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Georgia Southern’s Shainaz Landge receives Regents’ Scholarship of Teaching and Learning Award
For Shainaz Landge, Ph.D., pushing boundaries in the classroom and the laboratory isn’t just a professional pursuit, it’s a passion. As an associate professor of organic chemistry at Georgia Southern University, Landge has spent more than a decade inspiring students to soar beyond traditional learning by blending research, mentorship and hands-on experiences that extend far beyond textbooks. That commitment to innovation has earned Landge the Regents’ Scholarship of Teaching and Learning Award, an honor from the University System of Georgia (USG) that recognizes faculty who contribute to the scholarship of teaching and learning through research, leadership and instructional excellence. “Receiving the Regents’ Scholarship of Teaching and Learning Award is a true honor,” said Landge. “It reinforces my passion for teaching and research, inspiring me to strive for excellence every day. My goal is to cultivate an engaging, positive learning environment where students are actively involved and genuinely excited about the learning process.” Landge’s work is grounded in synthetic organic, medicinal and supramolecular chemistry. Her research focuses on developing novel synthetic methodologies with applications in medicinal chemistry and materials science, creating compounds with potential therapeutic properties and supramolecular systems with unique functionalities. “This award is a reflection of Dr. Landge’s deep passion for education and research, and her ability to inspire students to think critically and engage meaningfully with the world around them,” said Provost and Executive Vice President for Academic Affairs Carl Reiber, Ph.D. “At Georgia Southern, we are dedicated to fostering an environment of discovery and innovation, and her work continues to elevate that mission, both in and out of the classroom. We are fortunate to have her as part of our academic community.” This isn’t the first time Landge’s dedication to student engagement and scientific inquiry has garnered recognition. Previously, she earned a University Award of Excellence for Student Success in 2021 and the College of Science and Mathematics Award of Excellence in Research in 2023. “This award is a testament to Dr. Landge’s exceptional contributions to the Scholarship of Teaching and Learning,” said Michael Huggins, Ph.D., dean of the College of Science and Mathematics. “Her innovative approach has not only deepened our understanding of effective teaching but has also led to measurable improvements in student outcomes across the College of Science and Mathematics.” In addition to her research and teaching, Landge has served as a Service-Learning Faculty Fellow (2023-2024) and is a current Research Advocate, reinforcing her commitment to bridging the gap between academic learning and real-world problem-solving. For more information about the Regents’ Scholarship of Teaching and Learning Award, visit : If you're interested in connecting with Shainaz Landge and learning more about her work then let us help - simply contact Georgia Southern's Director of Communications Jennifer Wise at jwise@georgiasouthern.edu to arrange an interview today.
Researchers laying the groundwork to eventually detect cerebral palsy via blood test
At the University of Delaware, molecular biologist Mona Batish in collaboration with Dr. Robert Akins at Nemours Children Hospital, is studying tiny loops in our cells called circular RNAs — once thought to be useless leftovers, but now believed to play an important role in diseases like cancer and cerebral palsy (CP). This is detailed in a new article in the Journal of Biological Chemistry. What are circular RNAs? They’re a special type of RNA that doesn’t make proteins but instead helps control how genes are turned on and off. Because they’re stable and can be found in blood, they may help doctors detect diseases more easily. So what’s the connection to cerebral palsy? CP is the most common physical disability in children, but right now it’s diagnosed only after symptoms appear — there’s no clear-cut test for it. Batish and her team are trying to change that. Working with researchers at Nemours Children’s Health, Batish discovered that in children with CP, a certain circular RNA — circNFIX — is found at much lower levels in muscle cells. This RNA normally helps the body make an important muscle-building protein called MEF2C. When circNFIX is missing or low, MEF2C isn’t made properly, which may lead to the weakened, shorter muscles seen in CP. This is the first time researchers have shown a link between circular RNAs and human muscle development in cerebral palsy. Why does this matter? If scientists can confirm this link, it could lead to: Earlier and more accurate diagnosis of CP using a simple blood test New treatments that help improve muscle development in affected children Batish’s ultimate goal? To create a test that can spot CP at birth — or even before — giving kids a better shot at early treatment and a higher quality of life. To speak to Batish, contact mediarelations@udel.edu.
