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Thanksgiving North and South: Why Canada and the U.S. Celebrate at Different Times
Every fall, both Canadians and Americans gather around the table to give thanks — but they do it more than a month apart. While the two holidays share themes of gratitude, harvest, and togetherness, they evolved under distinct historical, cultural, and seasonal circumstances that reflect each nation’s story. A Canadian Harvest of Thanks Canada’s Thanksgiving traces its roots back to 1578, when English explorer Martin Frobisher held a ceremony in Newfoundland to give thanks for safe passage across the Atlantic. Over time, the holiday blended European harvest traditions with local customs, emphasizing gratitude for the year’s bounty rather than a single historic event. Because Canada’s growing season ends earlier than in most of the United States, Thanksgiving naturally became an autumn harvest celebration held in early October. It was officially recognized in 1957, when Parliament declared the second Monday of October as a national holiday “to give thanks for the harvest and the blessings of the past year.” The American Tradition South of the border, Thanksgiving carries a different historical symbolism. The U.S. holiday traces back to 1621, when Pilgrims and the Wampanoag people shared a harvest feast in Plymouth, Massachusetts. While similar in spirit, the American version became tied more closely to the nation’s founding mythology — a story of cooperation, survival, and gratitude in the New World. Because harvests occur later in the U.S., the celebration naturally took place in late November. In 1863, during the Civil War, President Abraham Lincoln proclaimed Thanksgiving a national holiday to promote unity, setting it for the final Thursday in November. Congress later standardized the date to the fourth Thursday in 1941. Seasons, Stories, and Shared Spirit At heart, both Thanksgivings mark the same human instinct: to pause, reflect, and give thanks. Canada’s October observance reflects the rhythm of northern harvests and a gratitude rooted in nature’s cycle. The American holiday, coming later in November, intertwines with its own national narrative of endurance and unity. Despite the calendar gap, the spirit is shared — families gathering to celebrate abundance, resilience, and community, in traditions that continue to evolve on both sides of the border. Connect with our experts on the history, traditions, and cultural meanings of Thanksgiving in North America. Check them out here : www.expertfile.com
'Brain-on-a-chip': Engineering tomorrow’s breakthroughs today
A “brain-on-a-chip” technology might sound like science fiction, but it’s real-world hope. James McGrath, a biomedical engineer at the University of Rochester, leads a team that develops micro-scale tissue chips to study diseases in lieu of conducting animal experiments. The team’s “brain-on-a-chip” model replicates the blood-brain barrier — the critical membrane separating the brain from the bloodstream — to mimic how the barrier functions under healthy conditions and the duress of infections, toxins, and immune responses that can weaken it. Recent findings from McGrath’s team show how systemic inflammation, such as that caused by sepsis, can compromise the barrier and harm brain cells. The researchers also demonstrated how pericytes — supportive vascular cells — can help repair barrier damage, an insight that could guide new therapies for Alzheimer’s and Parkinson’s. The research culminated in a pair of recent studies published in Advanced Science and Materials Today Bio. “We hope that by building these tissue models in chip format, we can arrange many brain models in a high-density array to screen candidates for neuroprotective drugs and develop brain models with diverse genetic backgrounds,” McGrath says. McGrath aims to transform how scientists test drugs and predict neurological side effects before they occur — helping rewrite how we study, and one day safeguard, the brain. Contact McGrath by clicking on his profile
