal submitted to NIH gets reviewed by a panel of experts in that particular field, so your peers are the ones reviewing your proposal and deciding whether it should be considered for funding.
Each panel is tasked with reviewing and scoring multiple proposals. About half of the proposals receive scores that do not warrant additional discussion for funding. The rest are scrutinized line by line.
Those with the best scores, based on their merits as well as agency budgets and priorities, are ultimately awarded grants. All applicants are sent the reviewers’ comments, and those not receiving funding may revise their proposal and resubmit. In my experience, few applications get funded the first time they are submitted, and most go through at least one round of revisions.
I’ve found it generally takes about two years from the time you start writing a proposal to the time that you get funded.
When did you learn that NIH and other federal grants were being rescinded at the University of Michigan?
West: The first notice I received was in mid-February of 2025. I was wrapping up a federally funded study where we were looking at different ways of measuring sexual identity in surveys. That study was funded by a $160,000 grant from NIH.
I received a notice from administrators for the National Center for Health Statistics – part of the Centers for Disease Control and Prevention – that maintains the data I was working with. The email said my work was being reviewed for compliance with the president’s executive orders and would be paused.
The email Brady received from the National Center for Health Statistics, terminating his access to the secure data he’d been using for his NIH-funded research study. courtesy of Brady Thomas West, CC BY
I was lucky, because that particular grant was set to end at the end of February, so the project was nearly finished, and the paper was already written.
And then over the following weeks, it was like a waterfall. I started hearing from colleagues who were working on grants related to climate change, vaccination, vaccine hesitancy, sexual identity, gender identity, DEI – all of the work related to that, I just heard story after story of these grants being ended on the spot.
What does this mean for the researchers who lost their funding? What will they do now?
West: These terminations put jobs at risk – not only the research faculty, but also the teams who were working on these projects and the administrators who helped format and submit the grants.
One of my Ph.D. students received an email from NIH that simply said his grant has been terminated. So his source of support as a graduate student at the University of Michigan was gone in an instant.
The University of Michigan has developed a new research funding program where you can apply for support if you’ve had your grant terminated, and your local department can help share the costs. My student is waiting to hear if he will receive some of that funding. This is a welcome development, but only a short-term solution to this problem.
So right now, everybody’s pivoting. Your first thought is, how can I write a proposal that’s not going to have certain keywords in it? And that’s just not a good way to do science.
The University of Michigan is committed to doing the best possible science, but it’s going to require some adaptation in terms of how to think about the proposal process. And, honestly, for the immediate future, part of being a scientist in the U.S. is getting a firm understanding of what the current administration wants to fund.
Are you or your colleagues considering leaving the university?
West: That’s the million-dollar question. Do you decide to pack up your family and move to a different country? Do you shift to private industry? Do you wait it out for the next administration and hope that things swing back in a direction that’s going to support the kind of work that you’re doing? Those are the kinds of career decisions that people have to think about.
Is the U.S. going to lose a lot of top-tier faculty at top-tier universities like the University of Michigan because of what’s going on? That’s a significant concern.
Brady Thomas West has received funding from the U.S. National Institutes of Health, the American Heart Association, the U.S. Department of Agriculture and National Science Foundation.
Source: United Kingdom – Executive Government & Departments
Press release
Creative industries and growth boosted with new UK-India cultural agreement
UK’s arts and culture, creative industries, tourism and sport sectors are set to benefit from a major new cooperation agreement with India
UK’s arts and culture, creative industries, tourism and sport sectors are set to benefit from a major new cooperation agreement with India
Culture Secretary leading a delegation of cultural leaders and UK institutions to Mumbai and New Delhi this week
Agreement to boost collaboration between British and Indian creative businesses and cultural institutions, delivering on Plan for Change to drive growth and opportunity
The UK’s arts and culture, creative industries, tourism and sport sectors are set to benefit from a major new cooperation deal and economic links with India, as the government delivers on its Plan for Change to boost growth and opportunity.
Culture Secretary Lisa Nandy, who is of Indian heritage, arrived on Thursday for a three-day visit to Mumbai and New Delhi. She has today (Friday) signed a new bilateral Cultural Cooperation Agreement with India’s Minister for Culture and Tourism, Shri Gajendra Singh Shekhawat. She has been joined on the trip by a delegation of senior leaders from VisitBritain, the British Film Institute and the Science Museum, to drive further collaboration between British and Indian creative businesses and cultural institutions.
The agreement will open the door for increased UK creative exports to India and enable more partnerships between UK and Indian museums and cultural institutions, helping to grow UK soft power.
On Thursday the Culture Secretary delivered a keynote speech at the World Audio Visual and Entertainment Summit (WAVES) in Mumbai, which was also attended by the Prime Minister of India, Narendra Modi. Her speech celebrated the living bridge that connects the UK and India, and showcased the strength and attractiveness of the UK’s creative industries, one of the growth-driving sectors identified in the UK government’s Industrial Strategy.
The Culture Secretary then toured Yash Raj Films Studio, where some of the most popular Bollywood films with audiences in the UK are made. Both the UK and India boast rich cinematic traditions and share a deep mutual interest in each other’s storytelling cultures, and the Culture Secretary wants to see more collaboration between UK and Indian film productions.
UK Secretary of State for Culture, Media and Sport Lisa Nandy said:
In the arts and creative industries, Britain and India lead the world and I look forward to this agreement opening up fresh opportunities for collaboration, innovation and economic growth for our artists, cultural institutions and creative businesses.
Growing up as a mixed race child with proud Indian heritage, I saw first hand how the UK’s culture – from food, fashion and film to music, sport and literature – is enriched by the unique contribution of the Indian diaspora. It has given me a deep connection to India’s culture and people and it is an honour to be visiting this magnificent country to forge a closer cultural partnership.
During the visit:
This evening the Culture Secretary will attend a marquee event at the British Council in Delhi, where she will preview performances from India’s Serendipity Arts Festival which is due to hold a mini festival in Birmingham in May and a large-scale event in London next year.
At the same reception, Visit Britain CEO Patricia Yates will launch the Starring GREAT Britain campaign in India, which will draw upon film and TV locations as a driver for inward tourism to the UK.
In the Okhla neighbourhood of Delhi, she will tour boutique fashion houses and workshops and meet a range of Indian fashion designers with UK links.
Earlier today the Culture Secretary met female cricketers at the Sharad Pawar Sports Club, ahead of India hosting the Women’s Cricket World Cup in October 2025. On Saturday she will meet football coaches involved in the Premier League Primary Stars programme in India, a partnership between the Premier League and the British Council to improve physical and sports education in primary schools. Earlier this week the Premier League announced it was opening a new office in Mumbai.
As well as her meetings with the Minister for Culture and senior Indian government ministers, the Culture Secretary is also expected to meet with significant Indian investors and business leaders.
Actor and writer Sanjeev Bhaskar said:
The creative industries are a powerful, enjoyable way to bring people together so I hope this visit further solidifies a mutual appreciation not just of the long established arts of both countries but also the evolving areas of film, music and theatre that are successfully combining artistic traditions from India and the UK to explore and cement what is a unique relationship.
Film director Gurinder Chadha said:
As a filmmaker who has spent my career celebrating being British Punjabi and honouring the connections between Britain and India, it is great to see our cultural bonds further strengthened through this new agreement from my friend and colleague Lisa Nandy.
Now we have a real opportunity to unlock exciting new creative opportunities for artists and storytellers to the benefit of both our countries.
ENDS
UK-India Programme of Cultural Cooperation Agreement
The Culture Secretary and Minister for Culture are expected to formally sign the UK-India Programme of Cultural Cooperation. The two nations will commit to enhancing cultural exchange between the UK and India through the arts and heritage, and to encourage long-term partnerships between UK and Indian businesses and cultural institutions.
Implementation will involve the British Council in India and the Indian Ministry of Culture, with participation from major UK cultural institutions including Arts Council England, the British Library, the British Museum, Natural History Museum, Science Museum Group and the V&A Museum. This has the potential for British museums to launch new partnerships on exhibitions or public programmes that engage the Indian diaspora in the UK.
The UK will work with India to support best practice and expertise on heritage conservation, museum management and digitisation of collections – including making knowledge contained in South Asian manuscripts more widely accessible, and the protection of cultural property, with both nations committing to combat illicit trafficking of cultural artifacts.
Further quotes:
Sir Ian Blatchford, Director and Chief Executive of the Science Museum Group, said:
This commitment from the British and Indian Governments to deeper cultural cooperation will further strengthen our relationships with Indian cultural and scientific organisations, helping the Science Museum Group to share ever more fascinating stories of scientific discovery with audiences in both the UK and India.
Visitors to Science City in Kolkata can explore our Injecting Hope exhibition – which delves into the rapid development of COVID-19 vaccines and was created in partnership with India’s National Council of Science Museums – now on display as part of an international tour that has inspired nearly five million visitors in museums across India, China and the UK.”
Tristram Hunt, Director of the V&A, said:
The V&A is delighted to contribute to the new UK-India cultural partnership. It will increase our ability to loan more objects from our world-class collection, and build strategic relationships with the booming Indian arts scene across design, fashion, photography, and performance.
Dr Nicholas Cullinan, Director of the British Museum, said:
The British Museum’s collaboration with partner museums across India are some of our deepest and most successful. For example, in Mumbai, we have a groundbreaking partnership with the CSMVS Museum – one of India’s biggest – which is based around the reciprocal exchange of objects, knowledge, and ideas.
I’m delighted that the UK-India Cultural Cooperation Agreement recognises, at the highest level, the importance of cultural collaboration between our two countries and we look forward to strengthening these partnerships further.”
Director of the Natural History Museum Doug Gurr said:
India is clearly a nation of talented, passionate and prolific wildlife photographers! Indian photographers have consistently been well-represented in our prestigious photography competition Wildlife Photography of the Year – and this year we had a record-breaking number of over 300 entrees from India, an increase of 79 per cent!
It has been our honour to share the awe-inspiring images of our Indian alumni to millions of people worldwide and we have had the pleasure of collaborating with Dhritiman Mukherjee, Ripan Biswas and Nayan Khanolkar to deliver conservation photography workshops for young people in Kolkata. We are thrilled that our connection continues at the Visual Poetries Photography Festival in Gujarat this summer, with our Competition Manager joining their jury and our Wildlife Photography of the Year Highlights on display throughout.
Rebecca Lawrence, Chief Executive of the British Library, said:
The British Library has a long history of successful collaboration with our peers in India, including on the landmark ‘Two Centuries of Indian Print’ project and through our Endangered Archives Programme.
We warmly welcome this agreement which will provide opportunities to further deepen our partnerships, exchange valuable professional skills and insights, and strengthen our shared networks of knowledge and culture.
More information:
VisitBritain forecasts a record 766,000 visits from India to the UK in 2025, up 7 percent on 2024, with travellers spending £1 billion – a 12 per cent year-on-year growth.
The BPI has reported that British music exports to India experienced a significant 26.3 percent increase in revenue. This moves India into the top 20 biggest overseas territories for UK recorded music, and there have recently been tours by major British acts including Coldplay in January and Ed Sheeran in February.
Mark Adams received his Ph.D. in Polymer Science from the University of Connecticut in 1993. After an 11-year tenure with Dow Chemical, Adams joined Henry Company in various vice president and senior vice president roles. Following his tenure at Henry Company, Adams joined Associated Materials, acting in senior vice president and later executive vice president positions. Since May of 2023, Adams has served as the Chief Operating Officer of HASA Inc., a large water treatment company based in southern California.
IMS reached out to Adams with five questions about his breadth of professional experience since obtaining his Ph.D., and how his time at UConn shaped it. Adams shows us that with grit, passion, and a strong support system, career growth occurs naturally.
Why did you choose to pursue your Ph.D. in polymer science at UConn?
My plan was to go to medical school after completing a B.S. in Chemistry from UConn. While working on my B.S., I took Physical Chemistry with Professor Andrew Garton. One day about halfway through the semester, he approached me after class and asked about what I was going to do after undergrad. I told him I was planning to go to medical school. He asked if I had ever considered grad school.
(contributed photo)
He went on to talk about an opportunity to go to the Institute of Materials Science for a Ph.D. in Polymer Science, working with him under a grant from NASA. Curious about the opportunity, I went to visit him at IMS, and the rest is history. I changed direction and worked to earn my Ph.D. on a research project for NASA, studying the degradation of polymeric spacecraft materials in the low earth orbit.
Who were some of the people who helped or inspired you most during your time at UConn, and how did their influence carry over into your professional career?
Obviously, Professor Garton had a huge impact on my academic career. He was incredibly energetic and excited about his research, which was infectious in his research group. When he passed away suddenly, prior to me completing my thesis, I was shocked and somewhat lost. My mentor in research was gone, and I was uncertain about the future and the choices I made. Fortunately, Sam Huang took me on to complete my degree.
Dr. Garton and other faculty at IMS taught me the importance of first principles and how to do research, but Dr. Garton is responsible for teaching me how to apply learning. How to identify a problem, develop root cause, research/develop technology needed, and implement technology solutions. He also helped me develop continuous improvement skills that have become the backbone of my career. Advanced research is interesting and fun but, using that to develop products and solutions is exciting.
A lot of your professional experience is more on the business side rather than in a lab or research setting. How did your Ph.D. and heavy scientific background impact your trajectory for success in so many executive-level corporate roles?
The first few roles early in my career were focused on technology and product development, which heavily leveraged my Ph.D. Successfully translating these efforts into value-creating opportunities required a complex voice of the customer requirements, which was only obtained and validated through observation and communication with end users. It’s at this interface where my unique skills started to develop, and when my career started taking turns from R&D leadership to new business development, sales, commercial leadership, and operations leadership. I have been fortunate to work with exceptional executive leaders that continually challenged and developed me, which has produced a myriad of different and challenging roles. This would not have been possible without the solid foundation I received from IMS and UConn.
What advice do you have for current polymer science students who may be unsure of their career paths?
Figure out your “internal” job description as early as possible. In other words, determine what you like to do most in combination with the skills and experience you have developed. When you figure out what your internal job description is, and you find a role that matches, you will experience dramatically accelerated growth. In my case, that was away from pure and applied research, and more focused on deploying all kinds of chemistry and engineering to develop solutions that rapidly grow businesses. Once you figure that out, job opportunities come faster than will be comfortable.
What are you most proud of having accomplished so far in your current position, and what do you most hope to accomplish going forward?
I am currently the Chief Operations Officer at a specialty chemical company specializing in water treatment. This role is truly the culmination of all my years of experience in multiple functions and companies. I am responsible for Operations at 12 sites, Engineering, Product/Process Development, EH&S, Continuous Improvement, Quality, and Transportation.
My biggest accomplishment so far with this company has been successfully restructuring and realigning our engineering group into a segmented portfolio management approach. We had way too many projects, worked on all of them at once, with too few resources, and no prioritization. Everything was delayed and above budget. Now, we are executing on time and on budget across the board on a full spectrum of projects from large new site design-builds, down to site specific capex projects.
My biggest challenge is developing and implementing automation technology in our packaging plants. We still require too much manual labor in an environment that is ergonomically challenging. Also, working with hazardous and corrosive materials poses unique challenges to metals and circuitry, so we needed to develop materials, machines, and now robots that reliably operate in challenging environments with hazardous chemicals. I guess it’s kind of like my Ph.D. work that analyzed polymers in low earth orbit, also a challenging and unforgiving environment.
IMS thanks Mark Adams very much for his willingness to share his unique journey, and we are excited to see where he takes HASA next.
On May 10 and 12, 2025, the College of Agriculture, Health and Natural Resources (CAHNR) and the Ratcliffe Hicks School of Agriculture will recognize graduates as they meet a major academic milestone.
Learn about a few of the nearly 600 stellar students who will soon become CAHNR alumni.
Bendy Al Zaatini, Allied Health Sciences
Hometown: Waterbury, CT
Why UConn? Throughout the chaos of the pandemic, I was positive that staying at home while simultaneously building my community at UConn Waterbury would be the right way to start my journey as an undergraduate student at the prestigious school. I was surprised by the number of resources that are available to students. There is always help when needed and many different pathways to achieve success.
Why your major? I am an Allied Health Sciences major, and I was drawn to it because of the different career opportunities that fall under this major. My plan after graduation is to receive my second bachelor’s degree through CEIN, the accelerated nursing program with UConn, starting January 2026.
Advice for incoming students? Stay busy, make your presence known, and make sure that everything you are involved in benefits you in different ways. Throughout your many involvements, never forget that you are a student first and prioritize your grades above all else.
Benjamin Angus, Agricultural and Resource Economics
Hometown: Avon, CT
WhyUConn? I have been a UConn fan my entire life, so for me it was a no brainer. Coming to Gampel as a kid or tailgating at Rentschler, UConn sports for me wasn’t a hobby, it was a lifestyle.
Why your major? I am a double major in Environmental Science and Natural Resource Economics. I am eager to join the fight against climate change and am looking forward to wherever that takes me. It is the most pressing issue of our time. After graduation, I am exercising my Covid year and coming back to UConn to get my Masters in Applied Resource Economics. After that, who knows? Wherever the wind takes me.
Advice for incoming students? When you sit down in class on the first day, talk to the person next to you. Learn their name, get their number, ask them their life story – just put yourself out there and I promise you will meet some incredible human beings. Also, bundle up on a clear winter night and walk to the top of Horsebarn Hill. No one ever looks at the stars in the winter, they are breathtaking.
Matt Antunes, Plant Science and Landscape Architecture
Hometown: Smithfield, RI
WhyUConn? UConn was a top ranked school in my choices for college, and I felt like I would get the best education for my major. I felt at home in my time at UConn with the friends and connections I made throughout my four years here.
Why your major? Plant Science (Sustainable Plant and Soil Systems) – with a turfgrass concentration. I always had a love for turf from a young age. Beginning with just mowing my home lawn as a teenager to eventually building a small putting green, I found I was always around turfgrass systems in my summers. I plan on continuing my education here as a graduate student studying turfgrass pathology, and I plan on working in the golf course industry as an assistant superintendent and hopefully a superintendent down the road.
Advice for incoming students? Go to a UConn sporting event (especially basketball even if you’re not into it). The energy and atmosphere are unmatched to any other sporting event I’ve been to in my lifetime.
Jillian Bowen, Pathobiology and Veterinary Science
Hometown: Trumbull, CT
WhyUConn? The academics were the main draw for me. As an R1 institution, I knew that UConn had a lot of research opportunities, and that really drew me in.
Why your major? My major is Pathobiology, or disease biology. I attended an agricultural high school and was a member of Future Farmers of America, so I already had an interest in animal science, but the pandemic was definitely a big factor in stimulating my interest in infectious diseases. Pathobiology is a perfect combination of those interests! After graduation, I am planning to attend UConn’s Master of Public Health program with a concentration in epidemiology.
Advice for incoming students? Variety is the spice of life, so don’t be afraid to try something completely different – learn how to breakdance! Join an improv group! Start a book club! The world is your oyster.
John-Henry Burke, Natural Resources and the Environment
Hometown: Suffield, CT
Why UConn? I chose UConn because I thought it offered the best ‘bang for my buck.’ You get an incredibly large institution with a large number of resources and a diverse array of opportunities for a price that is much more affordable than other schools.
Why your major? I’m an Environmental Science major with a concentration in Sustainable Systems and a minor in Political Science and a minor in Environmental Economics and Policy. I was drawn to environmental science after taking a class in high school where I learned about climate change, plastic pollution, species extinction, and other threats facing our planet. I’m going to law school in the fall, and I would like to ultimately go into environmental law to advance environmental policy and protect natural areas.