Humans have long taken inspiration from the natural world. From the indigenous cultures of the world who understand and utilize the properties of plant and animal products, to Leonardo da Vinci’s “flying machine” sketches inspired by his observations of flying birds, humankind has often looked to nature to help solve its problems and drive innovation. With rapid scientific advancements of the 19th and 20th centuries, and the exponential growth of sustainability practices over the last quarter century, the concepts of bio-inspired design and biomimicry have been increasingly pursued across myriad disciplines of study and implementation. Alyssa Stark, PhD, associate professor of biology at Villanova University, is one of the “boots-on-the-ground” researchers in pursuit of nature’s solutions to human problems. She recently took the time to chat with us about these fields, her research interests and the future of biomimicry. Villanova PR: We sometimes hear the terms “bio-inspired design” and “biomimicry” used interchangeably. Are they the same concept? Alyssa Stark: I see those as two different things. Bio-inspired design is when we are looking at an organism and see that it’s doing something that we want to emulate as humans. I work with animals that have unique adhesive properties. I ask questions like: Can we see that? Can we build it? Can we transfer that information, those ideas, those principles – it could be chemistry, physics, biological structure – and make something useful for us? That is also true with biomimicry, but the big difference for me is that we're keeping in mind the sustainability components. The natural world is not polluting. If we're using this biomimicry lens, how do we learn from nature to make products or solve problems in a sustainable way, keeping in mind the specific environment in which we are located? As an example, we wouldn't use a heavy water process if we were in the Arizona desert, instead we should look to our immediate surroundings to solve problems. PR: It seems the work going on in this field really takes a unique level of interdisciplinary collaboration. What types of different professionals are working in biomimicry? AS: It really pulls together biologists, engineers, physicists, chemists, even design artists and businesspeople. I've worked with a lot of different businesses that want to have sustainability in their company at broad levels by using biomimicry. They are not motivated by making a cool product, but realizing it actually saves them money if they think about their whole company in a biomimetic perspective. There are people who work on the social side of biomimicry, helping these companies completely restructure themselves to be more efficient and more time and money sensitive, without ever making a product. But of course, products are a huge part of it, too. And to make that happen, all of those professions, and more, are vital and active in this space. PR: In terms of products, what are some of the most successful examples of biomimetic designs being implemented? AS: A classic one is a building in Africa that doesn't have any air conditioning units because it has a series of vents like a termite mound. Or the bullet train being shaped like a kingfisher’s beak. One scientist found that whales have bumps on their fins, which you might think is not hydrodynamic. But as it turns out, it actually cuts through water more efficiently by creating little vortices. This concept was then applied to wind turbines. There are many examples of biomimicry actually working and being used. My mind is blown when I talk to an artist or designer about biomimicry because it's just wild the way they think. PR: Where does your overall work as a biologist fit into the world of biomimicry? AS: My hard science work is very much functional morphology – shape and structure of things and how they function. That includes behavior and their organismal interaction with the environment. I ask questions like: How do their structures function and perform? How sticky are they? How fast are they? How do they behave in their environment? What happens if they hit different challenges in their environment? My work kind of naturally fits well with biomimicry, especially for product development. I observe the natural world and then I start testing questions and predictions that I have about it, like figuring out how the heck this ant is sticking to this wet leaf. My results can then be applied directly. We have to first understand how these organisms work, and then others can run with it to try to put it to use. PR: What organisms do you work with and what about them are you studying? AS: I mostly study geckos, ants, and sea urchins and I just started working with some coral, looking at why some coral undergo bleaching, and some don’t. With sea urchins, we're also figuring out where their incredibly hard teeth are mineralized so we can understand it enough to try to mimic it. I like playing in that zone, because it still provides me a chance to do the hard science, but also talk to engineers and others and provide them information. With geckos, what I kind of broke open with my PhD thesis was that they have an adhesive that works in wet environments. Having a reusable adhesive that can work on skin, especially in the medical world, is a big problem and where most of my research lies. Think of a bug that you can’t pry off, but then it suddenly runs. How do these organisms move with such sticky feet? Figuring out how to make a reusable adhesive that doesn’t get dirty and can handle all these different environments is a difficult problem to solve. PR: How do you see this field evolving, especially as we strive for a greener, more sustainable future? AS: I would say the next step is the social levels of these big ecosystems. How do we build a city that functions like a rainforest or like a coral reef? Not just a product, but how do we actually shape our world by taking behaviors, processes, or systems that we see in the natural world to help us? Look at a pride of lions and their hierarchy, or what kind of feedback loops are there in an ant colony that allow them to give information back to their colony members quickly and share resources. I think that is the future of this field, and it’s an exciting future. *To learn more about Dr. Stark’s research and the field of biomimicry, click here to listen to a recent episode of NPR’s science show, “The Pulse.”