The e-learning resource, Supporting people living with long COVID, was developed by the Centre for Pharmacy Postgraduate Education (CPPE) It is designed to help community pharmacy teams build their skills, knowledge and confidence The programme offers video and audio resources, practical consultation examples and strategies for supporting individuals. Professor Ian Maidment at Aston Pharmacy School has been involved in a project with the Centre for Pharmacy Postgraduate Education (CPPE) to develop a new e-learning programme for community pharmacists, called Supporting people living with long COVID. The programme is designed to help community pharmacy teams build their skills, knowledge and confidence to support people managing the long-term effects of COVID-19. It was developed with researchers undertaking the National Institute for Health and Care Research (NIHR)-funded PHARM-LC research study: What role can community PHARMacy play in the support of people with long COVID? During the development of the e-learning resource, as well as with Professor Maidment, CPPE worked in collaboration with researchers from Keele University, the University of Kent, Midlands Partnership University NHS Foundation Trust and lechyd Cyhoeddus Cymru (Public Health Wales). The research draws on lived experience of long COVID, as well as the views of community pharmacy teams on what learning they need to better support people living with the condition. This new programme offers video and audio resources, practical consultation examples and strategies for supporting individuals through lifestyle advice, person-centred care and access to wider services. Professor Maidment said: “As an ex-community pharmacist, community pharmacy can have a key role in helping people living with long COVID. The approach is in line with the NHS 10 Year Health Plan, which aims to develop the role of community pharmacy in supporting people with long-term conditions.” Professor Carolyn Chew-Graham, professor of general practice research at Keele University, said: “Two million people in the UK are living with long COVID, a condition people are still developing, which may not be readily recognised, because routine testing for acute infection has largely stopped. For many, the pharmacy is the first place they seek advice about persisting symptoms following viral infection. The pharmacy team, therefore, has the potential to play a really important role in supporting people with long COVID. This learning programme provides evidence-based information to develop the confidence of pharmacy staff in talking to people with long COVID. Developed with people living with long COVID, the programme’s key message is to believe and empathise with people about their symptoms.” Visit www.cppe.ac.uk/programmes/l/covid-e-01 to access the e-learning programme. This project is funded by the National Institute for Health Research (NIHR) under its Research for Patient Benefit (RfPB) Programme (Grant Reference Number NIHR205384).
A global team of researchers using the new X-ray Imaging and Spectroscopy Mission (XRISM) telescope, launched in fall 2023, discovered something unexpected while observing a well-studied neutron star system called GX13+1. Instead of simply capturing a clearer view of its usual, predictable activity, their February 2024 observation revealed a surprisingly slow cosmic wind, the cause of which could offer new insights into the fundamental physics of how matter accumulates, or “accretes,” in certain types of binary systems. The study was one of the first from XRISM looking at wind from an X-ray binary system, and its results were published in Nature—the world's leading multidisciplinary science journal—in September 2025. Spectral analysis indicated GX13+1 was at that very moment undergoing a luminous super-Eddington phase, meaning the neutron star was shining so brightly that the radiation pressure from its surface overcame gravity, leading to a powerful ejection of any infalling material (hence the slow cosmic wind). Further comparison to previous data implied that such phases may be part of a cycle, and could “change the way we think about the behavior of these systems,” according to Joey Neilsen, PhD, associate professor of Physics at Villanova University. Dr. Neilsen played a prominent role as a co-investigator and one of the corresponding authors of the project, along with colleagues at the University of Durham (United Kingdom), Osaka University (Japan), and the University of Teacher Education Fukuoka (Japan). Overall, the collaboration featured researchers from dozens of institutions across the world. GX13+1 is a binary system consisting of a neutron star orbiting a K5 III companion star—a cooler giant star nearing the end of its life. Neutron stars are small, incredibly dense cores of supergiant stars that have undergone supernovae explosions. They are so dense, Dr. Neilsen says, that one teaspoon of its material would weigh about the same as Mount Everest. Because of this, they yield an incredibly strong gravitational field. When these highly compact neutron stars orbit companion stars, they can pull in, or accrete, material from that companion. That inflowing material forms a visible rotating disk of gas and dust called an accretion disk, which is extremely hot and shines brightly in X-rays. It’s so bright that sometimes it can actually drive