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Batter Up! Major League Baseball Season Begins Tomorrow! | Media Advisory
The start of the Major League Baseball season is more than just America's favorite pastime returning; it's a cultural event that ties into themes of community, nostalgia, and the ever-evolving narrative of sports in society. Like every big league, the start of the season speaks to the unity and division that sports can create, the economics of professional leagues, and the role of athletes in social movements. Possible story angles include: The economic impact of MLB on local communities Innovations in sports technology and data analytics The role of sports in bridging cultural divides MLB's response to social justice issues Health and safety protocols in professional sports Gambling, is it a growing problem for athletes? Connect with an Expert about Major League Baseball For journalists seeking research or insights for their coverage about the MLB and the economics behind professional baseball, here is a select list of experts from our database. To search our full list of experts visit www.expertfile.com Curt Smith Senior Lecturer – University of Rochester Christina Gipson Assistant Professor of Sport Management – Georgia Southern University Greg Stewart, MD W. Kennon McWilliams Professor of Sports Medicine – Tulane University Photo Credit: Michael Lewis Professor of Marketing; Faculty Director, Emory Marketing Analytics Center · Emory University, Goizueta Business School Lisa Pike Masteralexis Senior Associate Dean and Professor of Sport Management – University of Massachusetts Amherst Photo Credit: Joshua Peacock
Research finds video games improve mobility for children with autism
University of Delaware professor Anjana Bhat has a long history of finding creative ways to keep autistic children engaged with the added benefit of improving their flexibility and gross motor skills. She’s used dance and play in the past but is now testing video games to see if they’re a viable intervention to promote movement in this population. Bhat and her team in the Move to 2 Learn Innovation Lab at UD's STAR Campus have been using Ring Fit on Nintendo Switch to help children with autism get their daily dose of exercise. “Children love video games, and they’re fun,” said Bhat, professor of physical therapy in UD's College of Health Sciences. “But there’s also a lot of evidence that video games with an exercise component have positive effects on cognition, social interactions and general physical activity levels.” She added that children with autism have a predilection for technology with a love of computers and robots, but exergaming hasn’t been studied in this population. “Technologies that have been tested and studied in children with autism mainly target sedentary functions that look at improvement in executive function and decision-making, but not necessarily exergaming,” Bhat said. “Exergaming has been studied in older populations and healthy children, but not so much in children with autism, so this study is unique.” After testing the intervention on a dozen children with autism over eight weeks, the consensus is that it works. “I’ve never seen anything grab their attention so much. Across the board, this tool is far more engaging than any other tool we’ve used before, including music and movement, yoga, general exercise, and outdoor play, which do not always work for every child,” Bhat said. “With exergaming and the variety of content that exists, most children remain engaged, and that’s what’s so unusual about this intervention compared to past interventions.” Games like tennis, volleyball, badminton, golf, sword fighting and bowling focus on the upper extremities, while soccer focuses on the lower extremities. Bhat receives accurate measures of improvement in a child’s ability through accelerometers in the video game controllers. “This is one place where children with autism shine,” Bhat said. “Their visual learning and sensory enhancements help them excel. This gives them a sense of self-efficacy and self-assurance that — they’re good at this,” she said. “It also gives them a sense of connection to the community because they can make friends and feel empowered. Video games are a great equalizer.” Bhat’s innovative pilot study was funded through a $50,000 award from the donor-created Maggie E. Neumann Health Sciences Research Fund, which targets research and innovation that aims to improve the lives of people with disabilities. Equipped with data from this study, Bhat hopes to expand access to the intervention and test it in the community. It’s already available at D-Fit Plus, an inclusive fitness center in New Castle that aims to help those with special needs explore fitness to build social skills and confidence, grow cognition, and manage stress. “It’s relatively low cost,” Bhat said. “Another advantage of this intervention is that you don’t need a highly skilled person present to work the intervention because the game leads the activity, making it accessible if embedded in the community.” This also provides a social outlet for the child’s parents. “Community settings bring a sense of connection for the child’s parents, who are always looking for community-based activities, and many environments aren’t suitable for children with autism,” Bhat said. “Many environments are too noisy or distracting. Exergaming removes those barriers and allows the child to engage with the game and maybe another partner.” Bhat’s previously published research has shown that 80% of people with autism face motor challenges. Her research is so compelling that she’s made a case to change the definition of autism to include motor impairments so those on the spectrum can get the proper physical therapy or gross motor interventions that could dramatically improve their quality of life.