Top UConn memories? One of the best parts of my UConn experience has been playing in the UConn Marching Band, where I served as Vice President. I’ve met so many amazing people through the band and accomplished a level of musicality I would’ve never imagined possible. Some notable UCMB performances were playing at a New England Patriots game and two Bowl games (Fenway and Myrtle Beach)!
Christian Carmona, Plant Science and Landscape Architecture
Hometown: Stamford, CT
WhyUConn? I chose UConn because it helped me the most financially and it was not as far away from my house as others were.
Why your major? My major is Landscape Architecture, and what drew me to it was that it was a form of architecture I had never heard of before. I was eager to try it out, and it gave me the opportunity to be creative and design spaces for communities. I hope to continue my education and pursue a master’s in architecture.
Advice for incoming students? Be open minded and ready to learn. You are here for a reason so stay focused on your goals and do not take anything for granted.
Laura Centanni, Animal Science
Hometown: Haworth, NJ
WhyUConn? I was leaning towards UConn due to the diversity of species in our barns on campus; however, what tipped the scales in the end was the mascot!
Why your major? My major is Animal science. I have had a passion for animals and service for as long as I can remember, and I am pursuing my passion of becoming a veterinarian through animal science here at UConn. I have already received my first few acceptances to vet school! Wherever I choose, I know that UConn prepared me well.
Advice for incoming students? Expand your comfort zone. Let it get so big that nothing is outside of it. UConn is one of the safest environments to explore that you will ever have, so take advantage of it!
Jessica Harris, Allied Health Sciences
Hometown: Mansfield, MA
WhyUConn? When it was time for me to look at colleges, I was excited to apply to UConn as is but I also discovered that CAHNR offered the major I was interested in, Allied Health Sciences, as part of the New England Regional Tuition Program. This made UConn such an easy choice for me because of its well-known academic excellence and affordability as an out of state school.
Why your major? I applied into UConn as an AHS major, because it would allow me to do my prerequisite courses to apply to physical therapy school, but I soon learned that it was not the right path for me. Luckily, AHS is such an adaptable major, intended to cater to your career interests, that I was able to stay on track despite changing paths, and ended up finding exactly what I wanted to do: UConn’s CEIN program.
Top UConn memories? Going to the UConn Dairy Bar, and 2023 when we won the Men’s National Basketball Championship for the first time in a while.
Sungwan Kim, Kinesiology
Hometown: Gyeongju, Republic of Korea
WhyUConn?UConn was my one and only choice because the research topics of my Ph.D. advisor, Dr. Neal Glaviano, perfectly align with my interests. Additionally, the collaborative research culture at UConn offers a unique opportunity to work with leading experts and engage in interdisciplinary projects, further enhancing my professional development.
Why your major? I am completing my PhD in Exercise Science. Working clinically as a certified athletic trainer, I witnessed firsthand the significant impact that orthopedic conditions have on individuals’ lives. This experience motivated me to investigate how musculoskeletal injuries or pain affect physical and psychological well-being and to explore optimal treatment strategies for rehabilitation and recovery. After graduation, I will start my postdoctoral research fellowship at Boston Children’s Hospital and Harvard Medical School.
Top UConn memories? One thing everyone should do during their time at UConn is take advantage of the Recreation Center. Whether it’s lifting weights, playing sports, or just taking a break after a long day, it’s a great place to stay active and recharge!
Gramos Medjolli, Kinesiology
Hometown: Korça, Albania
WhyUConn? I had heard a lot of great things about UConn from a few people I knew, and I learned what an excellent institution it is. In fact, UConn was the only university I applied to—it was UConn or nothing! I thought to myself, if it’s meant to be, it will be. And it was! At the time, I was living in Germany and already practicing as a physical therapist.
Why your major? My grandpa always said, “The flowing water always stays fresh.” That’s why I decided to pursue the Doctor of Physical Therapy program at UConn, even after already being a licensed PT in Albania and Germany. I wanted to be the best version of myself in my profession because I love what I do. I truly believe physical therapy is one of the best jobs someone can have. If you’re not making someone else’s life better, then you’re wasting your time. I also want to advocate for the field of physical therapy and create things that will benefit the community.
Advice for incoming students? Don’t stress too much in advance. He who suffers before it’s necessary will suffer more than necessary. You won’t remember how many hours you studied, but you will remember the beautiful moments and adventures you experienced.
Yasmin Rosewell, Agricultural and Resource Economics
Hometown: Las Vegas, NV
WhyUConn? I chose UConn because of its diverse and upbeat environment. The student body is heavily involved in the sports teams, clubs, and educational opportunities the school has to offer.
Why your major? Economics of Sustainable Development and Management. I was drawn to this because I enjoyed the business aspects of the major, but the department was so involved in the students’ learning and offered great connections and opportunities to learn through different outlets. As an athlete, all of my professors within the department were extremely supportive and accommodating of my absences during the season, and that helped me succeed and learn the material without being overly stressed. After graduation, I plan to travel and then move to New York City and pursue a career in logistics.
Advice for incoming students? Everyone on this campus is truly rooting for each other. The sense of comradery is one of a kind and the students and staff of UConn are encouraging, inclusive, and collaborative. So be bold. Don’t be afraid to be amazing. There is a place here for everyone and you will find yours. There are always people behind you and in your corner.
Sydney Seldon, Natural Resources and the Environment
Hometown: Harker Heights, TX
WhyUConn? I originally came to UConn to play on one of the athletic teams here but when that didn’t work out, I was launched into a time of self-discovery, which unleashed a deeper purpose and passion for spiritual formation and sustainability (both social and environmental).
Why your major? My major is unique – Environmental Science and an Individualized Major in Sustainable Communities with a Minor in Sustainable Community Food Systems. After graduation, I’ll be joining staff with the Navigators, an international, interdenominational Christian ministry, and walking alongside students as they explore faith and spirituality.
Advice for incoming students? Be courageous. College brings with it a host of new experiences and opportunities to grow so surrender to it. Allow yourself to be challenged and molded into not only a committed learner, but also a committed individual. Allow your conceptions about the world and yourself to be challenged. Find people who gracefully love you and push you to be the best version of yourself, so that out of that, you can contribute to being a positive influence in the world around you.
Noah Sneed, Pathobiology and Veterinary Science, Animal Science
Hometown: Natick, MA
WhyUConn? I chose UConn because of the opportunities for hands-on learning, as well as their extensive commitment to academia and research as an R1 university.
Why your major? I came into college as an animal science major who was planning on going to veterinary school. I was drawn to it because I have always loved animals, and I was so excited to be able to get hands-on experience working with horses, pigs, sheep, chickens, and of course cows. I was drawn to pathobiology because I realized that further than just administering vaccinations, I was interested in how they worked and the process to make them. I was able to join a pathology research lab on campus, and it has been such an enriching experience. After graduation, I am taking two gap years before medical school. I will be working full time as an EMT in the Boston area, as well as completing a Post-Baccalaureate program at the Tufts Graduate School of Biomedical Sciences.
Advice for incoming students? Everyone should go to a men’s and women’s basketball game at Gampel Pavilion and sit in the student section. I have never felt so much pride for my school before; it is truly an amazing experience.
Mingda Sun, Nutritional Sciences
Hometown: Farmington, CT
WhyUConn? I chose UConn because I am from Connecticut, and did not want to go to school too far away from home. I also chose UConn because it has a strong nutrition and pre-medical program, which were areas of study I wanted to pursue. Moreover, UConn is a large school with students of many different backgrounds, and I felt like it was a place where I could belong and find a community of friends.
Why your major? I am a nutrition major with a minor in Spanish. I am passionate about how nutrition relates to health and the human body and have worked in numerous community health and public health initiatives as an undergraduate that are related to nutrition and disease prevention. Learning different languages is something I enjoy and believe is an important skill for connecting with patients and populations as a future health care professional. After graduation, I plan to attend medical school and become a doctor!
Advice for incoming students? Do not be afraid to reach out for support, mentorship, or guidance when you need it. If you have an idea or a passion that you want to pursue, there are faculty and students at UConn who are willing to help you. Don’t be afraid to take the initiative for your own learning!
Matt Syrotiak, Animal Science
Hometown: Bethlehem, CT
WhyUConn? I spent a great deal of time here at UConn through 4-H activities and high school FFA competitions. It’s safe to say that the Storrs campus was familiar to me from early on, despite my family having never been and never attending college themselves. While it was the campus and familiarity that drew me to UConn, it was the community of students, faculty, and staff that made me stay.
Why your major? My major is Animal Science, and I was drawn to it thanks to my involvement with the UConn Extension 4-H program where I worked on my dairy goat project. Through working with my goats, I gained a greater interest in the field, and it was reinforced by my time in agriscience classes throughout high school. UConn was the perfect fit to continue my work in animal science thanks to the proximity of the barns on campus and emphasis of hands-on class work. After graduation, I’ll serve as State 4-H Program Coordinator with UConn Extension, and create meaningful connections for 4-H youth, volunteers, and educators to increase the reach of the college and its community.
Advice for incoming students? The connections that you gain through being a part of the UConn community are critical to future success whether its classmates, educators, or alumni. You never know when those people will make a new appearance in your life.
Jonathan Vasquez Garcia, Nutritional Sciences
Hometown: Willimantic, CT
WhyUConn? Ever since I was little, I was always part of various programs associated with UConn, and when I came to campus, I felt that this school was my calling.
Why your major? I originally wanted to become a nurse. However, during my fall semester of sophomore year, I took my first nutrition class, where I gained valuable insight into the role of a registered dietitian. Ultimately, I changed my major to pursue a path aligned with my newfound passion for nutrition and sought out experiences that would deepen my understanding of the field. After graduation, I plan to pursue a master’s in clinical nutrition and complete my dietetic internship to become a registered dietitian. Eventually, I plan to work in a clinical setting to further gain foundational knowledge.
Advice for incoming students? My advice is to have fun and take advantage of all the resources UConn has to offer. And you should diversify your social network; you never know who you will meet.
Source: United Kingdom – Executive Government & Departments
Speech
Dame Angela McLean’s speech at the Royal Institution
This is a draft text of the speech ‘Discourse: The future of engineering biology’ delivered by Government Chief Scientific Adviser Professor Dame Angela McLean at The Royal Institution on 25 April 2025.
I want to start by asking you all to think about how you got here tonight.
I don’t mean in some philosophical sense; that kind of question is better left to other speakers. I mean literally: how did you make your way, here, to the Royal Institution?
If you’re anything like me, you relied on Google Maps to show you the way (although I may be obliged to say “Other providers are available”). Perhaps you also used your phone to pay for the bus or Tube.
If you’re joining us online – hello to you all! – you’ll be watching on a phone, tablet or laptop. So, one way or another, most of us made it here thanks to 1 of these devices.
Now I want you to think about the battery in your phone. Chances are it’s a lithium-ion battery. And if you came in an electric car or bus, you would also have depended on a lithium-ion battery.
The advantage of lithium-ion batteries compared to traditional alkaline batteries – the kind you may still put in the back of your TV remote – is that they can provide more energy and are rechargeable. People old enough to have depended entirely on alkaline batteries for many more devices besides the TV remote will remember the frustration when they ran out of power – and trying to cobble together another set of batteries to get them working again. Our phones may go dead, but it’s simple and convenient to recharge them.
But there is a downside, namely all the metals that go into making these modern batteries and electrical products, including lithium, cobalt and other rare earth elements.
Getting hold of these metals is hard. Most are currently extracted and purified from compounds in rocks, a process which can be very energy-intensive as well as very polluting.
Recycling and reusing these same metals is also hard.
This is the periodic table of the elements created by Dmitri Mendeleev, first published in 1869 and subsequently presented right here at the Royal Institution some 20 years later.
How many elements do you think are used in electronic products?
Electronic products can contain up to 60 different elements – around 52 of them metals (those are the elements highlighted in blue on the slide) – and we currently rely on inefficient and environmentally damaging methods to isolate and recycle individual metals.
Indeed, many electronic items cannot be recycled. They simply go to landfill. This is already a serious issue and it’s 1 that will only get worse as global demand for electronics increases.
Well, what if I told you that researchers here in the UK have identified naturally occurring bacteria, which have the ability to extract and recycle metals from this sort of waste?
Hats off to anyone in the audience familiar with the strain of bacteria called Shewanella oneidensis MR-1, which can remove manganese from lithium-ion batteries. Or the bacteria Desulfovibrio alaskensis, which is capable of precipitating cobalt out from a mixture of the different metals and chemicals in lithium-ion batteries.
I’m only aware of these bacteria thanks to amazing research taking place in the UK, including by Louise Horsfall’s group at the University of Edinburgh. Louise’s team have been collaborating with researchers from across the country as part of the ReLib project, which stands for the reuse and recycling of lithium-ion batteries.
Actually, 1 of the funders for this project is the Faraday Institution, the UK’s flagship battery research programme named for the great Michael Faraday whose desk is in front of me.
On his desk I have a few items to use to help explain battery recycling.
Louise’s team have primarily been focused on recycling metals from large lithium-ion batteries used in electric vehicles. However, they can be pretty large – too large for me to bring here tonight. Nevertheless, many of you will know what a lithium-ion battery looks like from your phone – and the science behind how we can recycle these batteries is no different.
Once lithium-ion batteries reach the end of their life they can be disassembled and shredded using mechanical methods to produce this. In this case, the shredded material has come from part of the battery called the cathode, which contains lots of the metals we want to recycle.
Once we’ve dissolved this shredded material using chemical or biological methods, we get this solution here… called metal leachate. This contains the useful metals we’re interested in and it’s at this point that we introduce the bacteria I mentioned earlier.
The bacteria collect and excrete specific metals as tiny nanoparticles which we can recover to give us something like this… which is manganese that Louise’s team has produced in the way I’ve just described from this exact process! We can then use this manganese to build new batteries or other devices.
You might be wondering what do we do with what’s left behind in the leachate solution. Well, after the bacteria have done their work we are left with this biobrine which is rich in lithium – and resembles what you might find in lithium deposits in South America. This too can be used to make new batteries.
And I’m not just talking about using a few types of microorganism to improve the extraction and recycling of 1 or 2 metals. There appear to be lots of different microbes out there capable of extracting different metals. Indeed, it’s possible that the bacteria have evolved this capability in a way that detoxifies their own environment, collecting up and excreting harmful metals and so not being poisoned.
So if we use combinations of these bacteria and we tweak the characteristics of these strains, we can increase the efficiency with which metals are purified and recycled from waste.
That word tweaking is important and it doesn’t do justice to the science involved. What we’re really talking about is engineering existing microbes to extract and recycle metals.
Extracting metals from the ground is a hugely expensive and damaging process. It looks rather like this:
What you can see on the bottom part of this slide is an open cast manganese mine.
And once we’re finished with products needing such metals, we throw them away. The top part of this slide shows a landfill site after a fire. There have been reports of lithium-ion batteries causing fires at landfill sites across the world.
With engineering biology, we only need to remove metals from the ground once; thereafter they can become part of a genuine circular economy through continual re-use.
We use physics, chemistry and engineering to get them out of the ground but then we can and should use biology and engineering to keep recycling them.
And this is just 1 example of what is within our grasp thanks to the power and potential of the scientific field called engineering biology.
I’m speaking about engineering biology this evening because I believe it could be the most significant branch of science for decades to come.
I want to explain why I think that’s the case – and to share my excitement about this field for 2 main reasons.
The first is that the science and engineering involved in this field is, frankly, beautiful.
The second – and more important – reason is that both current and future applications will make a huge difference to the everyday lives of people in the UK and across the world.
I’m here to try to convince you of both these things, but if I can convince you of only 1, I want it to be the latter.
I’m really keen for people to recognise that the scientists and engineers in this field are working to produce solutions that most, if not all, of us can agree are necessary… urgently necessary even.
To kick off, I ought to say that – as Government Chief Scientific Adviser – my role is to advise the Prime Minister and the Government on all matters related to science, technology and engineering.
The job – and the advice – is a mixture of proactive and reactive work. It covers everything from providing scientific and technical advice during a national emergency to explaining the risks and opportunities around emerging technologies like artificial intelligence and engineering biology.
Now, in getting to grips with the promise of engineering biology, I did have a little bit of a head start.
I am a mathematical biologist by background. My own research focused on using mathematical models to improve our understanding of the evolution and spread of infections like measles and HIV.
I don’t, however, have any background in engineering, nor in biochemistry. So I have had to get up to speed over the past few years.
At this point let me explain what engineering biology actually is.
Engineering biology involves applying engineering to biological processes in order to bend biology to our will.
In other words, it’s the practice of using ideas and tools taken from engineering to design and modify living organisms or biological systems.
Using tools and ideas developed over recent decades, the goal is to develop new materials and energy sources; to improve animal, plant and human health; to address environmental issues in new and sustainable ways.
What we’re talking about is the ability to harness and control biology predictably, repeatably and – I’ve said this already – usefully. Sometimes that will mean working with what’s already available in nature; at other times, it will involve genetic modification techniques.
Let me unpack some of this a bit further.
Firstly, on the engineering side. Here, I want to start with the design-build-test-learn cycle – DBTL for short.
This approach has been central to product development in engineering disciplines for some time. It drives continuous refinement and innovation, making research and development faster and more efficient.
In engineering biology, design-build-test-learn is brought to bear on biological processes – by which I mean the activities occurring within living organisms.
Image of the design-build-test-learn cycle. Each element is located in a different quarter and all 4 quarters make up a circle.
Essentially, I’m talking about designing something biological – like a version of a cell, or it could be a biological process (such as cell division) or a genetically-engineered system…
Then building it, maybe in the lab…
Then testing it to see how well it works…
Before finally, and perhaps most importantly, learning from what did and didn’t work and then feeding the lessons into another round of design, making improvements again and again around this cycle, towards an end goal.
This looks like being a more efficient way of recycling metals, to use the case study I gave at the start.
And why is this approach necessary? Well, because living organisms are highly complex, with many different parts and networks of interactions between those parts.
One could argue that physical or chemical systems are a bit more straightforward, more predictable, more easily quantifiable. We’ve been using this design-build-test-learn process to bend chemistry and physics to our will for more than a century – very successfully.
The complex and often unpredictable nature of biological systems means we need to work through multiple permutations to get to a desired outcome – and that’s where the engineering in engineering biology comes in.
If we can get this approach right – and I’m going to offer some further examples later showing where we already are – then we have the power to systematically develop biological systems to meet some of the biggest challenges we face.
Let me be more definitive. If the nineteenth century was chemistry’s golden age, and the twentieth century was the same thing for physics, I believe the twenty-first century should be the golden age for biology.
Why am I so optimistic?
This century can belong to biology because of a series of extraordinary advances in scientific understanding.
Where to begin? Of course, we have spent thousands of years modifying the living world.
But I’m not going to go all the way back to the domestication of wild crops. I’m not even going back to Darwin and Mendel.
Instead I’ll start with Watson, Crick and Wilkins – as well as the often overlooked Rosalind Franklin; 3 of the 4 received a Nobel Prize in 1962. By determining the structure of DNA, they discovered what we can call the language of biology.
Understanding the structure of DNA opened the door to reading this complex language, then editing it, then actually writing it ourselves.
Our ability to read DNA took a big step forward thanks to Walter Gilbert and Fred Sanger, who shared half of the 1980 Nobel Prize in Chemistry. Gilbert and Sanger did lots of work to understand the building blocks of DNA – the nucleotide alphabet of biology, if you like.
The next game-changer was in 1983 when an American biochemist, Kary Mullis, developed something called the Polymerase Chain Reaction. Better known as PCR, it is a laboratory technique that’s used to make copies of particular pieces of DNA. Think of it as a photocopier for DNA.