matter away from the neutron star. “Imagine putting a giant lightbulb in a lake,” Dr. Neilsen said. “If it’s bright enough, it will start to boil that lake and then you would get steam, which flows away like a wind. It’s the same concept; the light can heat up and exert pressure on the accretion disk, launching a wind.” The original purpose of the study was to use XRISM to observe an accretion disk wind, with GX13+1 targeted specifically because its disk is persistently bright, it reliably produces winds, and it has been well studied using Chandra— NASA’s flagship X-ray observatory—and other telescopes for comparison. XRISM can measure the X-ray energies from these systems a factor of 10 more precisely than Chandra, allowing researchers to both demonstrate the capabilities of the new instrument and study the motion of outflowing gas around the neutron star. This can provide new insights into accretion processes. “It's like comparing a blurry image to a much sharper one,” Dr. Neilsen said. “The atomic physics hasn't changed, but you can see it much more clearly.” The researchers uncovered an exciting surprise when the higher-resolution spectrum showed much deeper absorption lines than expected. They determined that the wind was nearly opaque to X-rays and slow at “only” 1.4 million miles per hour—surprisingly leisurely for such a bright source. Based on the data, the team was able to infer that GX13+1 must have been even brighter than usual and undergoing a super-Eddington phase. So much material was ejected that it made GX13+1 appear fainter to the instrument. “There's a theoretical maximum luminosity that you can get out of an accreting object, called the Eddington limit. At that point, the radiation pressure from the light of the infalling gas is so large that it can actually hold the matter away,” Dr. Neilsen said, equating it to standing at the bottom of a waterfall and shining light so brightly that the waterfall stops. “What we saw was that GX13+1 had to have been near, or maybe even above, the Eddington limit.” The team compared their XRISM data from this super-Eddington phase to a set of previous observations without the resolution to measure the absorption lines directly. They found several older observations with faint, unusually shaped X-ray spectra similar to the one seen by XRISM. “XRISM explained these periods with funny-shaped spectra as not just anomalies, but the result of this phenomenally strong accretion disk wind in all its glory,” Dr. Neilsen said. “If we hadn’t caught this exact period with XRISM, we would never have understood those earlier data.” The connection suggests that this system spends roughly 10 percent of its time in a super-Eddington phase, which means super-Eddington accretion may be more common than previously understood—perhaps even following cycles—in neutron star or black hole binary systems. “Temporary super-Eddington phases might actually be a thing that accreting systems do, not just something unique to this system,” Dr. Neilsen said. “And if neutron stars and black holes are doing it, what about supermassive black holes? Perhaps this could pave the way for a deeper understanding of all these systems.”
Soaring gold prices could bring big rewards – and even bigger risks
This week, gold prices surged to record highs, reshaping both the financial and geopolitical landscape. The University of Delaware’s Saleem Ali can explain the potential environmental, social and economic ripple effects of this gold rush and the opportunities and risks it creates. He says a controlled release of global gold reserves could help ease market pressure and mitigate the negative impacts. Ali, a professor of energy and the environment, can discuss the following main points: • The record gold price (which dipped slightly today) has implications for new gold mining projects becoming more financially attractive which could have environmental and social implications in those areas. • Major gold trading hubs like Switzerland and Dubai will need to be more vigilant as gold will become more attractive for the illicit economy for commodities. • We have major global bank reserves of gold even though the gold standard is no longer used to back currency. Some of these reserves could be liquidated to reduce pressure and negative externalities. Such a controlled release of gold reserves could help to manage the price rise. Ali also serves on the Independent Governance Committee for the Dubai Multicommodity Center, which manages all of the gold coming into the United Arab Emirates. To reach Ali directly and arrange an interview, visit his profile and click on the “connect” button. Interested reporters can also send an email to MediaRelations@udel.edu.