Maureen Leffler, D.O., Named ChristianaCare’s Chief Wellbeing Officer
Maureen “Mo” Leffler, D.O., MPH, has been appointed chief wellbeing officer of ChristianaCare, effective Nov. 25. In her role, Leffler leads the ChristianaCare Center for WorkLife Wellbeing and strategies to enhance the professional fulfillment and well-being of ChristianaCare’s nearly 14,000 caregivers, overseeing advocacy programs and initiatives to optimize their experience and foster a culture of well-being throughout the organization. She works closely with leaders across key departments to address factors impacting caregiver well-being. Leffler most recently served as the inaugural chief wellbeing officer at Nemours Children’s Health, where she helped the organization to achieve the 2022 Joy in Medicine distinction from the American Medical Association for prioritizing proven efforts to enhance the professional fulfillment of physicians. There, she established a Center for Associate Wellbeing; led the first systemwide assessment to strategically address well-being and burnout; and implemented a peer support program and expanded the scope of resources available to support the emotional and mental health needs of employees. In collaboration with organizational leaders, she supported targeted clinical team assessments and systems-based interventions to foster well-being. Prior to this role, Leffler served as a pediatric rheumatologist at Nemours and as an assistant professor of pediatrics in the Division of Rheumatology at Thomas Jefferson University. Since 2017, Leffler has served as the course director of the Chief Resident Leadership Training Program for the Accreditation Council for Graduate Medical Education (ACGME). In response to the COVID-19 outbreak, she co-chaired ACGME’s National Task Force on Well-Being. She and her team developed a national graduate medical education well-being community, which she continues to convene, to understand the evolving challenges and share strategies to improve well-being. She represents the ACGME as a coach for the National Academy of Medicine Action Collaborative on Clinical Well-Being and Resilience. She also serves as a consultant to the Professional Satisfaction team at the American Medical Association. Leffler earned her medical degree from the Philadelphia College of Osteopathic Medicine, followed by a residency in pediatrics at Nemours and Thomas Jefferson University Hospital, where she served as chief resident. She subsequently trained in pediatric rheumatology at Nemours and Jefferson. She also earned a Master of Public Health from Temple University and studied chemistry at St. Joseph’s University. Recently, Leffler completed the Georgetown Executive Leadership Certification Program.
Innovating (Western) North Carolina
NCInnovation may sound like a catchy name for a craft beer, but it is much more than a name. NCInnovation is a nonprofit organization created to unlock the innovative potential of North Carolina’s world-class public universities. While the state of North Carolina is a well-recognized leader in research and development, the output does not measure up to the state’s size and historically, most of the state’s research efforts have stemmed from the Research Triangle Park. Today, other regions of North Carolina are making a name for themselves with innovative concepts that University of North Carolina System schools are developing through academic-industry partnerships every day. This is where NCInovation steps in — to bridge academia and industry, to move inventions to market and create long-term economic benefits for all regions of the state. This is done by supporting researchers with grant funding, mentorship and partnership development to commercialize applied research breakthroughs and accelerate the transition from the classroom to the production floor. NCInnovation’s focus is on supporting North Carolina public university research that has commercial promise. Four regional networks are located at UNC System campuses in Charlotte, Cullowhee, Greensboro and Greenville. WCU is part of NCInnovation’s Western Regional Network, led by Meagan Coneybeer, regional innovation network director. “We are tech agnostic, which means that we are open to any faculty member here in the western part of the state at our institutions which include WCU, UNC Asheville, North Carolina School of Science and Mathematics Morganton and Appalachian State,” Coneybeer said. The program supports faculty working on industry-led, program-based innovations in partnership with industry or those who are interested in collaborating on large scale regional economic development projects that would be anchored in research, experience and excellence of a university collaboration. As part of the pilot grant funding, Brian Byrd, WCU’s mosquito expert and professor in the environmental health sciences program, along with Scott Huffman, professor in WCU’s Department of Chemistry and Physics, have been approved for grant funding from NCInnovation to continue their work in developing tools that utilize spectroscopy to analyze vibrational signals from mosquitoes. “Using spectroscopy, we are developing tools that analyze chemical signals from mosquitoes to tell us the species, sex, age of the mosquitoes and if they are infected,” Byrd said. “Using our approach, we can rapidly assess the risk of infection in the Aedes mosquitoes that transmit dengue fever and Zika.” Currently, it takes days or weeks to conduct this type of risk assessment, but the approach Byrd and Huffman are developing will make the work much quicker and more efficient. “There is a similar Aedes mosquito in Western North Carolina that transmits La Crosse virus causing encephalitis in children every year,” Byrd said. “This tool gives us a platform to improve risk assessments and opportunities to reduce human disease.” For Huffman, this project hits close to home. “When I was a boy, I almost died from a vector-borne disease,” he said. “This experience impacted me. While I have no skills or ability to address the particular disease that I experienced, working with Brian for the past six years has given me the opportunity to contribute in a small way to the field of pediatric