The technique lets scientists easily – and cheaply – create many millions of copies of DNA segments from very small original amounts – and that makes reading the DNA in a sample possible even if it is only there in tiny amounts.
You will all have become familiar with PCR during the Covid pandemic, when it was used to make many copies of the viral genetic material to allow reliable diagnosis of a Covid infection. That was the test where you did a swab, popped it in a test tube and then sent it away in the post. It was particularly important early on, before we had home testing kits.
The invention of PCR also earned a share of the 1993 Nobel Prize in Chemistry – that’s DNA Nobel number 3.
Fast forward 10 years to 2003 and the completion of the Human Genome Project. Researchers across the world spent some 13 years cataloguing the precise sequence of all the DNA in the cells of a human being. It was a huge effort and that first whole genome sequence of a human cost an estimated £2.5 billion.
Thankfully – but also remarkably – sequencing technology has come on leaps and bounds over the past 20 years. Now, it is possible to sequence the same amount of DNA analysed by the Human Genome Project in a single day – and for just a few hundred pounds! We’ve even developed pocket-sized machines which are capable of reading DNA in real-time.
In fact, I have 1 here: a portable sequencing device made by Oxford Nanopore. You simply add your sample into the middle here – this contains the sensor that will help to read the DNA sequence of your sample. Then simply close the lid and press go. And the results are delivered straight to your laptop via a USB-C cable which plugs into the end here.
This is useful for situations where we can’t send off a sample for analysis and wait days for the results – if, say, we’re urgently trying to identify the cause of an infection in some far-flung corner of the world.
So… we’ve learned to amplify DNA using PCR and we’ve learned to read DNA – fast – using rapid sequencing technologies.
We’ve also started learning – and do emphasise “started” – to accurately and precisely “edit” DNA.
Previously, when we wanted to do this, the methods were somewhat cruder – such as gene guns, which were used to literally fire DNA into cells.
We now have tools like CRISPR-Cas9 (another Nobel prize-winning technology developed by Emmanuelle Charpentier and Jennifer Doudna), and we can now take a targeted portion of DNA and change it very accurately in specific places. Some people have compared CRISPR to using a pair of genetic scissors.
Some of you might be wondering whether engineering biology is any different from another common term: synthetic biology. They are often applied interchangeably, although different countries interpret them in different ways.
The way I see it, synthetic biology refers to tools like CRISPR, used to design and build new biological components. Engineering biology is taking these tools – with or without genetic modification – and using the DBTL cycle to apply these tools at scale to find solutions to problems in the world around us.
There are still challenges with the accuracy of such tools, but the possibilities are vast.
We know that certain diseases are caused by mutations in a single gene. Sickle cell disease, for example, is caused by mutations in the beta-globin gene, resulting in red blood cells which are misshapen. As a result, these red cells don’t flow around the body as well as they should. This can cause those affected – roughly 17,500 people in the UK – to suffer from anaemia as well as complications like terrible pain and organ damage.
In the past, the only treatment was to rely on regular blood transfusions or a bone marrow transplant, neither of which comes without risks or complications. However, researchers have been using CRISPR to precisely edit the gene responsible for sickle cell with great success – so much so that, in January this year, the treatment was approved for use in the NHS as the world’s first gene-editing treatment for blood disorders.
And this is just 1 of many gene-editing clinical trials going on right now, including treatments for liver disease, heart disease and some cancers.
The possibilities are not confined to human diseases. We can use these genetic scissors to develop crops that are better at withstanding drought and more resistant to insects, so we don’t have to rely so much on pesticides.
And it’s these tools that are being used to modify the bacteria designed for metal recycling that I spoke about at the start.
Now, it would be remiss of me to talk about the tools of the future without mentioning AI and the transformative impacts it could have.
A prime example is the challenge of understanding and predicting how proteins fold up intricately and precisely in all of our cells. Decoding this process is something scientists have been trying to achieve for decades.
And in 2018, DeepMind came along with its AI model AlphaFold. AlphaFold has since been used to calculate the structure of hundreds of millions of proteins. And, yes, it earned the UK’s Demis Hassabis a share of last year’s Nobel prize in chemistry.
Timeline starting with images of James Watson, Francis Crick, Maurice Wilkins and Rosalind Franklin above the year 1962. Images of Walter Gilbert and Frederick Sanger are next to the year 1980. Image of Kary Mullis is next to the year 1993. Images of Emmanuelle Charpentier and Jennifer Doudna are below the year 2020 and an image of Demis Hassabis is below the year 2024.
All that’s missing on my timeline now is the capacity to design a new protein from scratch de novo. That will bring us into the realm of being able to write the language of biology – designing and printing a sequence of synthetic DNA to produce a protein with the properties that we want, from scratch.
I’ve just been talking about how technologies such as AI, and tools such as CRISPR, are helping to broaden the range of biological powers at our disposal and increase our ability to design and optimise biological systems.
And all this comes with valid concerns about risks. An example which springs to my mind was when scientists in Australia created a version of a mouse virus back in 2001 that instead of causing the normal mild symptoms, killed all of the mice within nine days. They were conducting some innocent genetic engineering research to try and make a mouse contraceptive vaccine for pest control and inadvertently found a way of creating a much more deadly version of the mousepox virus. Unsurprisingly, this made quite a splash in the media – although I think it was good that such a story was not buried.
The point I want to make is that we must develop the right practices and regulation so that we ensure that research is carried out safely and responsibly but we do not stifle innovation.
We refer to this as “responsible innovation” and it is 1 of the pillars of our government vision for engineering biology. That has given rise to new guidance on which genetic sequences people should be allowed to order for their research – welcome progress.
Having the UK take a lead in this kind of responsible innovation – where we are thinking carefully about the desired benefits of our research as well as about how to avoid negative impacts – lets us manage the risks and harness the wealth of opportunities that engineering biology can offer.
There are also other challenges to overcome. What’s standing in the way of us exploiting engineering biology for good? I won’t dwell for long on this, because you’re here to hear about science, not policy – but it is important to talk about the barriers.
We’ve already spoken about proper regulation for engineering biology. We also need to have proper ways of funding the basic research that drives this wonderful new technology and also the application of that research that lets us solve real-world problems. Then there’s also the task of making more people aware of the potential for progress here.
But a key area for me – and also a common issue across all areas of science and technology – is making sure we have the right skills in our future workforce to perform the future jobs that come with new technologies.
The skill set for engineering biology is particularly broad: the field is a combination many different skill-sets and mindsets. Mostly we train people either to become biologists or to become engineers, and for this technology we need people who can think with both those mindsets. So we need to think about a pipeline which starts in schools, with children getting the right grounding in key subjects – and children also hearing about the exciting careers they can pursue through developing and using the technologies I’ve talked about.
I think it’s vital that we don’t think exclusively about technical skills: communication skills are extremely important too. It’s a wonderful thing to do pioneering, cutting-edge research but we also need to be able to explain what that’s about and why people should want it.
So far, I’ve told you a bit about what engineering biology is and how we’ve got to this point, poised for biological century. I’ve also talked a bit about risks and challenges, but I think it’s now time to delve further into the applications that I think are so inspiring.
Today, I launched a report called “Engineering Biology Aspirations”. It’s our attempt to share our excitement about the possibilities that this technology opens up – and we want to share it with everyone, my colleagues inside government and also much more widely.
It contains case studies, written by UK-based experts, that illustrate some of the diverse problems we can address using engineering biology. Microbial metal extraction is 1 of them. I want to highlight some others during the rest of this talk – and to recognise some of the amazing research taking place in the UK.
One of the reasons that I commissioned the report is that all too often, when someone mentions engineering biology or synthetic biology, the examples will involve vaccines or medicines.
Of course those are fantastic, important applications: with the Covid pandemic such a fresh memory, we are all acutely aware of the life-saving importance of rapid and effective vaccine production. And I’m in awe of those researchers who can edit the gene that causes sickle cell disease.
But I want to make sure that we also shine a light on the true breadth of opportunities that engineering biology presents, not only in health, but across agriculture, materials, chemicals, energy, defence.
So, let’s shift gear and think about the fashion industry. Unlike metal recycling, it’s a sector familiar to all of us. We all buy and wear clothes, but we don’t often stop to think about where they’ve come from, how they’ve been made, and at what cost to the environment.
Putting aside issues around workforce conditions and waste, the fashion industry is 1 of the world’s largest polluters, responsible for up to 8 per cent of carbon emissions globally…
Not to mention the pollution generated in the form of clothing and textiles dumped in landfills, like this 1 in Bangladesh, never to biodegrade.
At the same time, 1/5 of the pollution of clean water around the world is caused by dyeing and treating textiles.
And there’s also growing awareness of the environmental damage caused by the microfibres shed by polyester clothing.
So it’s no surprise that plenty of researchers and companies here in the UK and beyond are seeking inspiration from biological processes to make new materials that don’t rely on fossil fuels or on animal products such as leather.
You may have been wondering why there are bottled drinks and a handbag beside each other on the Faraday desk. Well, they’re made of essentially the same material.
The process of making both items starts with microbes that naturally produce a material called nanocellulose.
In the case of Mogu Mogu – a coconut water drink you might find in your local supermarket – the nanocellulose is responsible for the lumps of jelly you can see in this bowl.
It is a polymer produced through fermentation – the same process used to make beer.
Now, 1 company I visited last year is called Modern Synthesis, based in South London and founded by Jen Keane and Ben Reeve. They’re aiming to develop scalable solutions to meet the fashion industry’s need for high-performing, versatile materials that don’t pollute the planet.
Modern Synthesis make nanocellulose fibres and then combine them with textiles such as cotton or linen to create new composites. These are then finished with natural coatings like waxes and oils to improve performance and to enhance look and feel, which are of course critical to customers. The result is this handbag!
Image of black, biologically derived material
And on the slide behind me, you can see in more detail the fibres that make up the handbag. These miniscule nanocellulose fibres are actually really, really strong – 8 times stronger than stainless steel relative to weight!
Modern Synthesis is just 1 example of a pioneering UK company making waves in this area. Another example is Solena Materials who are using AI to help design completely new materials from scratch, including fibres that are effective at absorbing energy. This makes them relevant for the military and the police, who need blast-, ballistic- and stab-proof clothing. As the ex-Chief Scientific Adviser for the Ministry of Defence, it’s great to see engineering biology applications offering benefits for defence.
Developing new materials like these can significantly reduce greenhouse gas emissions compared to traditional material production. This includes minimising the environmental impacts of raising livestock for leather or the energy-intensive processes involved in creating synthetic textiles such as polyesters and nylons. Better still, these materials can be designed for biodegradability, getting away from the big problem of plastic pollution.
Allow me to quote from our report for a second: “Imagine a world where every piece of your clothing has minimal cost to the environment, with zero waste going to landfills. Even if a piece of clothing is accidentally discarded into the environment, it safely biodegrades to leave no trace of its existence. This is the future of fashion, and engineering biology is helping to make it happen.”
Let me move now to another pervasive problem: inefficiencies in food production. Most of you will be aware that fertilisers are used by farmers across the world to supply nitrogen to their crops. Without fertilisers, yields suffer.
But there are 2 problems. First, the process for making nitrogen fertilisers is very energy-intensive. It’s responsible for between 1 and 2% of the entire world’s energy use – and generates matching CO2 emissions. Second, using fertilisers has considerable environmental impacts, releasing further greenhouse gas emissions and damaging waterways thanks to fertiliser runoff from fields.
This slide shows excessive algae growth – a common impact of fertiliser runoff – in the River Wantsum in Kent.
Currently, farmers across the world use more than 200 million tonnes of chemical fertilisers every year.
Diagram showing molecules of nitrogen and hydrogen converted into molecules of ammonia, with a chemical equilibrium sign betweem ammonia and molecules of nitrogen that combine with molecules of hydrogen
Now, this ability to produce nitrogen at scale – via the Haber-Bosch process – was without question the most important chemical breakthrough of the 20th century. The reaction that underpins this industrial process is shown behind me – converting nitrogen and hydrogen into ammonia, which is commonly used in fertilisers. It was discovered by Fritz Haber. Over half the global population depends for survival on foods fertilised using industrial production of nitrogen. But for the reasons I’ve outlined, we do need to do better.
So how can engineering biology help?
What if we could engineer cereals crops to absorb their own nitrogen from the environment, without relying on fertilisers? We call that “fixing” nitrogen.
There are actually examples of this happening in nature. There are bacteria in the soil called rhizobia which are particularly good at fixing nitrogen; in fact, they convert nitrogen gas from the atmosphere into ammonia – which is precisely the form of nitrogen that plants need. Legumes such as peas, clover and lupins attract these rhizobia bacteria to live in their roots – in small structures called nodules. In return for a steady supply of ammonia, the plant houses and feeds the bacteria, forming an ideal symbiotic relationship.
Behind me is an illustration of a plant with root nodules… but in classic Blue Peter style, here are a couple I grew earlier!
This clover plant from my lawn has nodules on its roots – but, because they are a bit tiny, I have also brought a photo of the same plant.
For these sort of plants, we can already coat their seeds with rhizobia and achieve increases in yields. And we can even go a step further by adding the bacteria directly to fields in a process called soil inoculation.
But the trouble with cereal crops like wheat, barley and maize is that they don’t have those root nodules and nor do they produce the special signalling chemicals that legumes use to attract bacteria.
Image showing a clover plant with roots that have small circular nodules on them in the bottom left-hand corner and a sweet-corn plant with roots without nodules in the top right-hand corner
Here is another plant that I’ve brought in from my garden. This 1 is sweet-corn, a variety of maize and a major cereal crop worldwide. You can see its roots here on the top part of the slide… no nodules! These kinds of crops do not set up this kind of symbiotic relationship with nitrogen-fixing bacteria.
So what researchers, like Phil Poole at the University of Oxford, are doing is trying to engineer a new generation of fertiliser-free crops, drawing on plant genetics, biochemistry and soil ecology.
One approach, given what I’ve just described, is to engineer cereals to form nodules on their roots that can host nitrogen-fixing bacteria.
The UK is leading the way on this – Oxford and Cambridge universities have major programmes backed by investment from our research councils and from the Gates Foundation. In fact, the teams involved work together as part of a larger collaboration, and have recently made some significant advances, engineering barley to form nodule-like structures and engineering barley roots to release the chemical signal rhizopine that prompts rhizobia to start fixing nitrogen.
The design-build-test-learn cycle I described earlier is a part of this research. All of the progress made so far has built on round after round of modifying, testing and redesigning organisms.
There are still many hurdles to overcome, both from a technical perspective and societally; genetic modification of crops is a very sensitive issue. But the value of the prize here is large, and I think scientists should not be shy about describing it.
Imagine a world where humanity’s main source of carbohydrates – cereal crops like wheat and barley – are able to generate their own nitrogen fertiliser.
We could tackle global food shortages on a much more sustainable basis and at the same solve 1 of the most urgent climate challenges, consigning industrially-produced nitrogen to the past.
Now, let’s just think about crops in a further context, because harvesting doesn’t have to be the end of their engineering biology journey!
At the start of this talk, I name-dropped a couple of bacterial strains in relation to metal recycling. Well the biologist in me can’t help but tell you another 1 – this time being a type of bacteria called Halomonas.
Researchers like Nigel Scrutton up at the University of Manchester, are engineering these bacteria to act as efficient factories for converting food waste into fuel via fermentation. When I say factories, I’m not talking about the massive industrial sites we would normally associate with fuel production.
This photo is of Fawley oil refinery in Hampshire.
Diagram showing drawings representing bacteria, food waste feedstock, a cylinder that produces fuel and container. The diagram shows that the result of feeding bacteria and food waste feedstock is fermentation that then produces fuel, which can be housed in a portable and scalable container
By contrast, these fuel-producing bacteria can be housed in different-sized containers like the ones on this slide – some of them not too dissimilar to shipping containers.
The beauty of this technology, therefore, is that it is inherently portable and scaleable to meet demand – with transformative implications for remote areas of the world where energy infrastructure can be scarce. And crucially, these are cleaner, fossil-free fuels that can be used to power homes, businesses, even aircraft.
Let’s focus on that last application for a second. At the moment, the aviation industry relies almost completely on kerosene-based fuels, which account for a staggering 3% of global CO2 emissions.
Burning fossil fuels is generally accepted as the main cause of global warming, so it is essential that we find ways to transition to sustainable sources of energy.
Engineering biology solutions like Nigel’s can therefore play a significant role in creating a future without fossil fuels. One of the benefits of using bacteria to turn waste into useful fuels is that this can create another circular economy in which we no longer need to extract and burn more and more harmful fossil fuels; instead we recycle the carbon we already have.
Personally, I think the environmental benefits are reason enough to get excited by this technology. But 1 of the great benefits of bacteria-fuel factories is how portable they are! In other words, they remove the need for large-scale bioreactor infrastructure.
Imagine a world where clean fuels could be produced locally and on demand – including in all those remote and sparsely populated regions which currently struggle to access the fuels they require.
Now, I argued just a moment ago that I want to convince people that engineering biology is about so much more than vaccines and medicines – and I hope that I’ve surprised at least some of you with the breadth of the examples I’ve described so far.
But I do have 1 example from medicine that is just too fascinating to leave out, and that’s research into laboratory-grown blood.
Why would we need such a product?
Currently, the world relies almost entirely on human blood donations to treat disease and for emergency medicine. In many countries, including the UK, donation rates fluctuate, and shortages can happen. On top of that, donated blood has a limited shelf life. It is challenging to store and challenging to distribute. When you consider the fact that some countries don’t have the infrastructure to deliver blood products safely, or think about conflict or humanitarian emergencies, the problems associated with donated blood become even clearer.
There are a few more issues too. It can be very difficult to source some rare blood types. And although blood services of course use screening to avoid known pathogens, there is always a risk of new ones arising, and being passed on to patients who receive blood transfusions.
For all these reasons, finding new ways to produce blood would be another game changer, and, once more engineering biology can help us.
Researchers, like Ash Toye at the University of Bristol, are exploring the possibility of banking unlimited supplies of red blood cells, either by transforming stem cells or genetically reprogramming donated precursor blood cells.
What you can see on the screen is a beautiful illustration by artist Claudia Stocker, which provides a visualisation of CRISPR – the “genetic scissors” technology I mentioned earlier – being used here to edit the genetic material of the precursor cells that will go on to become red blood cells.
The part of the image to focus on is the centre of the slide and specifically the spiral spools of DNA emanating from the big blue circle in the middle – the cell that will eventually give rise to the red blood cells around the outside of the slide. The little blue doughnuts represent the CRISPR technology in action, actively and precisely editing the DNA as we have instructed it to do.
This editing can enable us to produce precursor cells that can grow and divide indefinitely in a controlled environment, giving us unlimited blood supplies.
The Bristol team pioneering this research has been working closely with NHS Blood and Transplant and other partners in a ground-breaking clinical trial called RESTORE – RESTORE being the acronym for REcovery and survival of STem cell Originated REd cells.
It’s the first time in the world that red blood cells grown in a laboratory have been given to another person as part of a trial into blood transfusion – you might have seen media coverage of this programme, which has attracted interest from all over the world. The trial should produce further results by the end of this year or early next.
In the future, we could go a step further and use CRISPR to delete the genes responsible for blood groups, and – in doing so – create “universal” blood that would be invaluable in providing blood transfusions for individuals with rarer blood types.