How Vulnerable Are America’s Water Systems to Outside Attack? | Media Advisory
The security of America's water systems is an issue of national importance, touching on the well-being and safety of millions. This topic gains urgency as it ties into broader concerns about infrastructure vulnerability, cyber-terrorism, and the readiness of public utilities to handle emerging threats. In light of recent breaches and heightened geopolitical tensions, the resilience of these essential systems is not just a matter of public safety but also of national security. Exploring this issue offers insights into: Cybersecurity measures for water supply systems The impact of climate change on water system resilience Federal and state responses to infrastructure threats Public health implications of water system breaches The role of technology in safeguarding against attacks Connect with an Expert about the Security of America's Water Systems For journalists seeking research or insights for their coverage about the Security of America's Water Systems, here is a select list of experts from our database. To search our full list of experts, visit www.expertfile.com Seth Hamman Director, Center for the Advancement of Cybersecurity and Associate Professor of Cyber Operations and Computer Science - Cedarville University David Bader Distinguished Professor, Data Science · New Jersey Institute of Technology Vladlena Benson Professor of Cybersecurity Management · Aston University William Hatcher Chair of the Department of Social Sciences · Augusta University TJ O’Connor, LTC (Ret.) Assistant Professor, Cybersecurity Program Chair | Computer Engineering and Sciences · Florida Tech Photo by: Adi Goldstein
Aston University and medicine manufacturer Catalent formed a Knowledge Transfer Partnership to identify more effective formulation additives The new selection matrix makes choosing the right additive quicker and the medicine development process shorter The project has been rated as ‘outstanding’ by Innovate UK A partnership between Aston University and contract medicine manufacturer Catalent has led to a faster process to identify the best ingredients for optimal medicine formulations, and has been rated as outstanding by Innovate UK. Catalent is a global leader in enabling pharma, biotechnology and consumer health partners to optimise product development, launch and full life-cycle supply for patients around the world. Its proprietary Zydis orally dissolving tablet (ODT) technology enables the absorption of drugs or active pharmaceutical ingredients (APIs) through the mouth tissues, which is much faster than absorption through the gut. However, many APIs have poor pre-gastric absorption and need to be combined with suitable excipients, or additives, to bind the active ingredients and speed up the process of dissolving and absorbing via the pre-gastric route. Identifying suitable excipients for the formulation is difficult, and so the Knowledge Transfer Partnership (KTP) between Aston University and Catalent was set up to develop a faster, more efficient approach. A KTP is a three-way collaboration between a business, an academic partner and a highly qualified researcher, known as a KTP associate. The UK-wide programme helps businesses to improve their competitiveness and productivity through the better use of knowledge, technology and skills. Aston University is a sector leading KTP provider, with 80% of its completed projects being graded as very good or outstanding by Innovate UK, the national body. The project was led by Aston University’s Afzal Mohammed, professor of pharmaceutics in the School of Pharmacy and associate dean (impact and knowledge exchange) for the College of Health and Life Sciences, who has expertise in the design and optimisation of orally dissolving tablet formulation. He was supported by other colleagues from Aston Pharmacy School including Dr Daniel Kirby, whose main area of research is the formulation of age-appropriate medicines for the extremes of life, Dr Affiong Iyire, who has research expertise in mucosal drug delivery, and Dr Raj Badhan, who is a pharmacokinetics expert with research interests in analytical approaches to predict oral drug absorption. Dr Ruba Bnyan, who has a master’s degree and a PhD in pharmaceutical drug formulation, as well as experience in cell-based models, was the KTP associate for the project. The KTP partners developed a selection matrix, whereby, based on the API properties, Catalent formulation scientists can quickly identify excipients that will improve the absorption of the drug through the mouth. Adopting this novel tool allows for quicker and more efficient drug development and has the potential to increase the number of Zydis ODT candidates in the pipeline for future development. Desmond Wong, product development supervisor at Catalent, said: “This project has exceeded our initial expectations and has the potential to accelerate product development for our clients. Our strong relationship with the Aston University team on this KTP project highlights the transformative potential of collaborative research and its impact on pharmaceutical innovation.” Professor Mohammed said: “This has been a very successful project, which has been rated as ‘outstanding’ by Innovate UK. We plan to put it forward for a KTP award and are looking forward to continuing working with Catalent on our next KTP project.” For more information on the KTP visit the webpage.