vector-borne diseases. This funding from NCI will help us translate some of our fundamental laboratory research into an applied tool that hopefully will benefit society.” The grant approval is conditioned on standard next steps, including executed grant agreements and formal notification to government partners. The funding is part of NCInnovation’s larger mission to unlock the innovative potential of North Carolina’s world-class universities. “Dr. Byrd and Dr. Huffman’s award from NCI is a testament to the exemplary dedication to teaching and applied research by the outstanding faculty at Western Carolina University,” WCU Chancellor Kelli R. Brown said. “This funding serves as a catalyst for additional innovative exploration by our faculty as we strive to bolster economic condition in Western North Carolina and indeed the entire state. I would like to thank the General Assembly for supporting exciting, applied research underway here at WCU and across the UNC System.” The grant funding from NCInnovation’s larger effort to support the development and commercialization of university research in North Carolina. The campus-to-industry pipeline has been the foundation of American innovation for decades. There is so much applied research happening and this gives us the oppertunity to support that journey to commercialization and to partner with universities to bring successes to market. - Bennet Waters, President and CEO of NCInnovation “We are consistently blown away by the applied research innovations coming out of North Carolina’s public universities,” said Michelle Bolas, NCInnovation executive vice president and chief innovation officer. “Dr. Byrd’s and Dr. Huffman’s work has promising applications throughout the state and country and we’re excited to watch this research continue to develop.” Bennet Waters, president and CEO of NCInnovation; is excited about the opportunities that will stem from these partnerships. “At its core, NCI is a regional economic development opportunity and the concept is to use the existing or potentially applied research from our university campuses and not just those that are in the RTP,” said Waters. “There is so much applied research happening and this gives us the opportunity to support that journey to commercialization and to partner with universities to bring their successes to market. NCInnovation puts boots on the ground to foster these relationships. This is not a Raleigh-centric model; this is about helping folks that live beyond population centers to develop economic opportunities.” The organization received $500 million in state funding as an endowment to accelerate the commercialization of research at universities. NCInnovation will deploy the interest earned on the endowment to provide grant funding and support services to university researchers. By doing so, NCInnovation will support the growth of new businesses and licensing revenue from commercialized research, helping boost economic development in the region. The program supports faculty working on industry-led, program-based innovations in partnership with industry or those who are interested in collaborating on large scale regional economic development projects that would be anchored in research, experience and excellence of a university collaboration. “The partnership between WCU and NCI presents incredible opportunities to promote research-based entrepreneurship, product development and commercialization, and bolsters the likelihood of new job creation in the western portion of the state,” said Rich Price, WCU’s chief marketing and strategic partnerships officer. “The investment potential presented by NCInnovation removes so many barriers to university-led product and concept realization and the creation of intellectual property that will fuel economic growth.” Looking to know more or cover this topic - we can help. Brian Byrd and Scott Huffman are both available to speak with media - simply click on either expert's icon now to arrange an interview today.
Post-Pandemic: How Alcohol Is Harming the Health of More Women
The prevalence of alcohol-related complications has been steadily increasing over the years, but a significant surge occurred during the pandemic, particularly among women aged 40 to 64. According to a JAMA Health Forum report titled High-Acuity Alcohol-Related Complications During the COVID-19 Epidemic, there was a significant increase in severe alcohol-related complications in women and alcoholism. The majority of these, 54% to 66%, were alcohol-related liver disease; smaller numbers, 3% to 5% and 1% to 3% were attributed to alcohol-related cardiomyopathy and alcohol-related gastritis with bleeding, respectively. What the trends mean If these trends persist, the increases in alcohol-related complications will continue to harm women. There are several reasons explaining this increase. In addition to the overall increase in alcohol consumption, the pandemic exacerbated feelings of loneliness and uncertainty about the future. Additionally, lockdowns led to more time spent at home – an environment where alcohol is readily available. How alcohol affects women Women are particularly vulnerable to the adverse effects of alcohol due to differences in body structure and chemistry. They absorb more alcohol and take longer to metabolize it. This means smaller amounts of alcohol can cause more serious health issues. Also, the shift towards drinking at home, which was further made easier by convenient online shopping and home delivery during the pandemic, led to increased consumption without judgment. Addressing any substance misuse needs a multimodal approach. There are treatment options and medications that can help. It is important to wean yourself off alcohol with a doctor’s supervision, as withdrawal can be severe and dangerous. Getting help Health care providers, patients and their loved ones can all partner in enhancing education and awareness about alcohol use risks and reducing stigma in seeking treatment when needed. It’s important for women to recognize that they are not alone and that help is available. It is a difficult addiction for anyone to go through, but education and support can significantly improve outcomes.