Image of a table containing the combinations of blood types of a donor and a recipient that match each other and ones that do not. The matches are highlighted in purple and the mismatches in red
This slide is a brief reminder of the complexities around ensuring blood compatibility between donors and recipients. Only the combinations in purple are suitable.
The prospects here are again tantalising. Imagine a world where no patient dies due to a lack of compatible blood following an accident or during surgery. Where safe blood is available on demand, can be stored for longer and is free of disease transmission risks.
So there are all these amazing opportunities, which you can tell I love talking about!
We’ve covered a fair bit of ground about engineering biology: not just historically but geographically, in universities and companies, and across a range of applications.
I’m so proud that our country can lay claim to so much ingenuity. Microbial metal recycling from Edinburgh. Biosynthetic fuels from Manchester. Lab-grown blood from Bristol. Nitrogen-fixing cereals from Oxford. And nanocellulose-based materials from right here in London.
I want to end, though on a broader point concerning emerging technologies such as engineering biology and others besides.
Earlier, you heard me talk about risks and challenges, including the need for responsible innovation.
Another challenge – though – is about how we, as a society, talk about science and technology in general.
Clearly, 1 of my aims this evening has been to raise awareness of engineering biology.
But it strikes me that we’re living through a period where public engagement around science is getting harder.
That’s not just because of the unprecedented volumes of misinformation circulating around us.
We now live in a less paternalistic society – which is surely a good thing – it is no longer enough for scientists to tell people what’s good for them and expect them to toe the line. Instead, we know we need to have a proper, well-informed debate about these issues.
Clearly, it would be possible for the promise of engineering biology to be compromised by public opposition. We need to listen to public concerns – really listen! – and understand that if we don’t respond to those concerns people will be perfectly within their rights to not support, or actively block, the engineering biology advances that we’re trying to create.
There is a lot of work to do here. I don’t think we can ever be finished listening to the public.
Essentially, the technologies we’re developing in engineering biology need to offer solutions to problems that people actually care about.
Health, nutrition, climate, the environment, sustainability, global equity. I know that these are problems that billions of people care about.
I hope I’ve persuaded you that when it comes to these problems, engineering biology can provide solutions.
Image of the front cover of the ‘Engineering Biology Aspirations’ report on the left-hand side and a QR code to the webpage with the report on the right-hand side
Thank you for listening – do read our report; here it is – and thank you to the Royal Institution for asking me to speak in this 200th anniversary year for discourses.
Source: United Kingdom – Executive Government & Departments
Speech
Culture Secretary Lisa Nandy speech at Waves Summit 2025
The Culture Secretary’s speech at the World Audio Visual & Entertainment Summit in Mumbai on 1 May 2025
Excellencies, distinguished delegates, ladies and gentlemen, on behalf of the UK Government, I would like to extend our deepest condolences to the families who lost loved ones in the appalling attacks last week. Our Prime Minister, Sir Keir Starmer, has personally shared his sorrow with Prime Minister Modi. On behalf of the British people, the UK condemns all forms of terrorism and the extremism that sustains it, always.
The relationship between India and the UK is strong and deep, and it is personal for me. My father grew up in Kolkata, where my Indian family still live, and I’m deeply proud to be the first ever Labour cabinet minister of Indian heritage in the United Kingdom.
Our shared history is woven into the fabric of both our nations. The UK is an island that has been shaped by waves of immigration. They include the many children of Empire, like my father, who came to England in the 1950s to study and later lecture in English literature. It was a journey that would lead him to go on to profoundly change and shape modern Britain through the struggle for race relations and the creation of the landmark Race Relations Act.
And like so many Indians before him, Sophia Duleep Singh, who simultaneously fought for and advanced women’s rights in the UK and independence in India. And Jayaben Desai, a five foot tall Gujarati woman who led thousands of workers out on strike in London’s East End, uniting the Labour movement in a battle that would improve the status, pay and conditions of a generation of labourers. These are the men and women who have helped to shape our national story in the United Kingdom and to forge modern Britain, and they, in turn, paved the way and inspired others, in particular, a man who made history just a few short years ago when he became the first person of Indian heritage to serve as Prime Minister of the United Kingdom, Rishi Sunak.
It is this long and shared history, in all its light and dark and the deep rooted personal ties that sustain it, that gives me an unshakable belief in the power of what we two nations can achieve together. And stretching before us is both an historic opportunity and a challenge that our generation must rise to, to forge a future that is grounded in mutual respect, shared prosperity and a renewed commitment to one another. Together, we can be exemplars of how we transcend national borders and work together in our mutual interest. That is why I’m so delighted to be here with you today. And it is fitting that it is here in this great city, the home of storytelling, that we will write the next chapter of our shared story together.
Many of you here will know that there are nearly two million people of Indian descent living in the United Kingdom, and they are the living, breathing bridge between our two nations. And while Britain undoubtedly has shaped India, it is equally true that India has profoundly shaped Britain, bringing an energy, a resilience and a richness that has had an immeasurable impact on British society, culture and identity. From the biggest British band in history, the Beatles, to Great British films like ‘Bend It Like Beckham’, India has helped to define what it means to be British. We deeply value this rich contribution to our national life and to our culture.
From Charli XCX to Nikita Chauhan and Daytimers, the next generation is already powering ahead, creating a vibrant tapestry of diversity and collaboration. But it is our firm belief that we can do more. Our Labour government, led by the Prime Minister Sir Keir Starmer, is determined to strengthen our relationship with India across all sectors of our economy, and we were delighted that our Chancellor Rachel Reeves was able to recently announce over £400 million worth of new trade and investment partnerships with India. Our regional mayors like Tracy Brabin, the Mayor of West Yorkshire, prized the relationship with Indian business for the jobs and investment they bring to parts of the UK, like Bradford, home to a rich, vibrant diaspora community.
We are in the UK a self confident, outward looking country at the start of a decade of national renewal, and whether it’s literature, film, fashion or music, Britain, like India, excels. It’s our firm conviction that by deepening our cultural ties, we can grow together, prosper together, and light up the world. As we do already in sports, and we are so looking forward to strengthening the sporting ties between our nations in the coming years to promote great sporting events that are streamed all over the world. I’ve been pleased to see the cricketing bonds extended beyond the field with the recent Indian investment in the majority of teams in the UK’s Hundred competition. And I look forward to welcoming both India’s women’s, men’s and mixed disability teams to England this summer.
We look back fondly as a country to the moment when we hosted London 2012. It was an incredible showcase for the UK’s talent, and we share your excitement about India’s potential bid for the 2036 Olympics and Paralympic Games. So as we move ahead, let our story be like Jab We Met – built on connection, trust and the courage to walk together. And not like Lagaan, although we have many dramatic cricket matches still ahead of us.
The creative industries, film, gaming, fashion, literature, music, are booming in both of our countries. We have named the UK creative industries as one of the eight powerhouses that will drive Britain’s growth and prosperity. I was delighted to appoint Baroness Shriti Vadera, Chair of Prudential PLC and the Royal Shakespeare Company, to lead the development of the government’s creative industries growth strategy.
I’m committed to ensuring that the UK remains one of the world’s most open and supportive places for filmmakers and creatives. Our government is investing in skills, in film studios, in tax incentives, and as you can see from my presence here today, and that of the British Film Institute, in our international relationships, which we prize. We’re backing the creative industries right across the United Kingdom, just as here in India your government is backing your creative industries to the hilt.
Nobody could have listened to that opening speech from the Prime Minister and not understand that this is anything less than a personal signal of intent that he will leave no stone unturned in his mission to power up the untapped potential that exists in the already global success story of Indian film, literature and fashion, and we share that ambition, for you and for us. Now is the time to work together to put rocket boosters under our creative and cultural industries for growth, prosperity and power.
And whether it’s music, theatre, arts, culture, gaming or fashion, look what our partnerships can achieve. In fashion, the British Indian designer Harri is making waves in every corner of the globe thanks to his creativity and our backing. Our government proudly supports new talent through the new gen program led by the British Fashion Council. And in gaming, we have companies like Tara Gaming Limited creating impactful cultural digital partnerships from the UK to India. In the arts, Chila Burman is quite literally lighting up the world with her artwork, backed by the British Arts Council and great British institutions like the Tate, at whose Liverpool gallery she will shortly exhibit. The National Theatre, one of the UK’s greatest cultural institutions, now with artistic director Indhu Rubasingham, has launched a new programme, which includes a new adaptation of The Jungle Book with Anupama Chandrasekhar, and a retelling of Hamlet starring Hiran Abeysekera. And as only one of three countries in the world that is a net exporter of music, we are delighted that the vibrancy of the British music scene is being powered by artists like Ed Sheeran, A. R. Rahman and Diljit Dosanjh, whose collaborations have brought fans flocking to stadiums from Manchester to Mumbai.
Britain is also home, as you know, to unique British public service broadcasters like the BBC, who are a vital part of the UK’s creative economy, and they ensure that we have the skilled workforce, the facilities, the expertise, that every investor benefits from.
We’re one of the most attractive places to invest in and collaborate, not least because of our competitive tax reliefs, including a new credit we launched for independent film and visual effects, as well as the high quality studios and our skilled workforce across the whole of the UK, not just London. Last year, production spend in the UK increased by 31%, testament to our global reputation as a world leading centre for international film and TV production. But we also benefit from India’s media and entertainment sector, one of the largest and most dynamic in the entire world, whose scale, reach and creative energy are nothing short of phenomenal.
My ambition is for our cooperation to lead a cinematic revolution that has impacts far beyond the screen. Both the UK and India boast rich cinematic traditions and share a deep mutual interest in each other’s storytelling cultures. Like ‘Lioness’ created by Kajri Babbar, who was herself inspired by our very own Gurinder Chadha.
Films from India regularly account for around 30% of non-English language releases in the United Kingdom, and there is a new wave of Indian independent cinema telling fresh stories to the world, but made with the United Kingdom. Like ‘Defenders of Planet Earth’, a shining example of cross cultural partnership tackling the most important of shared challenges – the climate crisis – by UK-based Fingerprint Content and the India Cine Hub. I see enormous potential for greater collaboration between our two countries. While our successes in these sectors are driving growth in our economies, providing good quality jobs across every part of our countries, collaboration can take this to a whole new level.
Already we’re seeing success. British crews working on Indian sets, Indian directors bringing their vision to British audiences and streaming services that offer a bridge between our two cultures, across the creative industries in goods services and especially audio-visual services, India is one of our most important partners. Given the size of our markets and the scale and quality of our TV and film sectors, I know we can be more ambitious.
Twenty years ago, we signed the UK-India Film Co-Production Treaty to act as a foundation for partnership in the audio visual sectors. And I am delighted that later this week, my fellow minister for culture, Shri Gajendra Singh Shekhawat and I will agree and sign a bilateral Cultural Cooperation Agreement on behalf of our two great nations.
This agreement will bring together flagship UK and Indian cultural institutions, including the British Library, the Science Museum and the Victoria and Albert Museum, many of whom are with us here at WAVES this week. But we also have over 1,700 accredited museums across the UK, in places like Birmingham, Manchester and Leeds, with expertise in every subject you can name, with many potential partnerships available to our Indian counterparts.
Behind this treaty – what breathes life into this treaty – is the passion, the creativity and the human connections across our thriving creative industries and the power of friendship and collaboration between our nations. In this new era where at times, it feels we’ve lost the ability to understand one another across the world, let us use our strengths as the greatest storytellers in the world to bring nations together. Let’s empower the next generation of storytellers from Mumbai to Manchester, Kolkata to Cardiff, Bangalore to Belfast, Lucknow to Leicester and Delhi to Dundee, because in film, fashion, music and arts Britain and India lead the world and we can rise to this moment of a divided world together.
Together, we will light up the world. Our relationship evolves, but it will always endure. One of Britain’s most famous poets, William Wordsworth, once wrote: “So backwards, as I cast my eyes, I see what was, and is and will abide; Still glides the stream, and will forever glide; The Form remains, The Function never dies.”
I look to a future where the UK and India, two great creative nations, continue to dream, to collaborate and to inspire the world together, as one of my favorite poets, the great Rabindranath Tagore, says: “We will shoot joy through the dust of the earth old love, but in shapes That renew and renew forever.” Thank you very much.
The next World Health Organization (WHO) Traditional Medicine Global Summit, 2–4 December 2025, was unveiled during a keynote plenary session at the World Health Summit Regional Meeting 2025 in New Delhi, India, on 25 April. The session, organized by the WHO Global Traditional Medicine Centre, brought together government ministers, private sector directors, scientists and United Nations leaders to explore how combining ancient wisdom and modern science can expand access to safe, effective and people-centred Traditional Medicine (TM) and strengthen global health equity.
Stewards of a collective future
Delhi-based broadcaster Rini Simon Khanna opened the session, entitled: “ Restoring balance: Scaling up access to evidence-based traditional medicine for health and well-being”. She emphasized that the audience had gathered as “stewards of a collective future in health”, with TM serving as “a bridge connecting ancestral knowledge and modern science”. Prataprao Jadhav, India’s Minister of State for the Ministry of Ayush, addressed the gathering via pre-recorded video, stressing the need to integrate traditional knowledge with modern health systems in response to global challenges. The Minister took the opportunity to introduce the second WHO Traditional Medicine Global Summit, to be held in December 2025, and encouraged people to continue the dialogue at the Summit and “be a part of this shared journey towards global health harmony”.
An evolving global health system
Dr Rajesh Kotecha, Secretary and Vice-Minister, Ministry of Ayush, opened the panel discussion, telling participants, “TM is not just a thing of the past, it is a living, evolving component of many health systems around the globe”, offering relevance and promise in delivering affordable, accessible, people-centred care.
The first panellist, Drungtsho Dorji Gyeltshen, Traditional Medicine Physician at National Traditional Medicine Hospital, Bhutan, showcased how the country’s traditional system of health care, Sowa-Rigpa, is accessible to rural and hard-to-reach communities and offers trusted, free and culturally relevant care. Sowa-Rigpa plays a key role in Bhutan’s Gross National Happiness, which is aligned to four pillars: good governance, social and economic development, preservation and promotion of culture, and environmental conservation.
Global strategy for TM
Dr Saima Wazed, Regional Director for WHO South East Asia Regional Office, explained how the draft WHO Global Strategy for Traditional Medicine, 2025–2034 (scheduled for discussion at the Seventy-eighth World Health Assembly) will support WHO Member States in integrating TM into primary health care. She stressed the need to develop evidence-based programmes to reduce misinformation, for greater confidence in TM. She also highlighted the need for culturally reflective policies and regulatory bodies, communicated in understandable language.
The role of evidence
Aditya Burman, Non-Executive Director of Dabur India, emphasized the need to shift from anecdotal to evidence-based TM, just as biomedicine did. He added, “We hear anecdotal a little too much when it comes to TM, and we’d like to change that”. When discussing how to drive future growth in the TM sector, Mr Burman said, “It’s not about shouting louder [about the benefits of TM], it’s about allowing the other side to be receptive – building effective products and proving their effectiveness in a globally understood language”.
Professor Georg Seifert, a Senior Lecturer in Paediatrics at Charité – Universitätsmedizin Berlin, Germany, built on this point by explaining that more research is urgently needed, particularly on TM’s cost-effectiveness and sustainability. He also noted that integration of TM and biomedicine requires trust between those working in both systems, which grows from transparency about the strengths and limitations of TM. Professor Seifert also remarked on cross-cultural collaboration: “I can envisage a global network of integrative clinical centres that aid a diverse care model using rigorous but flexible methods, tailored to cultural and therapeutic contexts”, he said.
Voices of youth
Tanushree Jain, Chair of Public Health at the International Pharmaceutical Students’ Federation and member of the WHO Youth Council, discussed the generational shift in young people’s attitudes towards wellness, which includes preventive practices that incorporate ethics and sustainability. She highlighted that young people want to see TM validated through science and integrated safely in modern care. “When traditional knowledge is adapted with rigour and relevance, it earns our trust”, she stated.
Digital tools like mobile health apps and fitness trackers are making traditional practices more accessible to youth and driving behaviour change. When these tools are engaging, educational, inclusive and sustainable, they empower young people to integrate personalized holistic care into their daily lives.
Bridging the gap between science and policy
Dr Soumya Swaminathan, former Chief Scientist at WHO and Chair of MS Swaminathan Research Foundation, stated, “No system of medicine has the answer to everything, and this is why we need to think about integrative medicine”. She stressed that there are currently different terms and diagnostic systems in use by traditional healers and allopathic doctors. She explained that to bridge the gap between science and policy, culturally significant practices need to be evaluated and integrated using robust, context-sensitive scientific methods, with a common language and vocabulary. Dr Swaminathan also highlighted the importance of harnessing the opportunities presented by modern tools, such as AI for diagnostics, through a multidisciplinary approach.
The future of TM
Dr Rajesh Kotecha asked each of the panellists one final question: “Looking ahead to the next five years, what is the one thing that is needed most for TM to advance the health and well-being of all?”
Drungtsho Dorji Gyeltshen said that establishing Bhutan as a centre of excellence, and focusing on sustainable and innovative practices will preserve and promote Sowa-Rigpa, ensuring it remains relevant, accessible and contributes to global health;
DrSaima Wazed emphasized bringing data and knowledge together from global TM practices in a standardized format, so they can be shared on a global platform;
Aditya Burman noted that it is important to ensure TM becomes part of the mainstream vocabulary, suggesting inclusion on medical TV shows and films, to show that TM is not a niche “out there” idea;
Professor Georg Seifert said that he sees big potential in preventive medicine and integrated health care models, but strong evidence and good business models are needed to show cost-effectiveness;
Tanushree Jain highlighted establishing evidence in scientific research and using that to build trust in TM;
Dr Soumya Swaminathan stressed that this is the time to come together to bring the disciplines together, to not fight over which one is better, but to develop the science and communicate it effectively to people, for the best person-centred care.
The session concluded with a question-and-answer session with the audience. One participant said that, as an editor at The Lancet medical journal, they noted a lack of submissions and publications on TM. They highlighted the need to bring TM to the global stage, through high-quality journal articles and clinical trials, for people to have trust. The panellists suggested some challenges, such as language or cultural understanding, as well as constructive feedback, such as the need for greater outreach or funding programmes. Dr Swaminathan added that there is also an evidence feedback loop – if the right research has not been published in the literature, then it is difficult to validate findings, as per publication policies, and suggested journals like The Lancet help create publishing opportunities for TM research.
Restoring balance
In his closing video address, Dr Tedros Adhanom Ghebreyesus, WHO Director-General, reminded the audience that TM is as old as humanity itself and that for hundreds of millions of people, TM is just medicine. Through GTMC, WHO is supporting research to harness the power of these ancient practices.
Moderator Rini Simon Khanna remarked that this is “not the conclusion of our conversation but the beginning of a shared journey”, which is as much about restoring balance within ourselves, our communities, the health system and our relationship with the natural world. That journey continues at the second WHO Global Traditional Medicine Summit in December. The summit video was unveiled, which sets out how the next Summit will help unlock the full potential of TM. The Summit offers not just a space for dialogue, but a call to action to explore how the nexus of TM and modern science can restore balance and well-being for people and our planet. Ms Khanna closed, “Restoring balance is not just a policy goal, it is a personal and planetary commitment.
BROOKFIELD, News, May 02, 2025 (GLOBE NEWSWIRE) — Brookfield Business Partners (NYSE: BBU, BBUC; TSX: BBU.UN, BBUC) announced today financial results for the quarter ended March 31, 2025.