#Expert Q&A: NJIT’s Donghee Yvette Wohn Weighs the Pros and Cons of Kids Playing Esports
Donghee Yvette Wohn, an associate professor at New Jersey Institute of Technology and director of its Social Interaction Lab, focuses on human computer interaction, where she studies the characteristics and consequences of social interactions in online environments such as social media, live streaming, virtual worlds (metaverse) and esports. Here she explains the appeal of esports among children in particular and how their parents can assess what’s appropriate for them. How would you describe the current landscape of esports? Esports is an umbrella term that is used for competitive computer gaming that usually, but not always, happens in teams. However, similar to books or movies, the content of the games vastly differs. Some games are very violent, some are not. Some have very realistic graphics, some are very fantasy-like and playful. It is thus hard, especially as a parent, to make blanket decisions when it comes to esports, you may have to take things case by case. So, then how can parents assess what’s appropriate for their children? A quick online search into the nature of the game to see its description or even watching ten minutes of what the gameplay looks like on YouTube or Twitch — where many people upload videos of gameplay — will give parents a better idea of what the game is like without having to play it themselves. What about in terms of the other players? It may be useful to use physical sports or any other extracurricular activity as a mental reference when thinking of how to deal with certain issues. For example, soccer is a sport that is great for socializing and team building, but if one is placing a 10-year-old in a game with other adults, there would be a lot of extra things one would want to consider. Like any social activity, one would want to be mindful of who the child is playing with, how much they are playing and how they are playing. For example, are they being respectful? And what kind of language is being used during the game? What skills could esports and similar gaming help children develop? Based on research, the collaboration and communication skills required to play successfully are extremely high. Even though people do not associate computer games as being a physical skill, the dexterity and hand-eye coordination required to play well require a very high level of intellect and physical ability. Of course, not everyone plays that well, but it does indicate that esports is a little different than some games that are more “mindless” or “relaxing” in nature. What about social skills? It strengthens existing friendships and can also open up one’s world by conversing with strangers. My colleagues and I did a research study where we found a student living in a rural area where most people did not go to college who wanted to go college because he was inspired by the older college students he was playing with. Playing the game in supportive environments can be mentally and socially beneficial. What are the downsides? Like any social situation, there is always the possibility of people misbehaving. The types of harassment documented in gaming environments is so horrible, but the reality is that children are exposed to all types of horrible situations — both online and offline — and helping them navigate difficult situations can help build resilience for the future. What’s a common misconception among parents? The most important thing is to understand that whatever happens in esports is not to be dismissed as something that is “only online” or “not real.” The emotions that children experience in the virtual world are very much real. How much parental supervision is needed? Younger children’s brains have not yet developed self-constraint, so the parent should decide how much time should be spent playing games, what games are played and who they are played with. Older children — once they start understanding logic — should be encouraged to plan these things for themselves. Looking to know more? We can help. Yvette Wohn is available to discuss esports and kids with media. Simply click on her icon to arrange an interview.
#Expert Q&A: NJIT’s David Bader on AI, Data Science, Quantum Computing
Artificial intelligence, data science and the emerging field of quantum computing are among the hottest research topics in computing today. David Bader, a distinguished professor at New Jersey Institute of Technology’s Ying Wu College of Computing and the director of the university’s Institute for Data Science, offers his take on each. The Computer History Museum has recognized you for developing a Linux supercomputer using commodity hardware. Was that a life-shaping lesson? It was a venture into the unknown, leveraging the emerging potential of Linux and commodity hardware to build something that was both accessible and powerful. This experience taught me the importance of embracing risk and the value of resilience. There were technical hurdles, skepticism from peers and the daunting task of venturing beyond established norms. Also, the Linux supercomputer project was not just about the technology. It was about building a community around an idea. How do user-friendly AI systems like ChatGPT impact your work? It enriches the palette of methodologies and technologies at our disposal, enabling us to tackle more ambitious projects with greater efficiency and creativity. By integrating these AI systems into our research and educational programs, we're not just enhancing our ability to process and analyze data. We're also empowering students and researchers with the means to innovate and explore new horizons in data science without being hindered by the technical complexities that once acted as barriers. Some information workers fear that AI will make their careers obsolete. But tech progress can’t be stopped, so how should people adapt? By embracing these technologies, learning to work alongside them and