Florida Tech, Kennedy Space Center to Study Waste Treatment in Space
Associate professor of chemical engineering Toufiq Reza has spent years researching sustainable waste conversion techniques on Earth. When Florida Tech offered him a sabbatical, he took the chance to learn what that conversion process looks like in outer space while further strengthening the university’s already deep ties to NASA. In Fall 2023, Reza became the first professor to leverage school funding to spend a semester at NASA’s Kennedy Space Center. He worked with Annie Meier, who leads a team developing ways to convert astronaut-generated trash into fuel during missions, known as in-situ resource utilization (ISRU). “I wanted to do something different that I haven’t done. I have been doing research in my field; I know who the players are,” Reza said.” I could have easily gone to a research lab at another university and continued my research. But I wanted to learn something new.” His sabbatical prompted a new partnership between NASA Kennedy and Florida Tech. This summer, they signed an annex to their existing Space Act Agreement which will allow Kennedy Space Center (KSC) and the university to conduct joint research regarding logistical waste treatment and ISRU. “At NASA, we want researchers who are doing something that could help us, that could be synergistic, and to not reinvent the wheel,” said Jose Nuñez, university partnerships and small sat capabilities manager at NASA Kennedy. “The goal is to find professors who can benefit the agency in an area that needs more research.” As part of the agreement, KSC will share raw materials, waste simulant samples and information such as gas composition data with Florida Tech. In return, the university will analyze and share findings, such as what useful products can be taken from trash-to-gas waste for use as plant nutrients, and evaluate value-added applications. “I will encourage students to work on some of their technologies, test them in our lab and vice versa. This is a massive thing,” Reza said. “We can learn from each other to help each other.” Already, Reza’s students have visited Meier’s lab, and Meier and her KSC team came to Florida Tech to present her research and visit the university’s research facilities. Meier’s goals are similar to Reza’s: Both researchers want to find sustainable ways to convert trash and waste into energy, materials and chemicals. However, the methods aren’t completely transferrable between the two different environments of Earth and space. On Earth, Reza explained, waste can be burned or stored in a landfill. Neither of those options are viable in space. “You cannot dig up the moon soil and start burying. There is no oxygen or air to actually burn it…there is no water,” Reza explained. Currently, astronaut waste, such as food packaging, clothing, hygiene items and uneaten food, is launched back towards Earth and incinerates on the way there. However, Meier is working to advance waste mitigation technology, which Reza got to see up close. One of her projects, the Orbital Syngas/Commodity Augmentation Reactor (OSCAR), mixes oxygen, heat and trash in a reactor, which burns the trash and collects the gas it creates. Over the course of the semester, Reza assisted in KSC’s Applied Chemistry Lab, where Meier’s research took place. He offered both expertise and extra hands, from helping measure samples to reading through literature. He also took note of innovative technology for potential new research ideas, such as potentially developing a way of protecting metal coatings in space using the tools he learned. Meier’s waste conversion technology is built for a space environment, but Reza said it is unlikely that her complete systems could be used for waste conversion on Earth. Just as water and oxygen are limited resources in space but are plentiful on Earth, vacuums are plentiful resources in space but are expensive to create back home. However, that doesn’t stop the researchers from seeking inspiration through the new partnership. “We can learn from them and then take a part of their technology and integrate it with ours to make our technology more sustainable and vice versa,” Reza said. “They can improve their technology by utilizing part of our technology as well. As Meier said, “I wanted to learn on the terrestrial side how we can infuse some of our technology, and he wanted to learn from us to grow into the space sector, so it was a really cool match.”