“We had an active start to the year, generating over $1.5 billion from our capital recycling initiatives, progressing the acquisition of two market-leading industrial operations and investing approximately $140 million to repurchase our units and shares,” said Anuj Ranjan, CEO of Brookfield Business Partners. “During periods of uncertainty and volatility, our consistent strategy of owning market leading businesses and executing on our operational improvement plans is more important than ever. With the enhanced strength of our balance sheet, we are well positioned to support our capital allocation priorities and continue compounding long-term value for our investors.”
Three Months Ended March 31,
US$ millions (except per unit amounts), unaudited
2025
2024
Net income (loss) attributable to Unitholders1
$
80
$
48
Net income (loss) per limited partnership unit2
$
0.38
$
0.23
Adjusted EBITDA3
$
591
$
544
Net income attributable to Unitholders for the three months ended March 31, 2025 was $80 million ($0.38 per limited partnership unit) compared to net income of $48 million ($0.23 per limited partnership unit) in the prior period.
Adjusted EBITDA for the three months ended March 31, 2025 was $591 million compared to $544 million in the prior period. Current period results included contribution from the recent acquisition of our electric heat tracing systems manufacturer in January 2025. Prior period results included $37 million of contribution from disposed operations including our offshore oil services’ shuttle tanker operation which was sold in January 2025.
Operational Update
The following table presents Adjusted EBITDA by segment:
Three Months Ended March 31,
US$ millions, unaudited
2025
2024
Industrials
$
304
$
228
Business Services
213
205
Infrastructure Services
104
143
Corporate and Other
(30
)
(32
)
Adjusted EBITDA
$
591
$
544
Our Industrials segment generated Adjusted EBITDA of $304 million for the three months ended March 31, 2025, compared to $228 million during the same period in 2024. Current period results included $72 million of tax benefits at our advanced energy storage operation and contribution from our electric heat tracing manufacturer which was acquired in January 2025.
Our Business Services segment generated Adjusted EBITDA of $213 million for the three months ended March 31, 2025, compared to $205 million during the same period in 2024. Strong performance at our residential mortgage insurer and increased contribution from our construction operation was partially offset by the impact of higher costs associated with technology upgrades at dealer software and technology services. Prior period results included contribution from our road fuels operation which was sold in July 2024.
Our Infrastructure Services segment generated Adjusted EBITDA of $104 million for the three months ended March 31, 2025, compared to $143 million during the same period in 2024. Prior period results included contribution from our offshore oil services’ shuttle tanker operation which was sold in January 2025.
The following table presents Adjusted EFO4 by segment:
Three Months Ended March 31,
US$ millions, unaudited
2025
2024
Adjusted EFO
Industrials
$
130
$
180
Business Services
117
168
Infrastructure Services
166
72
Corporate and Other
(68
)
(89
)
Adjusted EFO in the current period included a $114 million of net gain related to the disposition of the shuttle tanker operation at our offshore oil services. Industrials Adjusted EFO included the impact of withholding taxes on a distribution received from our advanced energy storage operation during the quarter. Adjusted EFO in the prior period included $62 million of net gains primarily related to the sale of public securities and $50 million of other income related to a distribution at our entertainment operation.
Strategic Initiatives
Specialty Equipment Manufacturer In February, we agreed to acquire Antylia Scientific, a leading manufacturer and distributor of critical consumables and testing equipment serving life sciences and environmental labs for approximately $1.3 billion. Brookfield Business Partners expects to invest approximately $160 million for an approximate 25% economic interest. The transaction is expected to close in the second quarter, subject to customary closing conditions and regulatory approvals.
Unit Repurchase Program During the quarter and subsequent to quarter end, we invested approximately $140 million to repurchase 5.9 million5 units and shares of Brookfield Business Partners at an average price of approximately $24 per unit and share. The repurchases were completed under our normal course issuer bid (NCIB) which we plan to renew once it expires in August this year.
Liquidity
We ended the quarter with approximately $2.4 billion of liquidity at the corporate level including $59 million of cash and liquid securities, $25 million of remaining preferred equity commitment from Brookfield Corporation and approximately $2.3 billion of availability on our corporate credit facilities. Pro forma for announced and recently closed transactions, corporate liquidity is $2.3 billion.
Distribution
The Board of Directors has declared a quarterly distribution in the amount of $0.0625 per unit, payable on June 30, 2025 to unitholders of record as at the close of business on May 30, 2025.
Additional Information
The Board has reviewed and approved this news release, including the summarized unaudited interim consolidated financial statements contained herein.
Brookfield Business Partners’ Letter to Unitholders and the Supplemental Information are available on our website https://bbu.brookfield.com under Reports & Filings.
Notes:
Attributable to limited partnership unitholders, general partnership unitholders, redemption-exchange unitholders, special limited partnership unitholders and BBUC exchangeable shareholders.
Net income (loss) per limited partnership unit calculated as net income (loss) attributable to limited partners divided by the average number of limited partnership units outstanding for thethreemonths endedMarch 31, 2025which was80.0 million(March 31, 2024:74.3 million).
Adjusted EBITDA is a non-IFRS measure of operating performance presented as net income and equity accounted income at the partnership’s economic ownership interest in consolidated subsidiaries and equity accounted investments, respectively, excluding the impact of interest income (expense), net, income taxes, depreciation and amortization expense, gains (losses) on acquisitions/dispositions, net, transaction costs, restructuring charges, revaluation gains or losses, impairment expenses or reversals, other income or expenses, and preferred equity distributions. The partnership’s economic ownership interest in consolidated subsidiaries and equity accounted investments excludes amounts attributable to non-controlling interests consistent with how the partnership determines net income attributable to non-controlling interests in its unaudited interim condensed consolidated statements of operating results. The partnership believes that Adjusted EBITDA provides a comprehensive understanding of the ability of its businesses to generate recurring earnings which allows users to better understand and evaluate the underlying financial performance of the partnership’s operations and excludes items that the partnership believes do not directly relate to revenue earning activities and are not normal, recurring items necessary for business operations. Please refer to the reconciliation of net income (loss) to Adjusted EBITDA included in this news release.
Adjusted EFO is the partnership’s segment measure of profit or loss and is presented as net income and equity accounted income at the partnership’s economic ownership interest in consolidated subsidiaries and equity accounted investments, respectively, excluding the impact of depreciation and amortization expense, deferred income taxes, transaction costs, restructuring charges, unrealized revaluation gains or losses, impairment expenses or reversals and other income or expense items that are not directly related to revenue generating activities. The partnership’s economic ownership interest in consolidated subsidiaries excludes amounts attributable to non-controlling interests consistent with how the partnership determines net income attributable to non-controlling interests in its unaudited interim condensed consolidated statements of operating results. In order to provide additional insight regarding the partnership’s operating performance over the lifecycle of an investment, Adjusted EFO includes the impact of preferred equity distributions and realized disposition gains or losses recorded in net income, other comprehensive income, or directly in equity, such as ownership changes. Adjusted EFO does not include legal and other provisions that may occur from time to time in the partnership’s operations and that are one-time or non-recurring and not directly tied to the partnership’s operations, such as those for litigation or contingencies. Adjusted EFO includes expected credit losses and bad debt allowances recorded in the normal course of the partnership’s operations. Adjusted EFO allows the partnership to evaluate its segments on the basis of return on invested capital generated by its operations and allows the partnership to evaluate the performance of its segments on a levered basis.
Inclusive of all limited partnership units and BBUC exchangeable shares repurchased under our NCIB during the three months ended March 31, 2025 and up to market close on May 1, 2025, based on settlement date.
Brookfield Business Partners is a global business services and industrials company focused on owning and operating high-quality businesses that provide essential products and services and benefit from a strong competitive position. Investors have flexibility to invest in our company either through Brookfield Business Partners L.P. (NYSE: BBU; TSX: BBU.UN), a limited partnership or Brookfield Business Corporation (NYSE, TSX: BBUC), a corporation. For more information, please visit https://bbu.brookfield.com.
Brookfield Business Partners is the flagship listed vehicle of Brookfield Asset Management’s Private Equity Group. Brookfield Asset Management is a leading global alternative asset manager with over $1 trillion of assets under management.
Please note that Brookfield Business Partners’ previous audited annual and unaudited quarterly reports have been filed on SEDAR+ and EDGAR, and are available at https://bbu.brookfield.com under Reports & Filings. Hard copies of the annual and quarterly reports can be obtained free of charge upon request.
For more information, please contact:
Media: Marie Fuller Tel: +44 207 408 8375 Email: marie.fuller@brookfield.com
Investors: Alan Fleming Tel: +1 (416) 645-2736 Email: alan.fleming@brookfield.com
Conference Call and Quarterly Earnings Webcast Details
Investors, analysts and other interested parties can access Brookfield Business Partners’ first quarter 2025 results as well as the Letter to Unitholders and Supplemental Information on our website https://bbu.brookfield.com under Reports & Filings.
The results call can be accessed via webcast on May 2, 2025 at 10:00 a.m. Eastern Time at BBU2025Q1Webcast or participants can preregister at BBU2025Q1ConferenceCall. Upon registering, participants will be emailed a dial-in number and unique PIN. A replay of the webcast will be available at https://bbu.brookfield.com.
Brookfield Business Partners L.P. Consolidated Statements of Financial Position
As at
US$ millions, unaudited
March 31, 2025
December 31, 2024
Assets
Cash and cash equivalents
$
3,442
$
3,239
Financial assets
11,642
12,371
Accounts and other receivable, net
6,948
6,279
Inventory and other assets
5,063
5,728
Property, plant and equipment
12,529
13,232
Deferred income tax assets
1,767
1,744
Intangible assets
19,157
18,317
Equity accounted investments
2,307
2,325
Goodwill
13,032
12,239
Total Assets
$
75,887
$
75,474
Liabilities and Equity
Liabilities
Corporate borrowings
$
1,017
$
2,142
Accounts payable and other
15,085
16,691
Non-recourse borrowings in subsidiaries of the partnership
42,316
36,720
Deferred income tax liabilities
2,614
2,613
Equity
Limited partners
$
2,158
$
1,752
Non-controlling interests attributable to:
Redemption-exchange units
1,246
1,644
Special limited partner
—
—
BBUC exchangeable shares
1,732
1,721
Preferred securities
740
740
Interest of others in operating subsidiaries
8,979
11,451
14,855
17,308
Total Liabilities and Equity
$
75,887
$
75,474
Brookfield Business Partners L.P. Consolidated Statements of Operating Results
Three Months Ended March 31,
US$ millions, unaudited
2025
2024
Revenues
$
6,749
$
12,015
Direct operating costs
(5,402
)
(10,878
)
General and administrative expenses
(311
)
(317
)
Interest income (expense), net
(770
)
(796
)
Equity accounted income (loss)
(8
)
23
Impairment reversal (expense), net
—
10
Gain (loss) on acquisitions/dispositions, net
214
15
Other income (expense), net
(83
)
116
Income (loss) before income tax
389
188
Income tax (expense) recovery
Current
(197
)
(90
)
Deferred
64
105
Net income (loss)
$
256
$
203
Attributable to:
Limited partners
$
30
$
17
Non-controlling interests attributable to:
Redemption-exchange units
23
15
Special limited partner
—
—
BBUC exchangeable shares
27
16
Preferred securities
13
13
Interest of others in operating subsidiaries
163
142
Brookfield Business Partners L.P. Reconciliation of Non-IFRS Measure
Three Months Ended March 31, 2025
US$ millions, unaudited
Business Services
Infrastructure Services
Industrials
Corporate and Other
Total
Net income (loss)
$
—
$
156
$
145
$
(45
)
$
256
Add or subtract the following:
Depreciation and amortization expense
222
165
343
—
730
Gain (loss) on acquisitions/dispositions, net
—
(214
)
—
—
(214
)
Other income (expense), net1
68
(79
)
93
1
83
Income tax (expense) recovery
18
25
101
(11
)
133
Equity accounted income (loss)
(3
)
26
(15
)
—
8
Interest income (expense), net
230
149
366
25
770
Equity accounted Adjusted EBITDA2
24
33
15
—
72
Amounts attributable to non-controlling interests3
(346
)
(157
)
(744
)
—
(1,247
)
Adjusted EBITDA
$
213
$
104
$
304
$
(30
)
$
591
Notes:
Other income (expense), net corresponds to amounts that are not directly related to revenue earning activities and are not normal, recurring income or expenses necessary for business operations. The components of other income (expense), net include$125 million of gains recorded at our offshore oil services due to vessel upgrades and unrealized gains recorded on reclassification of property, plant and equipment to finance leases, $78 million of business separation expenses, stand-up costs and restructuring charges, $50 million of net revaluation losses, $35 million of transaction costs and $45 million of other expenses.
Equity accounted Adjusted EBITDA corresponds to the Adjusted EBITDA attributable to the partnership that is generated by its investments in associates and joint ventures accounted for using the equity method.
Amounts attributable to non-controlling interests are calculated based on the economic ownership interests held by the non-controlling interests in consolidated subsidiaries.
Brookfield Business Partners L.P. Reconciliation of Non-IFRS Measure
Three Months Ended March 31, 2024
US$ millions, unaudited
Business Services
Infrastructure Services
Industrials
Corporate and Other
Total
Net income (loss)
$
240
$
(65
)
$
98
$
(70
)
$
203
Add back or deduct the following:
Depreciation and amortization expense
254
212
342
—
808
Impairment reversal (expense), net
(4
)
(12
)
6
—
(10
)
Gain (loss) on acquisitions/dispositions, net
(15
)
—
—
—
(15
)
Other income (expense), net1
(140
)
(18
)
32
10
(116
)
Income tax expense (recovery)
24
(3
)
(27
)
(9
)
(15
)
Equity accounted income (loss)
(1
)
(4
)
(18
)
—
(23
)
Interest income (expense), net
252
180
327
37
796
Equity accounted Adjusted EBITDA2
17
39
16
—
72
Amounts attributable to non-controlling interests3
(422
)
(186
)
(548
)
—
(1,156
)
Adjusted EBITDA
$
205
$
143
$
228
$
(32
)
$
544
Notes:
Other income (expense), net corresponds to amounts that are not directly related to revenue earning activities and are not normal, recurring income or expenses necessary for business operations. The components of other income (expense), net include$158 millionof net revaluation gains,$50 millionof other income related to a distribution at our entertainment operation,$21 millionof transaction costs,$19 millionof business separation expenses, stand-up costs and restructuring charges and$52 millionof otherexpenses.
Equity accounted Adjusted EBITDA corresponds to the Adjusted EBITDA attributable to the partnership that is generated by our investments in associates and joint ventures accounted for using the equity method.
Amounts attributable to non-controlling interests are calculated based on the economic ownership interests held by the non-controlling interests in consolidated subsidiaries.
Brookfield Business Corporation Reports First Quarter 2025 Results
BROOKFIELD, News, May 2, 2025 – Brookfield Business Corporation (NYSE, TSX: BBUC) announced today its net income (loss) for the quarter ended March 31, 2025.
Three Months Ended March 31,
US$ millions, unaudited
2025
2024
Net income (loss) attributable to Brookfield Business Partners
$
(58
)
$
(150
)
Net loss attributable to Brookfield Business Partners for the three months ended March 31, 2025 was $58 million compared to net loss of $150 million during the same period in 2024. Current period results included $7 million of remeasurement loss on our exchangeable and class B shares that are classified as liabilities under IFRS. As at March 31, 2025, the exchangeable and class B shares were remeasured to reflect the closing price of $23.46 per unit.
Dividend
The Board of Directors has declared a quarterly dividend in the amount of $0.0625 per share, payable on June 30, 2025 to shareholders of record as at the close of business on May 30, 2025.
Additional Information
Each exchangeable share of Brookfield Business Corporation has been structured with the intention of providing an economic return equivalent to one unit of Brookfield Business Partners L.P. Each exchangeable share will be exchangeable at the option of the holder for one unit. Brookfield Business Corporation will target that dividends on its exchangeable shares be declared and paid at the same time as distributions are declared and paid on the Brookfield Business Partners’ units and that dividends on each exchangeable share will be declared and paid in the same amount as distributions are declared and paid on each unit to provide holders of exchangeable shares with an economic return equivalent to holders of units.
In addition to carefully considering the disclosures made in this news release in its entirety, shareholders are strongly encouraged to carefully review the Letter to Unitholders, Supplemental Information and other continuous disclosure filings which are available at https://bbu.brookfield.com.
Please note that Brookfield Business Corporation’s previous audited annual and unaudited quarterly reports have been filed on SEDAR+ and EDGAR and are available at https://bbu.brookfield.com/bbuc under Reports & Filings. Hard copies of the annual and quarterly reports can be obtained free of charge upon request.
Brookfield Business Corporation Consolidated Statements of Financial Position
As at
US$ millions, unaudited
March 31, 2025
December 31, 2024
Assets
Cash and cash equivalents
$
968
$
1,008
Financial assets
324
353
Accounts and other receivable, net
3,397
3,229
Inventory, net
59
52
Other assets
641
627
Property, plant and equipment
2,479
2,480
Deferred income tax assets
206
197
Intangible assets
6,031
5,966
Equity accounted investments
201
198
Goodwill
4,993
4,988
Total Assets
$
19,299
$
19,098
Liabilities and Equity
Liabilities
Accounts payable and other
$
5,371
$
5,276
Non-recourse borrowings in subsidiaries of the company
8,711
8,490
Exchangeable and class B shares
1,682
1,709
Deferred income tax liabilities
951
988
Equity
Brookfield Business Partners
$
(78
)
$
(59
)
Non-controlling interests
2,662
2,694
2,584
2,635
Total Liabilities and Equity
$
19,299
$
19,098
Brookfield Business Corporation Consolidated Statements of Operating Results
Three Months Ended March 31,
US$ millions, unaudited
2025
2024
Revenues
$
1,966
$
1,865
Direct operating costs
(1,789
)
(1,652
)
General and administrative expenses
(75
)
(64
)
Interest income (expense), net
(219
)
(210
)
Equity accounted income (loss)
3
1
Impairment reversal (expense), net
—
(2
)
Remeasurement of exchangeable and class B shares
(7
)
(111
)
Other income (expense), net
(34
)
(11
)
Income (loss) before income tax
(155
)
(184
)
Income tax (expense) recovery
Current
(23
)
(44
)
Deferred
43
54
Net income (loss)
$
(135
)
$
(174
)
Attributable to:
Brookfield Business Partners
$
(58
)
$
(150
)
Non-controlling interests
(77
)
(24
)
Cautionary Statement Regarding Forward-looking Statements and Information
Note: This news release contains “forward-looking information” within the meaning of Canadian provincial securities laws and “forward-looking statements” within the meaning of applicable Canadian and U.S. securities laws. Forward-looking statements include statements that are predictive in nature, depend upon or refer to future events or conditions, include statements regarding the operations, business, financial condition, expected financial results, performance, prospects, opportunities, priorities, targets, goals, ongoing objectives, strategies and outlook of Brookfield Business Partners, as well as regarding recently completed and proposed acquisitions, dispositions, and other transactions, and the outlook for North American and international economies for the current fiscal year and subsequent periods, and include words such as “expects”, “anticipates”, “plans”, “believes”, “estimates”, “seeks”, “intends”, “targets”, “projects”, “forecasts”, “views”, “potential”, “likely” or negative versions thereof and other similar expressions, or future or conditional verbs such as “may”, “will”, “should”, “would” and “could”.
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References to Brookfield Business Partners are to Brookfield Business Partners L.P. together with its subsidiaries, controlled affiliates and operating entities. Unitholders’ results include limited partnership units, redemption-exchange units, general partnership units, BBUC exchangeable shares and special limited partnership units. More detailed information on certain references made in this news release will be available in our Management’s Discussion and Analysis of Financial Condition and Results of Operations in our interim report for the first quarter ended March 31, 2025 furnished on Form 6-K.