leveraging their capabilities to enhance our own skill sets and productivity. Also, it's important to focus on the uniquely human skills that AI cannot replicate, such as creativity, emotional intelligence and critical thinking. By honing these abilities, workers can ensure they remain irreplaceable components of the workforce, capable of tasks that require a human touch — from complex decision-making to empathetic interactions with customers or clients. What should non-programmers learn about AI? It’s important to be aware of how AI decisions are made, the potential biases in AI systems and the ethical considerations of AI use. Additionally, developing data literacy is crucial, as it enables individuals to evaluate AI outputs and understand the importance of data quality and biases. A basic grasp of AI and machine learning concepts — even without programming skills — can demystify AI technologies and reveal their potential applications. Staying informed about AI advancements across various sectors can also inspire innovative ideas and foster interdisciplinary collaborations. There’s a sci-fi plot where computers get so smart that people lose control. The new class of user-friendly AI is making people excited but also nervous. Should we be afraid? While it’s natural to harbor concerns about the rapid progression of AI, allowing fear to dominate the discourse would be a disservice to the potential benefits these technologies can offer. Instead, this moment calls for proactive engagement with AI and an investment in understanding its inner workings, limitations and the ethical dilemmas it presents. By advocating for responsible AI development, emphasizing education and promoting transparency, we can foster an environment where AI serves as a tool for societal advancement. This approach ensures that we remain at the helm of AI's trajectory, steering it toward outcomes that uplift humanity rather than scenarios that fuel dystopian fears. What other emerging technologies excite you in their potential to transform computing? Quantum computing. This technology, with its potential to solve complex problems exponentially faster than classical computers, could revolutionize fields ranging from cryptography to drug discovery, climate modeling and beyond. Quantum computing's promise to tackle challenges currently beyond our reach, due to its fundamentally different approach to processing information, represents a leap forward in our computational capabilities. Its convergence with AI could lead to unprecedented advancements, making this era an incredibly thrilling time to be at the forefront of computing and data science. Looking to know more? We can help. David Bader is available to discuss AI, quantum computing and data science with media. Simply click on his icon to arrange an interview.
The digits of pi are infinite. It’s an irrational number—one whose decimal never ends and never repeats. Over time, with brilliant minds and brilliant technology, humans have been able to calculate its digits further and further, now forming a 100-trillion decimal tail. In many ways, the infinitely long decimal expansion of pi is a metaphor for its limitless applicable value. With new ways of thinking, measuring and computing, the significance of pi has permeated throughout the study and use of mathematics and countless other disciplines. Pi is a mathematical constant by definition and also because of its ubiquity. “To offer an Augustinian-themed analogy, pi is to mathematics as Gregor Mendel’s peas are to biology,” said Katie Haymaker, PhD, associate professor of mathematics and statistics at Villanova University. “At first glance, Mendel’s experiments convey some basic understanding of the function of genetics. However, the way genes are expressed is incredibly complicated, and scientists continue to study genetics and gene therapies today. Similarly, mathematicians today study objects that are historically tied to the development of ideas inspired by explorations of pi. Pi is one gateway to a garden of mathematical possibilities.” Dr. Haymaker currently teaches a course called “Mathematics for Human Flourishing,” inspired by the Francis Su book of the same title. Her class discusses math in everyday life and how engaging in mathematical exploration can develop virtues like studying ethics or other humanities can and also expand quality of life. “I don’t have class this Pi Day, but usually I would share a little something about pi if I did,” she said. So, what exactly is pi? The easy answer is that it’s the ratio of the circumference (the length all the way round) to the diameter (the length across) for any circle. “If you measure across a circle with a piece of rope, how many pieces of the same rope would you need to measure around?” Dr. Haymaker explained. The never-ending answer starts with 3.14, hence the common celebration of Pi Day on March 14. This value has been studied for millennia: The ancient Egyptian Rhind Papyrus, dating to around 1650 BCE, offers a very close estimation for pi as 3.16049. Even the Bible, in 1 Kings 7:23, a circular vessel is described, and the ratio of circumference to diameter calculated to exactly three. “There are interesting explorations by biblical scholars about why this number is not exactly the value that we now know as pi, including that the brim around the vessel accounts for the discrepancy,” Dr. Haymaker said. Over time, novel methods for approximating pi were discovered, advancing humankind’s understanding of its value, and leading to various other paths of mathematical study. The famous Greek mathematician and inventor Archimedes, for instance, discovered a way to approximate pi’s value by use of a regular polygon (a closed geometric figure made of equal straight lines and angles). In those times, measuring a circle was not well defined, according to Dr. Haymaker. By placing the regular polygon inside the circle, the straight lines can be measured, those straight lines can be