Brian Byrd, Western Carolina University’s mosquito expert and professor in the environmental health sciences program, along with Scott Huffman, professor in WCU’s chemistry and physics program, have been approved for grant funding from NCInnovation to continue their work in developing tools that utilizes spectroscopy to analyze vibrational signals from mosquitoes. “Using spectroscopy, we are developing tools that analyze chemical signals from mosquitoes to tell us the species, sex, age of the mosquitoes and if they are infected,” Byrd said. “Using our approach, we can rapidly assess the risk of infection in the Aedes mosquitoes that transmit dengue fever and Zika. There is a similar Aedes mosquito in Western North Carolina that transmits La Crosse virus causing encephalitis in children every year, so this tool gives us a platform to improve risk assessments and opportunities to reduce human disease.” Currently it takes days or weeks to conduct this type of risk assessment, but the approach Byrd and Huffman are developing will make the work much quicker and more efficient. “Dr. Byrd and Dr. Huffman’s award from NC Innovation is a testament to the exemplary dedication to teaching and applied research by the outstanding faculty at Western Carolina University,” WCU Chancellor Kelli R. Brown said. “We are confident that this announcement will serve as a catalyst for additional innovative exploration by our faculty as we strive to bolster economic condition in Western North Carolina and indeed the entire state. I would like to thank the General Assembly for supporting exciting, applied research underway here at WCU and across the UNC System.” The grant approval is conditioned on standard next steps, including executed grant agreements and formal notification to government partners. This funding is part of NCInnovation’s larger mission to unlock the innovative potential of North Carolina’s worldclass universities. “We are consistently blown away by the applied research innovations coming out of North Carolina’s public universities,” said Michelle Bolas, NCInnovation executive vice president and chief innovation officer. “Dr. Byrd’s and Dr. Huffman’s work has promising applications throughout the state and country and we’re excited to watch this research continue to develop.” NCInnovation helps university innovations advance towards commercialization by supporting university applied research through the critical R&D phase between proof concept and readiness for the private market. The grant funding approved for Byrd is part of NCInnovation’s larger effort to support the development and commercialization of university research in North Carolina. The campus-to-industry pipeline has been the foundation of American innovation for decades. For more information, visit NCInnovation.org. Looking to know more or cover this topic - we can help. Brian Byrd's research focuses on domestic mosquito‐borne diseases, specifically La Crosse encephalitis. He is available to speak with media - simply click on his icon now to arrange an interview today.
Aston University to train the UK’s next generation of decarbonisation experts
Consortium led by the University is to receive almost £11 million to open doctoral training centre Will focus on use of biomass to replace fossil fuels and removal of CO2 “…part of the UK’s biggest-ever investment in engineering and physical sciences doctoral skills”. Aston University is to train the next generation of scientists tasked to remove greenhouse gases from the environment. A consortium led by the University is to receive almost £11 million to open a doctoral training centre which will focus on leading the UK towards net zero. The centre, based at Aston University, will bring together world-leading research expertise and facilities from the University of Nottingham, Queens University Belfast and the University of Warwick and more than 25 industrial partners. The funding has been announced by the UK science, innovation and technology secretary Michelle Donelan. The centre is to receive almost £8 million of government money while the remainder will be made up through match funding and support from industry and the four universities. The government has described it as part of the UK’s biggest-ever investment in engineering and physical sciences doctoral skills, totalling more than £1 billion. The Aston University centre will focus on the use of biomass to replace fossil fuels and removal (or capture) of CO2 from the atmosphere, with the potential to create new sources of fuels and chemicals. Integration of these two areas will lead to significant cost and energy savings. Called NET2Zero, the centre will train PhD students across the full range of engineered greenhouse gas removal techniques including direct air capture, CO2 utilisation (including chemical and material synthesis), biomass to energy with carbon capture and storage, and biochar. The students will work in the centre’s laboratories exploring the conversion of feedstock into alternative energy, improving conversion processes and measuring how the new technologies will impact the economy. Supported by a range of relevant industrial, academic and policy partners the centre will equip students to develop the broad range of skills essential for future leaders in decarbonisation. NET2Zero will be led by Professor Patricia Thornley, director of Aston University’s Energy and Bioproducts Research Institute (EBRI). She said: “I am delighted that this centre for doctoral training has been funded. The climate emergency is so stark that we can no longer rely on demand reduction and renewables to meet our decarbonisation targets. “If we are to have greenhouse gas removal options ready in time to be usefully deployed, we need to start now to expand our knowledge and explore the reality of how these can be deployed. This partnership of four leading UK universities with key industrial and policy partners will significantly augment the UK’s ability to deliver on its climate ambitions.” “We are absolutely delighted to be working with our partners to deliver this unique and exciting programme to train the technology leaders of the future. Our students will deliver research outcomes that are urgently needed and only made possible by combining the expertise and resources of all the centre’s academic and industry partners.” Science and technology secretary, Michelle Donelan, said: “As innovators across