After weeks of preparation, the space observatory has begun its science mission, taking about 3,600 unique images per day to create a map of the cosmos like no other. Launched on March 11, NASA’s SPHEREx space observatory has spent the last six weeks undergoing checkouts, calibrations, and other activities to ensure it is working as it should. Now it’s mapping the entire sky — not just a large part of it — to chart the positions of hundreds of millions of galaxies in 3D to answer some big questions about the universe. On May 1, the spacecraft began regular science operations, which consist of taking about 3,600 images per day for the next two years to provide new insights about the origins of the universe, galaxies, and the ingredients for life in the Milky Way.
[embedded content] This video shows SPHEREx’s field of view as it scans across one section of sky inside the Large Magellanic Cloud, with rainbow colors representing the infrared wavelengths the telescope’s detectors see. The view from one detector array moves from purple to green, followed by the second array’s view, which changes from yellow to red. The images are looped four times. NASA/JPL-Caltech
“Thanks to the hard work of teams across NASA, industry, and academia that built this mission, SPHEREx is operating just as we’d expected and will produce maps of the full sky unlike any we’ve had before,” said Shawn Domagal-Goldman, acting director of the Astrophysics Division at NASA Headquarters in Washington. “This new observatory is adding to the suite of space-based astrophysics survey missions leading up to the launch of NASA’s Nancy Grace Roman Space Telescope. Together with these other missions, SPHEREx will play a key role in answering the big questions about the universe we tackle at NASA every day.” From its perch in Earth orbit, SPHEREx peers into the darkness, pointing away from the planet and the Sun. The observatory will complete more than 11,000 orbits over its 25 months of planned survey operations, circling Earth about 14½ times a day. It orbits Earth from north to south, passing over the poles, and each day it takes images along one circular strip of the sky. As the days pass and the planet moves around the Sun, SPHEREx’s field of view shifts as well so that after six months, the observatory will have looked out into space in every direction. When SPHEREx takes a picture of the sky, the light is sent to six detectors that each produces a unique image capturing different wavelengths of light. These groups of six images are called an exposure, and SPHEREx takes about 600 exposures per day. When it’s done with one exposure, the whole observatory shifts position — the mirrors and detectors don’t move as they do on some other telescopes. Rather than using thrusters, SPHEREx relies on a system of reaction wheels, which spin inside the spacecraft to control its orientation. Hundreds of thousands of SPHEREx’s images will be digitally woven together to create four all-sky maps in two years. By mapping the entire sky, the mission will provide new insights about what happened in the first fraction of a second after the big bang. In that brief instant, an event called cosmic inflation caused the universe to expand a trillion-trillionfold. “We’re going to study what happened on the smallest size scales in the universe’s earliest moments by looking at the modern universe on the largest scales,” said Jim Fanson, the mission’s project manager at NASA’s Jet Propulsion Laboratory in Southern California. “I think there’s a poetic arc to that.” Cosmic inflation subtly influenced the distribution of matter in the universe, and clues about how such an event could happen are written into the positions of galaxies across the universe. When cosmic inflation began, the universe was smaller than the size of an atom, but the properties of that early universe were stretched out and influence what we see today. No other known event or process involves the amount of energy that would have been required to drive cosmic inflation, so studying it presents a unique opportunity to understand more deeply how our universe works. “Some of us have been working toward this goal for 12 years,” said Jamie Bock, the mission’s principal investigator at Caltech and JPL. “The performance of the instrument is as good as we hoped. That means we’re going to be able to do all the amazing science we planned on and perhaps even get some unexpected discoveries.” Color Field The SPHEREx observatory won’t be the first to map the entire sky, but it will be the first to do so in so many colors. It observes 102 wavelengths, or colors, of infrared light, which are undetectable to the human eye. Through a technique called spectroscopy, the telescope separates the light into wavelengths — much like a prism creates a rainbow from sunlight — revealing all kinds of information about cosmic sources. For example, spectroscopy can be harnessed to determine the distance to a faraway galaxy, information that can be used to turn a 2D map of those galaxies into a 3D one. The technique will also enable the mission to measure the collective glow from all the galaxies that ever existed and see how that glow has changed over cosmic time. And spectroscopy can reveal the composition of objects. Using this capability, the mission is searching for water and other key ingredients for life in these systems in our galaxy. It’s thought that the water in Earth’s oceans originated as frozen water molecules attached to dust in the interstellar cloud where the Sun formed. The SPHEREx mission will make over 9 million observations of interstellar clouds in the Milky Way, mapping these materials across the galaxy and helping scientists understand how different conditions can affect the chemistry that produced many of the compounds found on Earth today. More About SPHEREx The SPHEREx mission is managed by JPL for the agency’s Astrophysics Division within the Science Mission Directorate at NASA Headquarters. BAE Systems in Boulder, Colorado, built the telescope and the spacecraft bus. The science analysis of the SPHEREx data will be conducted by a team of scientists located at 10 institutions in the U.S., two in South Korea, and one in Taiwan. Caltech in Pasadena managed and integrated the instrument. The mission’s principal investigator is based at Caltech with a joint JPL appointment. Data will be processed and archived at IPAC at Caltech. The SPHEREx dataset will be publicly available at the NASA-IPAC Infrared Science Archive. Caltech manages JPL for NASA. For more about SPHEREx, visit:
SPHEREx
News Media Contact Calla CofieldJet Propulsion Laboratory, Pasadena, Calif.626-808-2469calla.e.cofield@jpl.nasa.gov 2025-063
Written in French, the book is the outcome of decades of botanical research and scientific collaboration between institutions and botanists from Burkina Faso, Mali, France, Switzerland and Germany. For the first time, it provides a complete inventory of ferns and flowering plants in Burkina Faso and Mali. It catalogues 2,631 species – both native and introduced – with 2,115 identified in Burkina Faso, 1,952 in Mali, and 1,453 shared between both countries.
Featuring over 800 photographs, 2,631 scientific illustrations, detailed descriptions, distribution maps, and identification keys, it serves as an essential tool for scientific research and biodiversity conservation. It’s also useful for sustainable development in the region.
We are a team of botanists from Burkina Faso, Mali and Europe who worked on this guide. One of our team is the botanist Jean César, who has carried out botanical research in the region for over 30 years. We based the guide on his earlier work in researching the flora of West Africa, and training young botanists.
By identifying plant species – whether common, rare, overexploited, or invasive – this guide can play a crucial role in conservation efforts: one can only protect what one knows.
The publication lays the groundwork for conservation of Sahelian ecosystems, which face increasing degradation with direct consequences for rural communities.
How we came up with the guide
As a team, we’ve conducted more than 40 years of research in Burkina Faso and Mali, documenting different plants. We also studied herbarium collections in Paris, Montpellier, Frankfurt and Geneva in Europe and Ouagadougou and Bobo-Dioulasso in Burkina Faso.
The book is written in French and includes an index of local plant names in the local languages of Bambara, Dogon, Sonrai, Sénoufo and Peulh. This makes it a valuable resource for local communities and researchers alike. There is an open access digital version to make sure that everyone can use the new illustrated guide.
Discovering new and rare species
The book highlights species previously known from only a few observations. These are both widely distributed species and plants that are rare, only found in unprotected areas facing heavy urbanisation.
About 330 of the plant species in the guide have only ever been seen once in Burkina Faso or Mali, although some are present in neighbouring countries.
Another 40 near-endemic species (mainly only found in Burkina Faso and Mali) have only been seen once 40 years ago. Most of those are aquatic plants, growing along the Niger River, or in small wetland environments.
Additionally, this research updates information on more than a hundred poorly understood species that require further study. Some of these are likely new to science and have not even been given formal names. For instance, we found a new type of Brachystegia tree in the Geneva Botanical Garden’s herbarium. It is new to science and will have to be described.
Many plants documented here hold ethnobotanical value. They are part of the indigenous knowledge of Burkina Faso and Mali and play roles in traditional medicine, agriculture and crafts.
We found more than 120 species that have medicinal uses. Identifying them with correct scientific names will be crucial for the study of how people can continue to use these plants, especially as medicine.
Unfortunately, the current insecurity in the region has made field studies extremely dangerous, threatening conservation projects. For instance, forest rangers can no longer travel freely, and some regions have become inaccessible.
Publishing this book at such a difficult time brings renewed momentum to scientists and serves as a positive sign of continued collaboration. It gives visibility to botanical studies in both countries and highlights the importance of collaborations among botanists from different continents.
By recording this biodiversity, this work not only preserves valuable ecological knowledge but also ensures that the knowledge of these species is not lost to conflict-driven environmental degradation. It sheds light on the importance of preserving plants for future generations.
Cyrille Chatelain receives funding from the Swiss Agency for Development and Cooperation (SDC).
Adjima Thiombiano, Blandine Marie Ivette Nacoulma, and Mamadou Lamine Diarra do not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and have disclosed no relevant affiliations beyond their academic appointment.
WAVES 2025 to witness the release of Statistical Handbook on Media and Entertainment Sector 2024-25 of Ministry of Information and Broadcasting, tomorrow. This is part of Government’s affirmation of the need for timely, reliable, authentic and comprehensive data on the M&E Sector as Media and Entertainment is an important component of the service sector having huge potential to contribute to growth of the economy of the country. Media & Entertainment ecosystem is a sunrise sector expected to grow at 7% CAGR to reach 3067 billion INR in 2027 as per the latest estimate. Various policy initiatives taken and its implementation need to be backed by appropriate data to have the optimum outcome.
Keeping in view the data requirement of the Ministry and other stakeholders in the sector, the Statistical Handbook on Media & Entertainment sector 2024-25, with the updated data and information on different segments of M&E sector will be launched at WAVES 2025 tomorrow.
A few snippets from the Statistical Handbook on Media & Entertainment sector 2024-25 are as follows:
Registered print publications soared from 5,932 in 1957 to 154,523 in 2024-25, with a CAGR of 4.99%
A total of 130 books on various themes including Children’s literature, History and freedom struggles, personalities and biographies, Builders of modern India, Science, technology and environment and other themes have been published by Publications Division, Ministry of Information & Broadcasting during 2024-2025.
100% geographical coverage through DTH service by March 2025.
Doordarshan Free Dish Channels: 33 channels in 2004 to 381 in 2025.
All India Radio (AIR) Coverage: Provides 98% population coverage through radio as of March 2025. Number of AIR radio stations grew from 198 in 2000 to 591 in 2025.
Private Satellite TV Channels surged from 130 in 2004-05 to 908 in 2024-25
Private FM stations grew from 4 in 2001 to 388 by 2024.
Information on State/UT-wise operational Private FM Radio Stations in India as on 31.03.2025.
Community Radio Stations (CRS) surged from 15 in 2005 to 531 in 2025. Data about State/UT/District/Location wise Operational CRS in India as on 31.03.2025 are also included.
741 Indian feature films certified in 1983, which was increased to 3455 in 2024-25, with a cumulative total of 69,113 by 2024-25
In addition to statistical data, information on the following is also available in the Handbook:
Awards in the film sector including International Film Festivals organized and documentaries produced by NFDC are also available in the Handbook.
Digital Media and Creator Economy including WAVES OTT Platform, Indian Institute of Creative Technologies (IICT) and Create in India Challenge (CIC) under WAVES 2025.
Landmark events in Information and Broadcasting Sector viz. the Press Registrar General of India (PRGI), Akashwani, Doordarshan, Private FM Radio Stations and TV-INSAT
Skilling courses under Ministry of Information & Broadcasting.
Ease of Doing Business initiatives by Ministry of Info & Broadcasting including Transformative Portals.
* * *
PIB TEAM WAVES 2025 | Rajith/ Lekshmipriya/ Darshana | 140
Source: Hong Kong Government special administrative region
Proposed road works for expansion of Hong Kong Science Museum and Hong Kong Museum of History gazettedG/F, Harbour Building, 38 Pier Road, Central, Hong KongG/F, Mong Kok Government Offices, 30 Luen Wan Street, Mong Kok, Kowloon4/F, South Tower, West Kowloon Government Offices, 11 Hoi Ting Road, Yau Ma Tei, Kowloon A notice of objection should describe the objector’s interest and the manner in which he or she alleges that he or she will be affected by the works or the use. Objectors are requested to provide contact details to facilitate communication. A notice of objection should be delivered to the Secretary for Transport and Logistics not later than July 2, 2025. Issued at HKT 11:18
Source: United Kingdom – Executive Government & Departments
Government response
Response to arbitration tribunal final report: UK-Sandeel (The European Union v. the United Kingdom of Great Britain and Northern Ireland)
UK Government statement on the sandeel Arbitration Tribunal’s final ruling in the UK-Sandeel case
The UK Government has received the sandeel Arbitration Tribunal’s final ruling in the UK-Sandeel case.
While the UK succeeded in the majority of its arguments, the Tribunal identified a procedural error in the decision to close English waters.
The ruling does not mean the UK is legally obliged to reverse the closure of English waters, and the decision to close Scottish waters was fully upheld.
The government will undertake a process in good faith to bring the UK into compliance.
The sandeel Arbitration Tribunal has published its final ruling.
This relates to decisions taken in March 2024 by the UK and Scottish Governments to close our North Sea Waters to sandeel fishing. The decisions were taken to protect vulnerable seabird populations and support the wider marine environment.
In April 2024, the EU launched dispute proceedings to challenge the closures. In October 2024, the EU referred the challenge to an arbitration tribunal to rule on the dispute.
The report found that the UK successfully demonstrated that the measures taken to close English and Scottish waters were based on the best available science and had sufficient regard to the principle of non-discrimination. The tribunal also found that the Scottish measures had sufficient regard to the principle of proportionality.
The Tribunal found that during the decision-making process to close English waters to sandeel fishing, the UK did not have sufficient regard to the principle of proportionality, specifically in relation to EU rights during the adjustment period – a requirement under the UK-EU Trade and Cooperation Agreement (TCA).
The government will now undertake a process in good faith to bring the UK into compliance.
There is no legal obligation for the UK to reverse the closures while the compliance process takes place, and the report does not indicate that compliance must require reversing the closures.
A government spokesperson said:
We welcome the clarity provided by this decision, and we will undertake a process in good faith to bring the UK into compliance on the specific issues raised by the Tribunal.
The ruling does not mean the UK is legally obliged to reverse the closure of English waters, and the decision to close Scottish waters was fully upheld.
We remain committed to protecting our seabirds and the wider marine environment, in accordance with our commitments to the TCA and other international agreements.
Disputes and the use of resolution mechanisms are a normal part of a mature relationship with international partners. We will continue to act in the national interest as we work towards a strong and lasting partnership with our European neighbours.
Robert F. Kennedy Jr, the United States’ top public health official, recently claimed some religious groups avoid the measles, mumps and rubella (MMR) vaccine because it contains “aborted fetus debris” and “DNA particles”.
The US is facing its worst measles outbreaks in years with nearly 900 cases across the country and active outbreaks in several states.
At the same time, Kennedy, secretary of the Department of Health and Human Services, continues to erode trust in vaccines.
So what can we make of his latest claims?
There’s no fetal debris in the MMR vaccine
Kennedy said “aborted fetus debris” in MMR vaccines is the reason many religious people refuse vaccination. He referred specifically to the Mennonites in Texas, a deeply religious community, who have been among the hardest hit by the current measles outbreaks.
Many vaccines work by using a small amount of an attenuated (weakened) form of a virus, or in the case of the MMR vaccine, attenuated forms of the viruses that cause measles, mumps and rubella. This gives the immune system a safe opportunity to learn how to recognise and respond to these viruses.
As a result, if a person is later exposed to the actual infection, their immune system can react swiftly and effectively, preventing serious illness.
Kennedy’s claim about fetal debris specifically refers to the rubella component of the MMR vaccine. The rubella virus is generally grown in a human cell line known as WI-38, which was originally derived from lung tissue of a single elective abortion in the 1960s. This cell line has been used for decades, and no new fetal tissue has been used since.
Certain vaccines for other diseases, such as chickenpox, hepatitis A and rabies, have also been made by growing the viruses in fetal cells.
These cells are used not because of their origin, but because they provide a stable, safe and reliable environment for growing the attenuated virus. They serve only as a growth medium for the virus and they are not part of the final product.
You might think of the cells as virus-producing factories. Once the virus is grown, it’s extracted and purified as part of a rigorous process to meet strict safety and quality standards. What remains in the final vaccine is the virus itself and stabilising agents, but not human cells, nor fetal tissue.
So claims about “fetal debris” in the vaccine are false.
It’s also worth noting the world’s major religions permit the use of vaccines developed from cells originally derived from fetal tissue when there are no alternative products available.
Are there fragments of DNA in the MMR vaccine?
Kennedy claimed the Mennonites’ reluctance to vaccinate stems from “religious objections” to what he described as “a lot of aborted fetus debris and DNA particles” in the MMR vaccine.
The latter claim, about the vaccine containing DNA particles, is technically true. Trace amounts of DNA fragments from the human cell lines used to produce the rubella component of the MMR vaccine may remain even after purification.
However, with this claim, there’s an implication these fragments pose a health risk. This is false.
Any DNA that may be present in this vaccine exists in extremely small amounts, is highly fragmented and degraded, and is biologically inert – that is, it cannot cause harm.
Even if, hypothetically, intact DNA were present in the vaccine (which it’s not), it would not have the capacity to cause harm. One common (but unfounded) concern is that foreign DNA could integrate with a person’s own DNA, and alter their genome.
Introducing DNA into human cells in a way that leads to integration is very difficult. Even when scientists are deliberately trying to do this, for example, in gene therapy, it requires precise tools, special viral delivery systems and controlled conditions.
It’s also important to remember our bodies are exposed to foreign DNA constantly, through food, bacteria and even our own microbiome. Our immune system routinely digests and disposes of this material without incorporating it into our genome.
This question has been extensively studied over decades. Multiple health authorities, including Australia’s Therapeutic Goods Administration, have addressed the misinformation regarding perceived harm from residual DNA in vaccines.
Ultimately, the idea that fragmented DNA in a vaccine could cause genetic harm is false.
The bottom line
Despite what Kennedy would have you believe, there’s no fetal debris in the MMR vaccine, and the trace amounts of DNA fragments that may remain pose no health risk.
What the evidence does show, however, is that vaccines like the MMR vaccine offer excellent protection against deadly and preventable diseases, and have saved millions of lives around the world.
Hassan Vally does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.
Source: The Conversation (Au and NZ) – By Andrea Carson, 2024 Oxford University visiting research fellow RIJS; Professor of Political Communication., La Trobe University
The spread of electoral misinformation and disinformation is undermining democracies around the world.
The World Economic Forum has identified the proliferation of false content as the leading short-term global risk in 2025 for a second consecutive year. Misleading information poses a bigger threat to global GDP, population and natural resources than even climate change or armed conflict.
Here in Australia, is the federal election facing the same threat from misinformation and disinformation? And how concerned should we be?
Fake information is real
Our latest study on public trust shows Australians are encountering electoral misinformation and are worried about it.
We surveyed more than 7,000 people during March and April when the election campaign was heating up. At least two-thirds of respondents said they had already encountered false or misleading election information.
Whether deliberate (disinformation) or unintentional (misinformation), we found Australians were exposed to different types of election falsehoods involving:
issues and candidates
election procedures
election integrity, such as alleged rigged outcomes and unsupported attacks on the Australian Electoral Commission (AEC).
Consistent with other Australian and international misinformation studies, people are clearly anxious about being misled. An overwhelming majority of respondents (94%) viewed political misinformation as a problem; more than half regarded it as a “big” or “very big problem”.