split to form a regular polygon with more measurable sides, and so forth. The more sides, the closer the measurement is to the true circumference of the circle. “That whole idea of approximating to the actual value is the main idea of calculus,” she said. “This notion by Archimedes predated that entire field.” Later, formulas were developed that surpassed Archimedes’ technique. A better approximation of pi was discovered around the year 450 by Chinese mathematician Tsu Ch’ung-chih, arriving at the easy-to-remember fraction 355/113. “This is one rational approximation to pi, and it’s also a fun Pi Day party trick because it’s the best approximation you can get with a fraction like this whose denominator is less than 10,000,” Dr. Haymaker said. These are just two examples of the many contributions made to advance the understanding of pi. Even the use of the Greek symbol to describe the ratio, which was popularized by 18th-century mathematician Leonhard Euler, was instrumental. Prior to that, there had been no agreed-upon symbol and the concept was often described using only words. In the thousands of years since the first recorded approximation of pi, the methods of its approximation—and pi itself—have been applied to multiple other fields of mathematical study such as trigonometry and calculus. For Dr. Haymaker, pi was important in the development of her own understanding of mathematics as well. “I have learned to expect the unexpected when it comes to pi,” she said. “It shows up in all sorts of places and it inspires us to dig deeper into why.” Today, pi can be calculated to 100-trillion decimal places (though only a dozen or so are needed for even the most accurate applications). On Pi Day 2023, 21-year-old Rajveer Meena memorized the first 70,000 digits, breaking a Guiness World Record in a mind-boggling 10-hour recitation. “I think that pi is fascinating to people because its digits behave in a random way and they go on forever,” Dr. Haymaker said. “If there is a string of numbers that is special to you—take 1842 for example—it exists somewhere in the digits of pi. In exploring pi, it feels like you are exploring the infinite, which naturally inspires mystical feelings about the number.” By the way, the string of numbers 1842 (the year Villanova was founded) appears at position 1738 counting from the first number after the decimal, according to the Pi-Search Page. So, whether it’s on March 14, July 22 (because the fraction 22/7 is a rational approximation of pi) or whenever you might celebrate, look down at that beautiful circular dessert you will cut into and think about “why pi(e)?” “Some people may scoff at Pi Day as being separate from ‘real’ mathematics,” Dr. Haymaker said. “But there is a joyfulness in celebrating this day that represents a deep connection that people have to mathematical discovery. After all, a person wrote the Rhind Papyrus, and it is people who program the computers that searched for the 100 trillionth digit of pi. This quest to understand is a deeply human endeavor. “To quote Francis Su, ‘the pursuit of math can, if grounded in human desires, build aspects of character and habits of mind that will allow you to live a more fully human life and experience the best of what life has to offer.’ So, if eating pie and other round foods on March 14 inspires someone to learn, ask questions, pursue answers and see themselves as an explorer of mathematics, then it is indeed a day to celebrate.”
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
Municipalities around the world have invested significant resources to develop connected smart cities that use the Internet of Things (IoT) to improve sustainability, safety and efficiency. With this increased demand for IoT experience, the VCU College of Engineering formed the OpenCyberCity testbed in 2022. The 1:12 scale model city provides a realistic, small-scale cityscape where students and researchers can experiment with new and existing smart city technology. Sherif Abdelwahed, Ph.D., electrical and computer engineering professor, is director of OpenCyberCity. He recently answered some questions about new developments within the testbed. The OpenCyberCity is a smart city testbed, but are there any real-life cities that one could call a smart city? Several real-life locales are considered smart cities due to their extensive use of technology and data-driven initiatives to optimize infrastructure and services. Dubai is one of the most notable. They have implemented smart transportation systems, buildings and artificial intelligence to transform the city’s operations and make them more efficient. Other reputable smart cities include Singapore and Seoul, which utilize smart energy management, smart transportation and comprehensive data analytics for improved urban planning and services. Seoul, in particular, has an initiative with smart grids and connected street lights, which VCU Engineering’s own OpenCyberCity test bed is working to implement. How does the OpenCyberCity address privacy? With so much technology related to monitoring, how are individual citizens protected from these technologies? Privacy is a major concern for smart cities and it is one of the main research directions for VCU Engineering’s OpenCyberCity. We are developing several techniques to prevent unwanted surveillance of personal information. Sensitive data is protected by solid protocols and access restrictions that only allow authorized users to view the data. Our aim is to find a reasonable middle ground between technological progress and privacy rights, staying within legal and ethical bounds. Some techniques to address privacy concerns include: Data Anonymization: This makes it difficult to trace back information to individual identities. Within the testbed, we will evaluate how to protect individual privacy while maintaining data utility and assess the impact on data quality. Secure Data Storage and Transmission: Encrypt data to protect it from unauthorized