the world break new ground faster than ever, it is vital that government, business and academia invests in ambitious UK talent, giving them the tools to pioneer new discoveries that benefit all our lives while creating new jobs and growing the economy. “By targeting critical technologies including artificial intelligence and future telecoms, we are supporting world class universities across the UK to build the skills base we need to unleash the potential of future tech and maintain our country’s reputation as a hub of cutting-edge research and development.” Centres for doctoral training have a significant reputation in training future UK academics, industrialists and innovators who have gone on to develop the latest technologies. The University of Nottingham’s Dr Eleanor Binner said: “We are absolutely delighted to be working with our partners to deliver this unique and exciting programme to train the technology leaders of the future. Our students will deliver research outcomes that are urgently needed and only made possible by combining the expertise and resources of all the Centre’s academic and industry partners.” Her colleague Professor Hao Liu added: “We look forward to providing our best support to the NET2Zero CDT, including using our past and existing successful experience in leading other centres, to make this an exemplar.” Overall, there will be 65 new Engineering and Physical Sciences Research Council (EPSRC) centres for doctoral training which will support leading research in areas of national importance including the critical technologies AI, quantum technologies, semiconductors, telecoms and engineering biology. The funding is from a combination of £500 million from UK Research and Innovation and the Ministry of Defence, plus a further £590 million from universities and business partners. Notes to Editors EPSRC and BBSRC Centre for Doctoral Training in Negative Emission Technologies for Net Zero (NET2ZERO) Led by: Professor Patricia Thornley, Aston University The Engineering and Physical Sciences Research Council (EPSRC) is the main funding body for engineering and physical sciences research in the UK. Our portfolio covers a vast range of fields from digital technologies to clean energy, manufacturing to mathematics, advanced materials to chemistry. EPSRC invests in world-leading research and skills, advancing knowledge and delivering a sustainable, resilient and prosperous UK. We support new ideas and transformative technologies which are the foundations of innovation, improving our economy, environment and society. Working in partnership and co-investing with industry, we deliver against national and global priorities. The Biotechnology and Biological Sciences Research Council (BBSRC) invests in world-class bioscience research and training on behalf of the UK public. Our aim is to further scientific knowledge, to promote economic growth, wealth and job creation and to improve quality of life in the UK and beyond. Funded by government, BBSRC invested £451 million in world-class bioscience in 2019-20. We support research and training in universities and strategically funded institutes. BBSRC research and the people we fund are helping society to meet major challenges, including food security, green energy and healthier, longer lives. Our investments underpin important UK economic sectors, such as farming, food, industrial biotechnology and pharmaceuticals. About Centres for Doctoral Training A CDT trains doctoral students with each centre focused on a specific theme or topic. Most CDTs will support five cohorts (a new cohort starting each academic year) with a cohort supporting an average of thirteen students. Fourteen of the centres will have four cohorts rather than five. EPSRC supports doctoral students through three training routes (Doctoral Training Partnerships, ICASE awards and CDTs), and in the last 30 years has supported over 50,000 doctoral students. About Aston University For over a century, Aston University’s enduring purpose has been to make our world a better place through education, research and innovation, by enabling our students to succeed in work and life, and by supporting our communities to thrive economically, socially and culturally. Aston University’s history has been intertwined with the history of Birmingham, a remarkable city that once was the heartland of the Industrial Revolution and the manufacturing powerhouse of the world. Born out of the First Industrial Revolution, Aston University has a proud and distinct heritage dating back to our formation as the School of Metallurgy in 1875, the first UK College of Technology in 1951, gaining university status by Royal Charter in 1966, and becoming The Guardian University of the Year in 2020. Building on our outstanding past, we are now defining our place and role in the Fourth Industrial Revolution (and beyond) within a rapidly changing world. For media inquiries in relation to this release, contact Nicola Jones, Press and Communications Manager, on (+44) 7825 342091 or email: n.jones6@aston.ac.uk
Image shows how tiny water channels control how water enters and exits cells through their membranes The Aston Institute for Membrane Excellence (AIME) will be set up with a £10m grant from Research England AIME will be led by Professor Roslyn Bill from Biosciences and Professor Paul Topham from Chemical Engineering and Applied Chemistry The globally unique institute will use biomimetic polymer membranes for applications such as water purification and drug development Aston University will establish the Aston Institute for Membrane Excellence (AIME), a globally unique, cross-disciplinary institute to develop novel biomimetic membranes, after receiving a major grant of £10m from Research England. AIME will be led by Professor Roslyn Bill, from the School of Biosciences, with co-lead Professor Paul Topham from the department of Chemical Engineering and Applied Chemistry (CEAC). Membranes, both biological and synthetic, are hugely important in many sectors. For example, the world’s top ten selling human medicines all target proteins in biological membranes, while synthetic polymer membranes are used in the US$100bn/year water purification industry. The team behind AIME believes that the full potential of membranes will only be realised by an interdisciplinary group spanning biology, physics and chemistry that can investigate membranes holistically. Professor Bill, a