An array of falsehoods
Our team, based across four universities, examined the types of electoral misinformation and disinformation Australians reported seeing. Almost two-thirds, 63.1%, encountered falsehoods about issues or candidates, such as misleading claims about parties’ policy proposals.
Thirty-nine percent reported misinformation/disinformation about voting procedures, such as when and how to vote. A similar share, 38.4%, identified fake content about election integrity, including false claims that elections are rigged or that the Australian Electoral Commission is colluding with political parties.
A significant number of people, 20-30%, were also unsure whether they had encountered misleading content. This uncertainty is concerning in itself. Being unable to judge the accuracy of information can undermine the formation of informed opinion.
It also aligns with other research showing many Australians feel they have limited ability to verify information online.
The most prominent examples of misinformation/disinformation related to major election issues, such as:
Medicare
nuclear energy
housing
cost of living
climate
The most common names that people associated with misleading information were:
Donald Trump
Clive Palmer
Labor Party
Liberal Party
Facebook
Deeper analysis is needed to understand the context of these self-reported claims of misinformation and disinformation during the campaign. However, we do know that those exposed to false content identified it in both mainstream daily news and social media sources.
Should we be alarmed?
Research across the fields of psychology, communication and political science shows exposure is not the same as impact. Yet, misinformation and disinformation can influence attitudes and behaviour among vulnerable groups.
Our own work on the 2023 Voice referendum showed disinformation targeting the Australian Electoral Commission had a small but noticeable effect on public trust, even though trust remained high overall.
In another global study, we found online disinformation can distort perceptions of election fairness.
These findings underscore the need to counter falsehoods. Electoral authorities and political leaders must work to protect democratic trust and prevent the kind of election denialism that led to the January 6 Capitol insurrection in the United States.
Of course, people might not always accurately judge how much misinformation or disinformation they’ve seen. This is a common challenge in studies like ours. But even if their perceptions don’t match reality, simply feeling exposed to false or misleading information is linked to greater political cynicism.
Fighting falsehoods
Encouragingly, most Australians recognise the problem and want action. In our survey, 89% said it’s important to know how to spot it, while 83% agreed the practice makes it harder for others to separate fact from fiction. But only 69% felt false information affected them personally.
Many feel especially vulnerable about false claims about candidates and election issues (see Figure 1). Such falsehoods are currently unregulated at the federal level in Australia. But the AEC ranks among the world’s most innovative electoral authorities in countering disinformation, even without “truth in advertising” laws.
In another, yet unpublished study, we found the AEC is a global role model with its multi-pronged strategy to counter misleading information. Its tools include a public disinformation register, media partnerships, and the “Stop and Consider” campaign, which provides clear, accurate information to help voters think critically before sharing content.
Our own study revealed other encouraging signs. Individuals who are more satisfied with Australian democracy perceive disinformation as less of an existential threat than those who are already dissatisfied. This suggests a positive attitude towards democracy helps protect democratic institutions.
This provides a strong rationale for non-profits such as the Susan McKinnon Foundation to promote the value of democratic governance. The Scanlon Foundation, is also making an important contribution with its recent Voices of Australia podcast series, “Truth, Trust and Politics”.
Whoever wins the election, our study shows one thing is clear – fighting electoral misinformation and disinformation is in everyone’s democratic interest.
Andrea Carson receives funding from the Australian Research Council for this project led by AJ Brown at Griffith University: DP230101777 — Mapping & Harnessing Public Mistrust: Constitutional Values Survey 2023-27.
Max Grömping receives funding from the Australian Research Council for this project led by AJ Brown at Griffith University: DP230101777 — Mapping & Harnessing Public Mistrust: Constitutional Values Survey 2023-27.
The world has been gripped by the case of Australian woman Erin Patterson, who was charged with the murder of three people after allegedly serving them a lunch of beef wellington containing poisonous death cap mushrooms (Amanita phalloides).
A new element of the sensational story emerged in court this week, when prosecutors reportedly alleged Patterson used iNaturalist to locate and visit places where death cap mushrooms were known to grow.
So what exactly is iNaturalist? And how is this 17-year-old citizen science project being used to better understand our world?
More than 240 million observations worldwide
iNaturalist is an app that allows users to take photos of plants, fungi, animals and any piece of nature. The photos are uploaded, and identified using a combination of crowd-sourcing and artificial intelligence.
All of this data is extremely important for scientists to understand the ecology of different species. iNaturalist has played a key role in the discovery of new species as well as sightings of species that have previously not been seen for decades.
iNaturalist might turn out to be an important part of Patterson’s trial, but how else can our observations be used?
Finding the unusual
Real people usually collect images for iNaturalist as part of their everyday life, rather than systematically as part of their job. That means there are patterns to the data that is collected.
Observations tend to be recorded on weekends and in good weather, and to involve life forms people find strange, unusual or interesting.
For example, at the time of writing, iNaturalist had recorded 1,382 sightings of domestic cats in Australia, compared with 29,660 koalas. But cataloguing the rare and wonderful can be useful.
When a user uploads an image to iNaturalist, they can also choose to make the location public, so others can see where it was found. iNaturalist
iNaturalist can be used to track invasive species
One key use of iNaturalist is understanding the native range of plants and animals.
Australia invests a lot of resources in preventing species from entering the country. But we still see incursions frequently. Observant citizen scientists can be really important for finding species outside their native range. In Australia, if observations of biosecurity threats are made, alerts are automatically sent to biosecurity teams for further investigations.
In the same vein, species commonly found in the pet trade can be quickly observed and captured to prevent the spread of invasive species.
In 2011, iNaturalist added more features to protect geoprivacy – which allows locations of observations to be obscured. Rare and exciting pets, and collectable insects could be found by looking at location data on iNaturalist.
There is previous evidence this has occurred. Nowadays, species of concern for poaching automatically have their locations obscured, preventing them from being illegally poached or collected. This can also be helpful to prevent people crowding popular endangered animals when they have been sighted.
Typically, anything listed as endangered will automatically have an obscured location on iNaturalist.
Observations on iNaturalist can be helpful for forensics
Observing nature, and taking photos of plants and animals in their native environment, can give us a much better understanding of where they naturally live and grow.
Aside from being fantastic for conservation reasons, this has potential use for forensic investigation of crimes. The use of insects, animals and plants in forensic cases is well established. For example the Sarcosaprophagous Beetle is used in Australia to help understand the time since death when bodies are found.
This sort of science is underpinned by an understanding of where insects naturally live, their lifespans and the sort of environments they thrive in, which are all features iNaturalist can help with.
Should I worry about my location data on iNaturalist?
Observing nature has huge benefits to understanding our natural world. But these observations do collect a lot of personal data in terms of where and when the observation occurred.
Although iNaturalist doesn’t sell users’ information, and users can obscure their precise location, the pictures a person shares can still contain enough information to figure out where they are.
This could be used for forensic intelligence to locate plants and animals of interest, and to place people with them at the time the photo was taken.
If you’re lucky enough to see a rare or threatened species, consider taking a photo that has little background information that can give away the precise details of the locations, particularly when observing immobile organisms like such as plants and fungi.
iNaturalist has played a key role in the discovery of new species. kodartcha/Shutterstock
iNaturalist is a fantastic resource for observing nature. More data points to understand where plants, animals, and mushrooms can be found is vital for understanding their ecology, and potentially conserving species.
It also has huge ramifications for biosecurity, forensics, and even understanding movements that may have occurred during an alleged crime. So it’s really worth getting out in nature and taking photos of interesting things you see!
Melissa Humphries receives funding from the MRFF, NIH, USDoD and DSTG.
Caitlyn Forster does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.
The native shrimp _Paratya australiensis_ was among the species found to incorporate carbon from natural gas into their bodies in the Condamine River.Chris Van Wyk/Flickr, CC BY-NC-ND
What’s the currency for all life on Earth? Carbon. Every living thing needs a source of carbon to grow and reproduce. In the form of organic molecules, carbon contains chemical energy that is transferred between organisms when one eats the other.
Plants carry out photosynthesis, using energy from sunlight to convert carbon dioxide and water into sugar and oxygen. Animals get carbon by consuming organic matter in their diet – herbivores from plants, carnivores from eating other animals. They use this carbon for energy and to produce the molecules their bodies need, with some carbon dioxide released by breathing.
But there are other, stranger ways of getting carbon. In our new research, we found something very surprising. River animals were feeding on methane-eating bacteria, which in turn were consuming fossil fuel as food.
Usually, the carbon used as food by river creatures is new in the sense it has been recently converted from gas (carbon dioxide) to solid carbon through photosynthesising algae or trees along the bank. But in a few rivers, such as the Condamine River in Queensland, there’s another source: ancient natural gas bubbling up from underground, which is eaten by microorganisms. Insects such as mayflies have taken to this methane-based carbon with gusto.
How does a river usually get its carbon?
The way photosynthesised carbon moves from a plant to an animal and then another animal can be described as a food web. Food webs show the many different feeding relationships between organisms, and show how species depend on each other for sustenance in an intricate balance.
In a river food web, carbon usually comes from one of two sources: plants growing and photosynthesising in the river (such as algae), or when organic matter such as leaves are washed in by rain or blown in by wind.
Rivers that are well connected to their floodplains often get plenty of carbon from leaf litter from trees which dissolves in water or is eaten directly by animals. Algae in rivers provide a high-quality source of carbon for animals because they can contain high concentrations of omega-3 fatty acids essential for growth and reproduction.
The primary source of carbon for river animals varies depending on prevailing conditions and the individual river.
The carbon of the Condamine
Some microorganisms called archaea naturally produce small amounts of methane in oxygen-depleted sediments of rivers.
But we wanted to look at the Condamine to see whether much larger volumes of methane could be used as food.
After it forms deep underground, natural gas can slowly escape through cracks in the earth. If a river bed is directly above, this methane-rich gas will seep into the river.
That’s what happens in Queensland’s Condamine River. The river rises on Mount Superbus, inland from Brisbane, and flows inland until it meets the Darling River.
In some parts of the river, methane bubbles up constantly through the water column from a natural gas reservoir that formed since the Late Pleistocene.
In these stretches of river, dissolved methane concentrations are extremely high: up to 350 times greater than trace concentrations upriver, away from the methane seep.
We wanted to see whether methanotrophic bacteria consuming methane from natural gas were being eaten by river animals, and whether we could trace the carbon signature through the food web.
To find out, we analysed the carbon in the bodies of river animals such as zooplankton, insects, shrimp, prawns and fish, and compared it to the different sources of carbon that could make up their food.
The results were clear: animals within reach of the natural gas seeping from underground had a distinct carbon signature showing they were eating food derived from the natural gas. In fact, for insects such as mayflies, methane-based food made up more than half (55%) of their diet.
Over time, this methane-derived food moved up the food web, showing up in prawns and even fish. Here too, it contributed a significant portion of their carbon.
Natural gas bubbles up through the water column to the surface of the Condamine in some stretches. Gavin Rees, CC BY-NC-ND
We found this methane–derived carbon moved through multiple levels of the local food web. It made up almost a fifth (19%) of the carbon in shrimp and 28% of the carbon in carnivorous fish.
For river shrimp and prawns, leaves washed into the river were still important sources of carbon. For mayflies, algae was still an important source of food.
But our work shows that natural gas seeps can be a major, even dominant, source of energy for the entire food web. This is very surprising. It shows an unexpected connection between Earth’s geology and living creatures in a river.
Why does this matter?
Until now, researchers have focused on river and land plants as the main way a river gets its carbon. Our research has uncovered a surprisingly significant way some rivers get their carbon – methane.
In deep sea research, this pathway is better understood. Methane-eating bacteria can form the basis of entire ecosystems which have sprung up around deep sea hydrothermal vents of hot water.
But until now, we have overlooked the role methane-eating bacteria can play in rivers. With this knowledge, we can better track the flows of carbon in rivers so we can gauge ecosystem productivity and see how a food web is functioning.
Paul McInerney receives funding from the Commonwealth Environmental Water Holder.
If you own a business, would you be willing to hire a person who has been convicted for a crime? Give them a chance when a background check shows they have a criminal record?
The answers matter for both individuals and communities. For people who have paid their debt to society, rejoining it can hinge on getting a second chance without being judged on their past.
It is not something they can really hide. Employers often conduct criminal background checks as part of the hiring process. People with criminal records face high levels of stigmatisation, making it harder to reenter their communities and make money legally.
The thorny question of what to do with people with convictions when it comes to employment has been considered by policymakers and justice campaigners around the world.
In the United States, more than 27 states have introduced “Ban the Box” legislation. While each law is unique, by and large they have eliminated the requirement to provide criminal background information in job applications.
And a number of countries, including New Zealand, have implemented clean slate initiatives which help conceal criminal records for people who meet certain criteria.
Our new research looks at whether New Zealand’s clean slate scheme increases the job prospects for eligible people.
The clean slate reform was introduced as the Criminal Records Act in 2004. People who were previously convicted of minor offences can now have their criminal records automatically concealed if they can maintain a conviction-free record for seven years after their last sentence.
The regulation excludes people who were involved in a serious offence (such as sexual misconduct) or who received a particularly punitive sentence (such as incarceration or an indefinite disqualification from driving).
The Criminal Records Act allows eligible people with a conviction to wipe their slate clean seven years after their last sentencing. Shutterstock
Clean slate and the labour market
Our research started with the Integrated Data Infrastructure (IDI), hosted by Statistics New Zealand (StatsNZ). This is a repository of records provided by different public and private agencies, including court charge data from the Ministry of Justice and tax records from Inland Revenue.
StatsNZ uses specific characteristics of individuals (such as name and birth date) to identify them across the different datasets. This enables researchers to track the same individual’s data footprint across different administrative records.
We used court charges data on all men convicted between 1992 and 2003 who had fulfilled the clean slate eligibility criteria. We then linked this pool of people with their Inland Revenue records to measure their employment and earnings.
To identify the labour market impact of the clean slate policy, we compared the employment and earnings of those who completed their seven-year rehabilitation period (the treatment group) with individuals who become eligible some time later (control group).
Limited benefits of clean slate scheme
Our analysis found the clean slate scheme has no relevant impact on the likelihood of eligible individuals finding work. This could result from the length of time required between sentencing and being eligible for a clean slate. Seven years could simply be too long.
But the clean slate scheme did create at least a 2% increase in eligible workers’ monthly wages and salaries – equivalent to a NZ$100 hike for an individual with an average monthly salary of $5,000.
The increase in monthly earnings appears to be greater for workers with a stronger commitment to working and for those who remain with one company for longer periods.
Global patterns
The labour market effects of concealing past convictions have also been explored in the US. Recent research looked at a policy enacted in Maryland, New Jersey, Pennsylvania and Bexar County, Texas. Mirroring our own results, the authors do not find any relevant impact on gaining employment.
Our findings indicate the concealment of past convictions through New Zealand’s clean slate scheme might happen too late to make a huge difference. But there are changes that can be made to improve work outcomes for people who have completed their sentences.
This could include following the example of countries such as Finland, where access to criminal histories is much more restricted. In Finland, the background check has to be directly relevant to the job requirements. For example, the law allows checks for someone applying to work in the financial sector who was convicted of fraud.
There would also be benefits from looking at the eligibility criteria for New Zealand’s clean slate scheme.
Currently, it only applies to people who committed a minor offence. But policymakers should consider whether it makes sense to expand the policy to people who committed more serious crimes but managed to turn their life around. Making this change would allow people to reap the benefits of working without stigma.
All that said, the government’s current “tough on crime” stance makes change unlikely, with a focus on the cost of crime rather than what happens after punishment has been completed.
Kabir Dasgupta is affiliated with the Federal Reserve Board. The opinions expressed in this article does not reflect the views of the the Federal Reserve Board or the Federal Reserve System.
Alexander Plum does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.
Owls, well adapted to hearing the exact location of prey, have something in common with an unrelated group of raptors – harriers.
A new study led by Canadian and Australian researchers has found that harriers across the world are able to keep a much better ear out for their next meal than previously thought.
The international team of University of Lethbridge and Flinders University researchers made the discovery when they found unexpected owl-like traits in the ear and brain of several harrier species, such as the Australian spotted harrier.
The new article published in Journal of Anatomy features the work of the Iwaniuk Lab at the University of Lethbridge in Alberta and Associate Professor Vera Weisbecker’s ‘Bones and Diversity Lab’ at Flinders University in South Australia.
University of Lethbridge PhD student Sara Citron, who led the study, says owls have fine-tuned hearing abilities, allowing some of their species to locate prey in complete darkness.
“Until recently, it was assumed that all their hearing adaptations were unique to owls. However, our study shows that harriers have independently evolved several key adaptations for finding prey by sound,” she says.
The research team focused on harriers – a group of hawks found in North America, Australia, NZ, Europe, and parts of Africa and Asia – because they show some unusual, owl-like hunting behaviours.
Senior author and PhD supervisor Dr Andrew Iwaniuk, Associate Professor at the Canadian Centre for Behavioural Neuroscience, says: “Hawks tend to hunt primarily by sight. But unlike other hawks, harriers fly low over tall grass with their beak pointed to the ground.
“During this so-called ‘quartering flight’, they are not only looking for prey, they are also listening for it,” he says.
Co-author Aubrey Keirnan, a PhD student at Flinders University who is also co-supervised by Dr Iwaniuk and Flinders University Associate Professor Vera Weisbecker, says that simply by looking at the harrier, you can see similarities with owls.
“The Australian Spotted Harrier is a great example,” she says. “When you look at this species’ face, you can see a distinctive disc-shaped face, which may improve their prey localisation just like owls.”
The discovery matches older behavioural studies showing that harriers can locate sounds with similar accuracy to owls, but how they did this has been a mystery.
Using specimens from wildlife rehabilitators and museums in Australia and Canada, the team examined the anatomy of the skull and brain of harriers and other closely related hawk species such as the wedge-tailed eagle.
They found that, like owls, harriers have enlarged ear openings and two expanded brain regions that are essential for calculating where a sound is coming from.
“These auditory nuclei are found in the brainstem and compare the time at which sounds arrive at the left or right ear,” says co-author Associate Professor in evolutionary biology Vera Weisbecker, from Flinders University’s College of Science and Engineering.
“If a sound arrives at both ears at the same time, then the sound is coming from directly in front of an animal. If there is a delay, this indicates that the prey is more to the left or right,” she says.
“By having these two brain regions expanded, harriers can make such computations more accurately than other hawks, allowing them to locate where a potential rat, mouse or other prey is hiding in the grass.”
“Harriers have therefore evolved an auditory system similar to owls, enabling them to target sounds as accurately as owls in a remarkable example of convergent evolution of both brain and behaviour in animals separated by over 60 million years,” adds first author Ms Citron.
The team is careful to point out that the auditory system of many owls is far more sophisticated than that of harriers. This explains the ability of some owl species, such as the barn owl, to hunt in complete darkness whereas hawks only hunt during the day.
“There are several other features that help owls with their keen hearing which we did not find in harriers. For example, some owl species have asymmetric ears that allow them to locate sound with greater acuity, and these owls also have several other enlarged brain regions that were not enlarged in harriers,” says Ms Citron.
The team hopes their study results will encourage further research on bird anatomy to find out how a species perceives its surrounds.
“Anatomical studies like ours are a window into how a bird perceives the world around it, which can be extremely useful for bird conservation,” adds Dr Iwaniuk. “For example, harriers’ reliance on sound for prey location means that they are likely more sensitive to traffic and industrial noise. This could be contributing to the large decreases in Northern Harrier populations we have seen in Canada.”