access. In the smart city testbed, these access control mechanisms will be implemented within the testbed’s infrastructure. We will also test different data handling processes and access control models to determine their ability to safeguard sensitive data. Privacy Impact Assessments: Regularly evaluate potential privacy risks of new smart city projects in order to mitigate them and ensure the ethical handling of data by those with access. Policy and Regulation Development: Data and insights generated from OpenCyberCity experiments can inform the development of cybersecurity policies and regulations for smart cities. How is the College of Engineering’s OpenCyberCity test bed different from similar programs at other institutions? While other universities have similar smart-city-style programs, each has their own specialty. The VCU College of Engineering’s OpenCyberCity test bed focuses on real-world contexts, creating a physical space where new technologies, infrastructure, energy-efficient transportation and other smart city services can be tested in a controlled environment. Our lab monitors real-time data and develops smart buildings, smart hospitals and smart manufacturing buildings to enhance the city’s technologies. Recent additions to the OpenCyberCity allow for expanded research opportunities like: Advanced Manufacturing: Students can apply advanced manufacturing techniques in a controlled environment. They can also test new materials, processes and automation technologies to improve efficiency and product quality. Energy Efficiency Testing: Environmental engineers and sustainability experts can evaluate energy consumption patterns within the smart manufacturing unit to implement energy-saving measures and assess their impact on sustainability. Production Optimization: Manufacturers can use real-time data from the smart manufacturing unit to optimize production schedules, minimize downtime and reduce waste. Predictive maintenance algorithms also help prevent equipment breakdowns. Education and Training: Hands-on experience with state-of-the-art manufacturing technologies helps train the workforce of the future. Integration with Smart City Services: Data generated by the manufacturing unit can be integrated with smart city services. For example, production data can inform supply chain management and energy consumption data can contribute to overall city energy efficiency initiatives. How has the OpenCyberCity changed in the last year? Is the main focus still data security? What started with research examining, analyzing and evaluating the security of next-generation (NextG) applications, smart city operations and medical devices has expanded. Data security is now only one aspect of OpenCyberCity. Its scope has grown to encompass more expansive facets of cybersecurity like automation and data analytics in the domain of smart manufacturing systems. The implementation of a smart manufacturing system in 2023 is something students really enjoy. Thanks to the vendor we used, undergraduate students had the option to develop functionality for various features of the manufacturing plant. Graduate students were also able to research communications protocols and cybersecurity within the smart manufacturing system. What does the smart manufacturing system entail and what kind of work is occurring within that system? An automated system is there for students to work with. Robot arms, microcontrollers, conveyor belts, ramps, cameras and blocks to represent cargo form an environment that emulates a real manufacturing setting. We’re currently brainstorming an expansion of the smart manufacturing system in collaboration with the Commonwealth Cyber Initiative (CCI). We plan to set up two building models, one for manufacturing and one for distribution, linked by a sky bridge conveyor system that moves items between the locations. Students work to leverage convolutional neural networks that use images to facilitate machine learning. When paired with the advanced cameras, it forms a computer vision system that can accurately place blocks in a variety of lighting conditions, which can be a challenge for other systems. By having to optimize the communication protocols that command the smart manufacturing system’s robotic arms, students also get a sense for real-world constraints . The Raspberry Pi that functions as the controller for the system is limited in power, so finding efficiencies that also enable stability and precision with the arms is key. Is there an aspect of cybersecurity for these automated systems? Yes. Devices, sensors and communication networks integral to the IoT found in smart manufacturing systems and smart cities generate and share vast amounts of data. This makes them vulnerable to cybersecurity threats. Some of the issues we look to address include: Data Privacy: Smart systems collect and process vast amounts of data, including personal and sensitive information. Protecting this data from unauthorized access and breaches is a top priority. Device Vulnerabilities: Many IoT devices used in smart systems have limited computational resources and may not receive regular security updates, making them vulnerable to exploitation. Interconnectedness: The interconnected nature of smart city components increases the attack surface. A breach in one system can potentially compromise the entire network. Malware and Ransomware: Smart systems are susceptible to malware and ransomware attacks, which can disrupt services and extort organizations for financial gain. Insider Threats: Employees with malicious intent or negligence can pose significant risks to cybersecurity. Potential solutions to these problems include data encryption, frequent software updates, network segmentation with strict access controls, real-time intrusion detection (with automated responses to detected threats), strong user authentication methods, security training for users and the development of well-designed incident response plans.