For Trump’s Perceived Enemies, the Process may be the Punishment
This article is republished from The Conversation under a Creative Commons license. Read the original article here. Former FBI Director James Comey pleaded not guilty to two criminal charges in a federal court in Alexandria, Virginia, on Oct. 8, 2025. The charges allege that Comey lied to Congress in September 2020 when he stood by earlier testimony that he did not authorize a leak of an FBI investigation involving Hillary Clinton. Numerous legal commentators on both the left and right have argued that Comey’s indictment is little more than the Trump administration seeking vengeance on one of the president’s perceived enemies. They allege that the president has it out for Comey, who investigated Russian interference in the 2016 presidential election and was fired by Trump in 2017. The president’s own words support the idea that the Trump administration is targeting Comey. In a social media post on Sept. 20, 2025, Trump directed Attorney General Pam Bondi to move forward with prosecutions against Comey, Democratic U.S. Sen. Adam Schiff and New York Attorney General Letitia James: “They’re all guilty as hell, but nothing is going to be done. …JUSTICE MUST BE SERVED, NOW!!!” If the case against Comey is exceedingly weak – and little more than a political prosecution – then, in my view as a scholar of the U.S. legal system, it should result in the dismissal of charges by the judge or a not guilty verdict by the jury. But even when an individual is not convicted, the process of defending against charges can itself be a form of punishment, as renowned legal scholar Malcolm Feeley pointed out almost 50 years ago. Here’s how the criminal justice process punishes even innocent people. The criminal justice process The criminal justice process is complex. After a grand jury returns an indictment at the request of a prosecutor, the accused appears in court for their arraignment. They are informed of the charges against them and typically enter a plea. During what’s called “discovery,” the prosecution and defense investigate the evidence the other side plans to rely on. There are also pretrial motions in which the parties ask judges to dismiss charges and accept or exclude evidence. The defense and prosecution may also meet to discuss a plea bargain, wherein the accused may plead guilty in exchange for a lesser sentence or reduced charges. If there is no plea bargain, then the case moves to trial, which is itself a complicated process. If a defendant is found guilty, they can mount an appeal to higher courts in an attempt to have their conviction overturned. To help navigate this process, criminal defendants typically hire a lawyer. And good lawyers don’t come cheap. Money and time Indigent defendants, who do not have the financial resources to pay their own legal fees, can rely on public defenders paid for by the government. But individuals who can afford to pay for their own lawyer face a substantial financial burden for attorney services and court fees. An experienced criminal defense lawyer can charge more than US$1,000 per hour, with fees quickly adding up. This means that mounting a legal defense can easily cost tens of thousands of dollars. On top of this, it takes a great deal of time to prepare for a criminal case. While lawyers and their staff do much of the legwork for trial preparation, a client works with their attorneys to help formulate a defense. As a result, criminal defendants lose one of the most precious commodities in the world: their time. And this time can come at a tangible cost in the form of lost wages, which harms their day-to-day lives. Put simply, every hour spent preparing for trial is an hour defendants could spend working or enjoying their lives. Stress and embarrassment It’s not pleasant being charged with a crime. The criminal process, which typically lasts months, takes a toll on one’s mental health. This is largely driven by the uncertainty surrounding the outcome of a criminal trial and the possibility of losing one’s freedom if convicted. In addition, there is a social stigma that comes with being accused of a crime. This can result in reputational damage, anxiety and embarrassment. The Trump administration appears to recognize this reality. Several media outlets have reported that FBI leadership had planned a public perp walk for Comey. According to a CBS News report, this was to have included “‘large, beefy’ agents … ‘in full kit,’ including Kevlar vests and exterior wear emblazoned with the FBI logo.” Apparently, the plan was aborted after several FBI supervisors refused to cooperate, viewing it as inappropriate. One agent was disciplined for insubordination after refusing to go along with the plan to embarrass Comey in this way. Not all criminal defendants suffer the same The extent to which criminal defendants experience the criminal justice process as a form of punishment varies from person to person. For high-status people like Comey, lost wages and attorneys’ and court fees may not be that big of a deal. But these costs may be incredibly significant for other people who have been, or are likely to be, targeted by the Trump administration. The high costs of lawyers’ fees are well known to the president. For instance, his political action committee spent millions of dollars on attorneys’ fees in an unsuccessful effort to defend Trump from criminal charges in New York. In addition, people no doubt experience the psychological stress and stigma of a possible criminal conviction differently. But regardless of one’s wealth, the lost time spent preparing a criminal defense is something that cannot be replaced. The recognition that the criminal process is itself a form of punishment is one of the reasons that the Department of Justice has maintained independence from the president. By violating the tradition of staying out of politics, the Justice Department in the Trump administration has opened the door for the president to seek retribution on his perceived political enemies. The mere act of putting them through the criminal process ensures that they suffer, regardless of their guilt or innocence.