The article, ‘The evolution of an “owl-like” auditory system in harriers: Anatomical evidence’ (2025) by Sara Citron, Cristian Gutierrez-Ibanez, Aubrey Keirnan, Vera Weisbecker, Douglas Wylie, Andrew N Iwaniuk has been published in Journal of Anatomy (Wiley Online Library) DOI: 10.1111/joa.14264.
Source: United States House of Representatives – Congressman David G. Valadao (California)
WASHINGTON –Today, the House of Representatives passed a Congressional Review Act resolution to repeal the Biden Administration’s listing of the longfin smelt as endangered under the Federal Endangered Species Act. This resolution would halt the proposed designation of critical habitat for the longfin smelt, as well as ensure California’s water remains available for those who need it most—families and farmers. Congressman Valadao joined Reps. Doug LaMalfa (CA-01), Vince Fong (CA-20), Tom McClintock (CA-05), Darrell Issa (CA-48), and Young Kim (CA-40) in introducing this resolution in March 2025.
“Th Biden Administration’s unnecessary decision to list the longfin smelt as an endangered species is yet another example of an environmental policy not grounded in science that puts fish over people,”said Congressman Valadao.“Our families and farmers are already struggling with burdensome regulations that restrict water deliveries and threaten the future of agriculture in the Central Valley, and this rule would have ensured even more of our water is sent out to sea. By passing this resolution, the House is taking an important step forward in rolling back draconian water restrictions that directly affect our farmers, families, and rural communities, and I’m happy to see common sense won.”
“The Biden Administration and activist judges have used this listing as a political tool to block progress on California water policy,”said Rep. LaMalfa.“This listing is based on cherry picked scientific anecdotes and even Stanford’s Center for Water California Recourses Policy and Management questioned the science of the listing. It adds yet another layer of conflicting regulations that dump tens of millions of acre feet of water out to the Pacific Ocean, with farmers receiving only 40% to 50% of their promised federal and state water. Congress isn’t going to stand by while bureaucrats and environmental lawsuits continue to wreck the water system that feeds our farms, our families, and our economy. I’m glad to see the House take a stand and push back with real solutions that help us grow food, provide water, and keep our economy strong.”
Background:
This designation, driven by litigation from an environmental group, by the U.S. Fish and Wildlife Service during the Biden Administration threatens California’s water supply by imposing new restrictions on the Central Valley Project (CVP) and State Water Project (SWP). This listing resulted in subsequent burdensome requirements imposed on the CVP that will divert even more water to the Pacific Ocean instead of supplying farms and families across the state. Under the Congressional Review Act, Congress can review and potentially block such regulations within a specific timeframe, and it drops the usual 60-vote requirement in the Senate for these resolutions.
Source: United States Senator Alex Padilla (D-Calif.)
Senate Advances Padilla, Murkowski Bipartisan Legislation to Reauthorize National Earthquake Hazards Reduction Program
WASHINGTON, D.C. — Today, U.S. Senators Alex Padilla (D-Calif.) and Lisa Murkowski (R-Alaska) announced that the Senate Commerce Committee unanimously advanced their bipartisan legislation to reauthorize the National Earthquake Hazards Reduction Program (NEHRP) through Fiscal Year 2028. The bill would provide lifesaving funding to support research, development, and implementation activities related to earthquake safety and risk reduction.
The NEHRP Reauthorization Act of 2025 would reauthorize annual funding from FY 2024-2028 across the four federal agencies responsible for long-term earthquake risk reduction under NEHRP: the Federal Emergency Management Agency (FEMA), the National Institute of Standards and Technology (NIST), the National Science Foundation (NSF), and the United States Geological Survey (USGS). The Senate unanimously passed a version of this bill late last year, but it was not taken up in the House of Representatives.
“It is not a matter of if, but when the next major earthquake strikes, and Californians know the importance of staying prepared,” said Senator Padilla. “The National Earthquake Hazards Reduction Program supports crucial tools like the ShakeAlert Earthquake Early Warning System, works to advance scientific understanding of earthquakes, and strengthens earthquake resilience in communities nationwide. I am glad to see this bipartisan effort move forward, and with the safety of our communities at stake, we must reauthorize this critical program as soon as possible.”
“Alaska is no stranger to massive earthquakes that can cause serious damage to our communities. From the 1964 Good Friday earthquake, the 7.1 earthquake in 2018, to the thousands of smaller quakes that rattle our state each year—it’s critical we invest in programs that keep us prepared and ready to respond to disaster,” said Senator Murkowski. “I am pleased to see that the Commerce Committee has advanced the National Earthquake Hazards Reduction Program Reauthorization Act, which will modernize earthquake safety programs in western states, reinforcing our readiness for future seismic activity. I look forward to supporting legislation on the Senate Floor.”
“The Earthquake Engineering Research Institute applauds the Senate Commerce Committee’s bipartisan advancement of the National Earthquake Hazards Reduction Program Reauthorization Act of 2025. This is a critical step in strengthening our nation’s long-term resilience to earthquakes. With an estimated $15 billion in losses from earthquakes in the U.S. every year, sustained support for mitigation is not only cost-effective—it is essential. We are encouraged to see momentum behind this program and look forward to continuing the vital work of reducing seismic risk in communities across the country,” said Ellen Rathje, President of the Earthquake Engineering Research Institute.
“The International Code Council welcomes Senator Padilla and Murkowski’s bipartisan leadership to reauthorize the National Earthquake Hazards Reduction Program (NEHRP),” said Code Council Chief Executive Officer John Belcik. “We call on Congress to immediately reauthorize NEHRP to continue the advancement of model building codes that improve building safety and earthquake resilience.”
“The American Society of Civil Engineer (ASCE) applauds Senators Alex Padilla and Lisa Murkowski for prioritizing the resilience of our nation’s infrastructure against seismic events and is pleased to support their efforts to reauthorize the National Earthquake Hazards Reduction Program (NEHRP). Since 1977, NEHRP has provided the resources and leadership that have led to significant advances in understanding the risk earthquakes pose and the best ways to mitigate them. This reauthorization will ensure that NEHRP resources continue to improve our understanding of earthquakes and guide the ASCE standards that form the backbone of building codes that protect public health, safety, and economic vitality,” said ASCE Past President Marsia Geldert-Murphey.
“The National Council of Structural Engineers Associations is proud to support the NERHP reauthorization bill and is grateful for the bi-partisan leadership of Senators Padilla and Murkowski. NCSEA urges Congress to prioritize reauthorization to enable the NEHRP agencies to contribute critical science, knowledge, and other best practices toward the development of codes, standards, and other resources used by structural engineers around the country to improve the earthquake resilience of our communities,” said Alfred Spada, Executive Director of the National Council of Structural Engineers Associations (NCSEA).
“SEAOC commends Senators Padilla and Murkowski for championing NEHRP reauthorization, aligning with Structural Engineers Association of California’s (SEAOC) commitment to enhanced seismic safety and community resilience. SEAOC implores Congress to act promptly in fortifying California and the entire nation against the seismic challenges ahead,” said Don Schinske, Executive Director of the Structural Engineers Association of California (SEAOC).
This NEHRP reauthorization includes:
Directing state and local entities to inventory high risk buildings and structures;
Expanding seismic events to include earthquake-caused tsunamis;
Providing more technical assistance to tribal governments; and
Improving mitigation for earthquake-connected hazards.
California faces substantial earthquake risks. According to the California Department of Conservation, over 70 percent of Californians live within 30 miles of a fault that could cause high ground shaking within the next 50 years. The state averages two to three earthquakes per year at magnitude 5.5 or higher, risking moderate structural damage. Because of these major earthquake risks, California has become a leader in earthquake research, including through the California Institute of Technology Seismological Laboratory.
The NEHRP Reauthorization Act of 2025 is endorsed by the American Society of Civil Engineers (ASCE), Earthquake Engineering Research Institute (EERI), International Code Council, National Council of Structural Engineers Associations (NCSEA), and Structural Engineers Association of California (SEAOC).
Senator Padilla has long been a leader in mitigating earthquake risks. As a California State Senator, Padilla authored Senate Bill 135, signed by Governor Jerry Brown in 2013, which required the state to establish the nation’s first statewide early warning system. In 2021, he led five of his U.S. Senate colleagues in requesting details from the U.S. Geological Survey (USGS) on future plans and funding needs for the West Coast Early Earthquake Warning system.
Source: United States Senator Alex Padilla (D-Calif.)
Padilla Introduces Bill to Strengthen Reservation Systems for Public Lands as Trump Administration Announces Scaled-Back Yosemite Summer Reservation System
After push from Padilla, Yosemite will implement a 2025 seasonal reservation system to improve visitor access and experience; however, the system is significantly pared down from the plan Yosemite proposed
WASHINGTON, D.C. — Today, U.S. Senator Alex Padilla (D-Calif.) introduced legislation to expand access to public lands, improve the visitor reservation process, and enhance transparency in how fees are collected for federal lands and national parks. The Review and Evaluation of Strategies for Equal Reservations for Visitor Experiences (RESERVE) Federal Land Act would direct the National Academy of Sciences (NAS) to study and recommend improvements to reservation systems across federal lands to ensure they are fair, user-friendly, and accessible to all Americans.
The legislation comes after the Trump Administration, following significant delays, announced that Yosemite National Park will implement a 2025 seasonal reservation system. However, this year’s system is significantly scaled back from the plan Yosemite successfully piloted previously, which was carefully crafted based off public input and data. This year’s system requires reservations for fewer days and hours than what Yosemite proposed. Earlier this year, Padilla pushed Secretary of the Interior Doug Burgum to allow Yosemite to implement its preferred reservation system, emphasizing its importance in managing park visitation while preserving Yosemite for future generations.
“For months, I’ve joined with park officials in calling on the Trump Administration to extend the use of Yosemite’s successful reservation system. While the decision to open reservations at Yosemite National Park for the summer is a win for outdoor lovers, the environment, and local businesses that rely on park visitors, it shouldn’t have taken this long,” said Senator Padilla. “The needless delays by the Trump Administration in approving a reservation system, and the Administration’s scaling back of Yosemite’s carefully crafted plan, will undermine the visitor experience for the millions who come to California to view this natural wonder. Congress must continue to invest in the staffing and resources needed to protect our national parks. We can start by passing my RESERVE Act, which will launch a national study on how to improve Recreation.gov and other public land reservation systems so they are accessible, transparent, and supportive of local communities’ needs.”
Yosemite is California’s most visited National Park, with an average of 3.3 million visitors annually. Last year, that number surged to 4.2 million visitors as Yosemite again piloted reservations during peak summer months. For decades, overcrowding, vehicle congestion, limited parking, and long lines have diminished what should ordinarily be a world-class experience, particularly for first-time visitors. Thanks to the reservation system, however, Yosemite was able to accommodate pre-pandemic visitor levels but without the excessive congestion. The reservation system helped distribute visitors more evenly throughout the day, week, and peak summer season.
Federal land management agencies have experimented with new visitor management methods such as online reservation systems for other public lands as well; however, there has been little national research on how these systems can be improved.
The RESERVE Act would direct NAS to study reservation systems across federal lands, including campsites, hiking permits, climbing passes, and other outdoor recreation activities. The report would be due in 18 months and would cover reservation system design, system user demographics, and data availability and accessibility. The study would also investigate the fee structure and transparency of Recreation.gov, the government’s centralized travel planning platform and reservation system for 14 federal agencies.
Senator Padilla is a strong advocate for ensuring equitable access to outdoor spaces. Last year, President Biden signed Padilla’s bipartisan, bicameral Outdoors for All Act into law as part of the Expanding Public Lands Outdoor Recreation Experiences (EXPLORE) Act. The Outdoors for All Act expands outdoor recreational opportunities in urban and low-income communities across the nation.
Scientists are researching how best to identify mushroom species as a basis for a potential drug-checking service.
Magic mushrooms are coming under the microscope, as scientists at the University of Auckland forage for evidence to support a drug-checking service with the goal of reducing harm.
Doctoral student Sam Lasham will research the science and the acceptability of such a service.
“We’d like to work out the effectiveness of a magic mushroom drug-checking service and the best way to run that, and, in the case of people who are seeking mental health benefits, reduce the risks and offer advice on safe consumption,” Lasham says.
Lasham’s interest grew out of his studies at the University of Otago in genetics and botany and focused on Aotearoa New Zealand’s indigenous mushrooms.
“I was using environmental DNA from soil across our native beech forests in the South Island to estimate where species were and what species were around.
“A lot of that research was focused on DNA sequencing and something called ‘DNA barcoding’, which is using short genetic sequences to identify species.
“That’s what has led into this, because the most important thing, from a safety perspective, is making sure you’ve got the right species of mushroom, and you haven’t got a common lookalike that’s poisonous.”
At the same time, Lasham became interested in illicit use of psilocybin mushrooms and the need for harm-reduction measures, founding Students for Sensible Drug Policy Aotearoa in Dunedin.
There has been increasing interest in the potential benefits of hallucinogenic mushrooms, including studies of microdosing for mental health and creativity at Waipapa Taumata Rau, University of Auckland.
Magic mushrooms are typically either grown from spores or foraged, then prepared in various ways to preserve them and enhance their effects.
The active ingredient, psilocybin, is relatively benign, but mushrooms contain other pharmacologically active compounds.
Adverse effects can include nausea, vomiting, increased heart rate, and headaches. If foraging, the biggest risk is accidentally picking a poisonous look-a-like species.
“Galerina are the best example of this as they are very similar to Psilocybe subaeruginosa but they contain some of the same toxins (amatoxins) as the death cap mushroom,” Lasham says.
There are numerous reports of a syndrome termed ‘wood-lovers paralysis’, which seems to be caused by species of psilocybin mushrooms that grow on wood.
Lasham is based in the School of Pharmacy using the lab to identify the constituent parts of various types of mushrooms.
He is working in senior lecturer Dr Rhys Ponton’s research group, which holds the only drug-checking licence specifically for research purposes in Aotearoa New Zealand.
“People can bring their mushroom samples in and know they are legally protected while we are doing a full, confidential and free check of their drugs,” Lasham says.
“We can test the samples to make sure they’re not a poisonous species and also to tell them what dose they have got, which will be another innovation that’s not currently being offered in any drug-checking service.”
The researchers will interview and survey people across the country to see how mushrooms are being consumed, what mushrooms people are using, how they’re using them and what sort of effects they are getting.
An advisory group of people with lived experience of mushroom use will guide how the research is set up, implemented and interpreted.
The research is supported by funding from the HRC and Ember Innovations.
Success in the lab could enable a ‘know your mushrooms’ service to run in a similar way to current drug-checking services at festivals, events and in the community.
Source: The Conversation (Au and NZ) – By Philippa Specker, Postdoctoral Research Fellow at the Refugee Trauma and Recovery Program, School of Psychology, UNSW Sydney
When Australia signed the United Nations 1951 Refugee Convention, it committed to providing protection to people who have fled war, persecution and human rights violations.
Refugees have often experienced severe traumatic events. This can include war, torture, kidnapping and witnessing the murder of loved ones.
Understandably, refugees are more likely than the general population to experience mental health problems. About 27% of adult refugees suffer from post-traumatic stress disorder (PTSD) and 30% from depression. Only 5.6% of Australians experience PTSD and 6.4% experience depression.
Australia has a humanitarian and legal responsibility to support the mental health of refugees and asylum seekers so they can recover and thrive.
Mental health problems are highly treatable when people have access to effective treatment. Addressing key barriers to accessing mental health services is in everyone’s best interest.
So, what mental health support is available for refugees when they arrive in Australia?
Different pathways
Much depends on how the person came to Australia and through which scheme they applied to be recognised as a refugee.
First, there are people who apply for and are granted refugee status by the United Nations High Commissioner for Refugees (UNHCR) or Australia’s humanitarian program before arriving in Australia.
These people, often termed “humanitarian entrants”, represent the largest cohort of Australia’s refugees.
Humanitarian Settlement Program caseworkers can refer these people to internal or external mental health support services.
Importantly, people under Australia’s humanitarian program can also access vital services such as:
Medicare
Centrelink
English-language classes.
They also have the right to work and study. This helps promote recovery, adjustment and wellbeing.
Some people apply for and are granted refugee status by the United Nations High Commissioner for Refugees before arriving in Australia. John Wreford/Shutterstock
Second, there are people who sought asylum via alternate pathways.
This often means they arrived in Australia without a valid visa. Or, they may have held a non-refugee visa and subsequently applied for refugee status after arriving in Australia.
These people, termed “asylum seekers”, are in a much more precarious situation.
They face lengthy visa processing times, the possibility of being held in detention, and a greater likelihood of being granted only temporary visas.
Many people in this situation are restricted from accessing government-run settlement support, such as the Humanitarian Settlement Program and Centrelink.
Demand for specialised mental health services is high. That can mean long waiting times for all Australians, including refugees and asylum seekers.
Research has identified a number of barriers that especially affect refugees and asylum seekers. These include:
stigma around mental health problems and help-seeking
lack of knowledge on mental health
language and cultural barriers, and
logistical barriers (such as cost and travel distance).
Finally, some refugees (particularly asylum seekers or people with temporary visas) may not be as aware of mental health services as humanitarian entrants. The latter group are often connected with such services while part of the Humanitarian Settlement Program.
This puts the onus on such individuals to independently research what services are available and refer themselves.
That’s a tough ask for people also busy finding housing, learning English, enrolling children in school, and progressing their visa applications.
International law dictates that survivors of torture and other forms of persecution under Australia’s protection have access to effective rehabilitation services.
More broadly, the psychological cost of trauma can make it harder for some refugees to adapt to life in Australia. PTSD and depression can be chronic conditions. Without effective treatment, mental health challenges can persist for decades.
Helping refugees recover from the psychological effects of trauma and displacement also promotes the prosperity of the wider community. That’s because refugees enrich Australian society by establishing local businesses, working, facilitating new trade links, volunteering and contributing to the community.
When refugees thrive, we all do.
Philippa Specker receives funding from an MQ: Transforming Mental Health Postdoctoral Scholarship (MPSIP15). She is an associate of the Human Rights Institute, UNSW.
Angela Nickerson receives funding from the Australian Research Council and the National Health and Medical Research Council.
Belinda Liddell receives funding from the Australian Research Council and National Health and Medical Research Council.
Source: People’s Republic of China – State Council News
KUNMING, May 1 — A park built on the Yuanmou ape-man archaeological site in southwest China’s Yunnan Province opened to the public on Thursday.
Located in the Chuxiong Yi Autonomous Prefecture, the park aims to become an integrated cultural space where visitors can experience millions of years of human history.
The Yuanmou ape-man site, located on a hillside about 200 meters from Danawu Village in Yuanmou County, was where two fossils of ancient human teeth were discovered in 1965. These fossils date back some 1.7 million years.
The park has a planned total area of over 370 hectares and is being developed in three phases. “We will strive to build the park into a comprehensive base that integrates paleogeological research and education, the scientific exploration of human origins, and the in-depth study of prehistoric cultural development,” said Zhang Wenwang, head of the prefecture.
Gao Xing, a researcher at the Chinese Academy of Sciences’ Institute of Vertebrate Paleontology and Paleoanthropology, said that the Yuanmou ape-man and culture were significant discoveries of ancient human remains in China. They are the first chapters in China’s elementary and middle school history textbooks, and an important testament to the survival and evolution of the early Homo erectus in East Asia.
Also on Thursday, an event marking the 60th anniversary of the discovery of the Yuanmou ape-man site was held in the county. Scholars and researchers from diverse fields convened to discuss topics such as human migration tracing, Paleolithic archaeology, site value transformation and digital cultural innovation.