Improving Care for Black Patients With Heart Failure and Hypertension
ChristianaCare’s Center for Heart & Vascular Health has dramatically improved the clinical outcomes of Black patients living with heart failure and hypertension by using a digital hybrid platform that provides patients with a dedicated health coach to ensure their care plan is followed and treatment goals are achieved. Through this innovative approach, ChristianaCare achieved a significant improvement in the number of Black patients adhering to prescribed doses of guideline-directed medical therapy (GDMT) for heart failure. “At ChristianaCare, we are deeply committed to eliminating disparities and achieving health equity in the communities we serve,” said Kirk Garratt, M.D., medical director of the Center for Heart & Vascular Health. “We are proud that we have been able to significantly improve the health outcomes of our patients, especially addressing health disparities in the Black population for patients with heart failure and hypertension.” Approximately 32% of ChristianaCare’s heart failure patient population identify as Black, which is a higher percentage compared to the Black population nationally (12.4%). Historically, Black Americans have experienced racial disparities in heart failure treatment and experience worse patterns of adherence to guideline-directed medical therapy (GDMT) . Additionally, Black Americans have a 30% greater risk of death from heart disease than white Americans. Combining technology and human-powered guidance This novel approach to care is powered by Story Health, a leading health technology services company. Its digital platform and health coaches have been able to deliver superior outcomes for ChristianaCare’s patients regardless of race. Black patients in particular have made remarkable gains: 6 times improvement on target doses of beta blockers (76%). 7 times improvement on target doses ACE/ARB/ARNIs (54%). 2 times improvement on target doses of MRAs (57%). ChristianaCare was also able to achieve improvement in Black patients taking SGLT2 inhibitors, rising from a 32% baseline to 74%. Despite their vital role in treating heart failure, SGLT2 inhibitors are historically underprescribed and see lower adherence – largely due to affordability challenges, as costs can be $500 per month or more. Helping patients overcome cost barriers is critical, which is why the health coaches directly engage with patients to identify those who may need assistance and will work on their behalf to qualify for prescription assistance programs. “Along with their digital platform, the health coaches from Story Health understand the unique needs of our patients and have helped us create deeper, more accessible relationships with our patients to help improve their health and outcomes,” said Sourin Banerji, M.D., medical director of Advanced Heart Failure and Mechanical Circulatory at ChristianaCare. The health coaches serve as an extension of the clinician to identify and resolve challenges such as medication adherence, lab work coordination, transportation arrangement and even prescription assistance that cause disruptions in a patient’s care journey and lead to negative outcomes. Improved control of hypertension In addition to heart failure patients, ChristianaCare’s collaboration with Story Health supported patients with hypertension, delivering significant reductions in blood pressure for those enrolled regardless of race. Among Black patients specifically, there were significant decreases in average absolute systolic and diastolic blood pressure levels (17 mm Hg and 8 mm Hg, respectively) after 120 days, compared to 8 mm Hg and 5 mm Hg decreases for uncontrolled hypertensives in another digital program after 12 months. As a result of this initial success, ChristianaCare’s Center for Virtual Health is expanding the use of this care model beyond cardiology to support all patients in the population. Many of these patients struggle to manage high blood pressure, and the use of a continuous care program will be an important tool to help with medication management and addressing social barriers. “Health equity is an incredibly important initiative, and we see our mission as critical to helping specialty and primary care providers drive more equitable care,” said Story Health Co-founder and President Nita Sommers. “As an industry leader, ChristianaCare understands that every individual deserves compassionate care that is accessible, so we are honored to be working with its cardiology team and now the Center for Virtual Health to improve the health of patients.” ChristianaCare has been recognized numerous times for high-quality heart care. Among the many achievements are the American College of Cardiology HeartCARE National Distinction of Excellence Award for three consecutive years (2020-2023) and being named among Healthgrades top 100 hospitals for heart care in the U.S. for the past two years (2022-2023).