In the two years since Augusta University and Wellstar Health System formally signed an agreement on August 30, 2023, the historic partnership has continued to evolve into a truly collaborative alliance. At its heart, the mission hasn’t changed: improving the health and wellbeing of all Georgians while educating and preparing the next generation of health care providers through access to world-class training. That was the message shared by Augusta University President Russell T. Keen, Medical College of Georgia at Augusta University Dean David C. Hess, MD, and former Wellstar President and CEO Candice L. Saunders at the recent Health Connect South conference held at the Georgia Aquarium in Atlanta. During their panel “Advancing Healthcare Through Public-Private Partnerships,” the three leaders – each instrumental in helping to create, implement and mold the historic partnership – shared with close to 1,100 attendees their insight into what makes the partnership beneficial for all and how it can be a model for advancing health care and health care education in Georgia and beyond. The full panel discussion is available for viewing here: It was an important event, and a full article is attached below as well. And if you're interested in learning more about the partnership between Augusta University and Wellstar, or connect with Augusta's President Russell T. Keen - simply click on his icon now to arrange an interview today.
Inside the Classroom: LSU Psychologist Shares Insight on Student Attention Spans
What large changes have schools seen over the past few years regarding attention spans? "Being distracted by something in nature when trying to do a task may have been the first type of distraction, along with internal distractions, such as thinking about something else when you are trying to complete a task. Thus, distraction is not new. What’s new today is that the types of distractions are more complex and can even be individually tailored to capture someone’s attention, which can lead to more temptations to shift our attention off of one task and over to something else." What are innocuous ways students can harm their attention spans? What effect do phones have on retention ability? "One way I think that students can harm their own task progress is to believe that they can truly multitask or do more than one thing at one time. If you are completing a homework assignment and you are tempted to check your social media feed, you are causing a switch of your attentional focus. It may seem quick and somewhat harmless, but numerous studies have indicated that trying to switch back and forth between two tasks results in more errors and has the overall effect of taking longer to complete the main task. Thus, put simply, do not multitask. Set aside a time limit, say 20 or 30 minutes, to solely focus on one assignment or one study guide. Then take a break." How can a depleted attention span affect general physical and mental health in children? "Mental effort can be as tiring as physical efforts. As a field, we now understand the importance of sleep and overall health for our cognitive systems. To support the efforts of sustained attention, it is important to recognize that learning takes time and it takes energy. In terms of young children, the many processes involved in the development of the body and the mind require more sleep than older children and adults. How may fixing a memory deficit look different in a teen versus a child? "Younger children need more breaks than older children, as well as needing more sleep. However, younger children are able to maintain their focus of attention. They may need more guidance and something we call “scaffolding." This term is used to indicate that the older learners may already have a framework to use to build their knowledge, whereas younger learners are starting from scratch. Providing extra support that is relative to their age and ability helps children to perform at their maximum level." Are schools set up to most efficiently stimulate students' minds? "When I think about the classrooms of early childhood settings, such as pre-K and lower elementary schools, the classrooms are set up to encourage learning. There are brightly colored pictures and words on the walls; there are reading nooks that are comfortable and easy to reach for smaller learners; there are spaces to move the desks around the room to allow for different configurations of the space; and so forth. As children get older, the classroom spaces start to reflect these changes and allow for different interactions between the students and the material. I think about a high school science lab with tables and equipment, as compared to a history classroom with classical book titles and historical figures displayed on the walls. I believe the physical spaces of many classrooms are well-suited to match the skills and capabilities of the children as they grow, because they are designed to meet the children where they are." What tools would you recommend teachers use to help students strengthen their learning skills? "As I mentioned earlier, learning new material takes time and effort. It is important for children and