European Research Council (ERC) Advanced grantee leads Aston Membrane Proteins and Lipids (AMPL) research centre of excellence that studies the structure and function of membrane proteins and associated lipids. Professor Topham leads Aston Polymer Research Group (APRG), which investigates the nanoscale behaviour of block copolymers (a type of polymer with a structure made of more than one type of polymer molecule) and polymer technologies for membranes. AMPL and APRG have already begun collaborative research and AIME will bring together the complementary expertise of both research clusters into one institute. AIME will initially comprise the eight researchers from AMPL and APRG. Alongside the co-leads Professor Bill and Professor Topham, will be Dr Alan Goddard, Professor Andrew Devitt, Professor Corinne Spickett, Dr Alice Rothnie, Dr Matt Derry and Dr Alfred Fernandez. It plans to recruit three further academics, six tenure-track research fellows, three postdoctoral research assistants (PDRAs), six PhD students, a research technician and a business development manager. Importantly, AIME will work with many existing Aston University colleagues to build a comprehensive research community focused on all aspects of membrane science. The new AIME team will focus on the development of bioinspired, highly selective polymer structures for applications in water purification and waste remediation, nanoparticles loaded with therapeutic molecules to treat disorders ranging from chronic wounds to neurological injuries, and the purification of individual membrane proteins with polymers to study them as drug targets. The vision is for AIME to become a ‘one-stop shop’ for interdisciplinary, translational membrane research through its facilities access and expertise, ideally located in the heart of the country. Professor Bill said: “The creation of AIME is ground-breaking. Together with Aston’s investment, E3 funding will deliver a step-change in scale and the rate at which we can grow capacity. We will address intractable scientific challenges in health, disease, and biotechnology, combining our world-class expertise in polymer chemistry and membrane biology to study membranes holistically. The excellence of our science, alongside recent growth in collaborative successes means we have a unique opportunity to deliver AIME’s ambitious and inclusive vision.” Professor Topham said: “We are really excited by this fantastic opportunity to work more closely with our expert colleagues in Biosciences to create advanced technology to address real world problems. From our side, we are interested in molecular engineering, where we control the molecular structure of new materials to manipulate their properties to do the things that we want! Moreover, we are passionate about a fully sustainable future for our planet, and this investment will enable us to develop technological solutions in a sustainable or ‘green’ way.” Professor Aleks Subic, Vice-Chancellor and Chief Executive of Aston University, says: “Our new Aston Institute for Membrane Excellence (AIME) will be a regional, national, and international research leader in membrane science, driving game-changing research and innovation that will produce a pipeline of high-quality research outcomes leading to socioeconomic impact, develop future global research leaders, create advanced tech spinout companies and high value-added jobs for Birmingham and the West Midlands region. Its establishment aligns perfectly with our 2030 strategy that positions Aston University as a leading university of science, technology and enterprise.” Steven Heales, Policy Manager (Innovation) at the West Midlands Combined Authority, said: “WMCA is delighted to see Research England back the Aston Institute for Membrane Excellence. This will enable Aston University’s excellent academics and research community to work closely with businesses to make advances in membrane technology and applications. “In 2023 the West Midlands Combined Authority agreed a Deeper Devolution Trailblazer Deal with Government, which included a new strategic innovation partnership with Government. Projects like AIME are exactly the kind of impact we expect this new partnership to generate, so watch this space.” Lisa Smith, chief executive of Midlands Mindforge, the patient capital investment company formed by eight Midlands research-intensive universities including Aston University, said: “This grant is an important vote of confidence in the Midlands scientific R&D ecosystem. AIME will play an important role in the future research of pioneering breakthroughs in membrane science and enable the world-leading research team at Aston University to develop solutions to real world problems. We look forward to closely working with the Institute and nurturing best-in-field research being undertaken at Aston out of the lab and into the wider society so it can make a positive impact”. Rob Valentine, regional director of Bruntwood SciTech, the UK’s leading developer of city-wide innovation ecosystems and specialist environments and a strategic partner in Birmingham Innovation Quarter, said: "As a proud supporter of the Aston Institute for Membrane Excellence (AIME), I am thrilled at the launch of this groundbreaking initiative. AIME exemplifies Aston University's commitment to advancing cutting-edge interdisciplinary research and further raises the profile of the region’s exemplary research capabilities and sector specialisms. AIME's vision of becoming a 'one-stop shop' for translational membrane research, strategically located at the heart of the country, aligns perfectly with our strategy at Bruntwood SciTech. We are committed to working with partners, including Aston University, to develop a globally significant innovation district at the heart of the UK where the brightest minds and most inspiring spaces will foster tomorrow’s innovation.” Membrane research at Aston University has also recently received two other grants. In November 2023, Professor Bill received £196,648 from the Biotechnology and Biological Sciences Research Council’s Pioneer Awards Scheme to understand how tiny membrane water channels in brain cells keep brains healthy. In December 2023, a team led by AIME team-member Dr Derry received £165,999 from the Engineering and Physical Sciences Research Council to develop biomimetic membranes for water purification. For more information about AIME, visit the webpage.