adults to realize this and to allow time and space for learning. Sometimes adults can forget what it was like to learn something new for the first time, because they already have a foundation for their knowledge. Children are acquiring new information, new skills, and making new connections in their neural networks every day. We learn by associating information with things we already know, and also by making new connections. I mean this in a figurative sense, such as thinking about how one vocabulary word may relate to another one, as well as in a literal neural sense. Our brains work by making connections between neurons to create neural networks." Does knowing what kind of learner you are (audio, visual, or descriptive) help you improve your memory? "In terms of learning styles, this has been a pervasive but misleading concept. I believe it has stuck around because it is also intuitive. People have preferences. We know this, and it is very apparent in almost all aspects of life (our fashion, our food choices, etc). However, having a preference is not the same thing as being limited to learning in only one modality. In fact, research has shown that teaching new information in more than one modality is the most effective way." What has been the most surprising result from your research? "Children are incredibly capable of vast amounts of learning. I do not think we give children enough credit for the acquisition of so many skills in a relatively short amount of time. As just one example, if an adult learner has ever tried to become proficient in a second language, they will realize that it is a difficult task. However, young children can pick up a second language in a manner that seems almost effortless. This is just one example of the fantastic capabilities and flexibilities of the young mind."
Taking discoveries to the real world for the benefit of human health
It takes about a decade and a lot of money to bring a new drug to market—between $1 billion to $2 billion, in fact. University of Delaware inventor Jason Gleghorn wants to change that. At UD, Gleghorn is developing leading-edge microfluidic tissue models. The devices are about the size of two postage stamps, and they offer a faster, less-expensive way to study disease and to develop pharmaceutical targets. These aren’t tools he wants to keep just for himself. No, Gleghorn wants to put the patented technology he’s developing in the hands of other experts, to advance clinical solutions in women’s health, maternal-fetal health and pre-term birth. His work also has the potential to improve understanding of drug transport in the female reproductive tract, placenta, lung and lymph nodes. Gleghorn, an associate professor of biomedical engineering, was named to the first cohort of Innovation Ambassadors at UD, as part of the University’s effort to foster and support an innovation culture on campus. Below, he shares some of what he’s learned about translating research to society. Q: What is the problem that you are trying to address? Gleghorn: A lot of disease has to do with disorganization in the body’s normal tissue structure. My lab makes microfluidic tissue models, called organ-on-a-chip models, that have super-tiny channels about the thickness of a human hair, where we can introduce very small amounts of liquid, including cells, to represent an organ in the human body. This can help us study and understand the mechanism of how things work in the body (the biology) or help us do things like drug screening to test therapeutic compounds for treating disease. And while these little microfluidic devices can do promising things, the infrastructure required to make the system work often restricts their use to high-end labs. We want to democratize the techniques and technology so that nonexperts can use it. To achieve this, we changed the way we make these devices, so that they are compatible with standard manufacturing, which means we can scale them and create them much easier. Gleghorn: One of the problems with drug screening, in general, is that animal model studies don’t always represent human biology. So, when we’re using animal models to test new drugs — which have been the best tool we have available — the results are not always apples to apples. Fundamentally, our microfluidic devices can model what happens in humans … we can plug in the relevant human components to understand how the mechanism is working and then ask questions about what drives those processes and identify targets for therapies to prevent the dysfunction. Q: What is innovative about this device? Gleghorn: The innovation part is this modularity — no one makes these devices this way. The science happens on the tiny tissue model insert, which is sandwiched between two pieces of clear acrylic. This allows us to watch what’s happening on the tissue model insert in real time. Meanwhile, the outer shell’s clamshell design provides flexibility: if we’re studying lung tissue and we want to study the female reproductive tract, all we do is unscrew the outer shell and insert the proper tissue model that mimics the female reproductive tract and we’re off. We’ve done a lot of the engineering to make it very simple to operate and use, and adaptable to common lab tools that everyone has, to eliminate the need for financial investment in things like specialized clean rooms, incubators and pumps, etc., so the technology can be useful in regular labs or easily deployable to far-flung locations or countries. With a laser cutter and $500 worth of equipment, you could conceivably mass manufacture these things for maternal medicine in Africa, for example. Democratizing the technology so it is compatible and useful for even an inexperienced user aligns with the mission of my lab, which focuses on scaling the science and the innovation faster, instead of only a few specialized labs being a bottleneck to uncovering new mechanisms of disease and the development of therapies. We patented this modularity, the way to build these tiny microfluidic devices and the simplicity of how it's used as a tool set, through UD’s Office of Economic Innovation and Partnerships (OEIP). Q: How have you translated this work so far? Gleghorn: To date, we've taken this microfluidic system to nine different research labs across seven countries and four continents — including the United States, the United Kingdom, Australia, France, Belgium and South Africa. These labs are using our technology to study problems in women’s health and collecting data with it. We’re developing boot camps where researchers can come for two or three days to the University of Delaware, where we teach them how to use this device and they take some back with them. From a basic science perspective, there is high enthusiasm for the power of what it can tell you and its ease of use. As engineers, we think it's pretty cool that many other people are using our innovations for new discoveries. Q: What support and guidance have you received from the UD innovation ecosystem? Gleghorn: To do any of this work, you need partners that have various expertise and backgrounds. UD’s Office of Economic Innovation and Partnerships has built a strong team of professionals with expertise in different areas, such as how do you license or take something to patent, how do you make connections with the business community? OEIP is home to Delaware’s Small Business Development Center, which can help you think about business visibility in terms of startups. Horn Entrepreneurship has built out impressive programs for teaching students and faculty to think entrepreneurially and build mentor networks, while programs like the Institute for Engineering Driven Health and the NSF Accelerating Research Translation at UD provide gap funding to be able to do product development and to take the work from basic prototype to something that is more marketable. More broadly in Delaware is the Small Business Administration, the Delaware Innovation Space and regional grant programs and small accelerators to help Delaware innovators. Q: How have students in your lab benefited from engaging in innovation? Gleghorn: Undergraduate students in my lab have made hundreds of these devices at scale. We basically built a little manufacturing facility, so we have ways to sterilize them, track batches, etc. We call it “the foundry.” In other work, graduate students are engineering different components or working on specific system designs for various studies. The students see collaborators use these devices to discover new science and new discoveries. That's very rewarding as an engineer. Additionally, my lab focuses on building solutions that are useful in the clinic and commercially viable. As a result, we've had two grad students spin out companies related to the work we've been doing in the lab. Q: How has research translation positively impacted your work? Gleghorn: I started down this road maybe five years ago, seriously trying to think about how to translate our research findings. Being an entrepreneur, translating technology — it's a very different way to think about your work. And so that framework has really permeated most of the research that I do now and changed the way I think about problems. It has opened new opportunities for collaboration and for alternate sources of funding with companies. This has value in terms of taking the research that you're doing fundamentally and creating a measurable impact in the community, but it also diversifies your funding streams to work on important problems. And different viewpoints help you look at the work you do in new ways, challenging you to define the value proposition, the impact of your work.
Hempstead Supervisor Announces Tax Cuts
Lawrence Levy, associate vice president and executive dean of the National Center for Suburban Studies, spoke to News 12 Long Island about Hempstead Town Supervisor John Ferretti proposing an 18% tax cut to the general fund for 2026, that he says would result in $5 million savings. Helping to fund the cut would be a reduction in the town’s workforce. “This could be a good thing if the reduction is the result of sound fiscal practices. It could be a bad thing if it’s the result of fiscal gimmicks,” Levy said. “We’re talking about – at best – dollars in savings, not hundreds of dollars, except for the most expensive of properties.
