Worth Longest, Ph.D.

The National Academy of Inventors (NAI) recently inducted five Virginia Commonwealth University (VCU) College of Engineering researchers as senior members. Chosen for their innovative engineering contributions, the honorees are recognized as visionary inventors whose groundbreaking research and patented technologies are driving meaningful societal and economic advancements across the national innovation landscape. “Invention represents the practical application of knowledge and stands as one of the many ways engineers can make a positive impact on their communities and the world,” said Azim Eskandarian, D.Sc, the Alice T. and William H. Goodwin Jr. Dean of the VCU College of Engineering. “This year’s honorees exemplify the interdisciplinary nature of our field, leveraging advanced concepts from mechanical, biomedical, chemical and pharmaceutical engineering to address today’s most pressing challenges. We are immensely proud that our dedicated researchers have earned recognition as members of the esteemed National Academy of Inventors.” The VCU College of Engineering NAI inductees are: Jayasimha Atulasimha, Ph.D. Engineering Foundation Professor Department of Mechanical & Nuclear Engineering An internationally recognized pioneer of straintronics, an approach to electrically control magnetism for ultra-low-energy computing, Atulasimha has made significant research contributions to next-generation memory, neuromorphic hardware and emerging quantum computing technologies. He holds four U.S. patents spanning energy-efficient magnetic memory, nanoscale computing architectures and medical tools. Atulasimha’s commercially viable inventions are funded by organizations like the Virginia Innovation Partnership Corporation and he leads multi-institutional collaborations that drive innovation in computing hardware, AI and quantum technologies with more than $10 million in funded research. Casey Grey, Ph.D. Postdoctoral Research Associate Department of Mechanical & Nuclear Engineering Bridging engineering and medicine, Grey’s work spans life‑saving stroke technologies, breakthrough respiratory and neurological care, and sustainable packaging. As a lead R&D scientist at WestRock, he helped create and commercialize the CanCollar® portfolio, a recyclable paperboard replacement for plastic beverage rings now used on five continents, eliminating thousands of tons of single‑use plastic annually. In medical device innovation, Grey’s patent and development work on a novel cyclic aspiration thrombectomy platform, currently in clinical trials, is advancing stroke treatment by enhancing clot removal efficiency and reducing long‑term disability. At the VCU College of engineering, Grey built a research and commercialization pipeline around neurological and respiratory technologies, securing eight provisional patents and leading multidisciplinary teams in neurology, neurosurgery, surgery, pharmacology and toxicology, internal medicine, and respiratory medicine. His work includes developing dry powder inhaler strategies for delivering life‑saving drugs to patients with acute respiratory distress syndrome (ARDS), a pediatric bubble CPAP system designed to protect brain development in premature infants, and non‑invasive, non‑pharmacological 40 Hz neuromodulation therapies to treat neurodegeneration and conditions with significant central nervous system complications, like sickle cell disease. In collaborations with the VCU Children’s Hospital and VCU Critical Care Hospital, Grey is leading two clinical studies that are translating these innovations to improve patient care. Ravi Hadimani, Ph.D. Associate Professor and Director of Biomagnetics Laboratory Department of Mechanical & Nuclear Engineering Hadimani founded RAM Phantoms LLC, a VCU startup company, commercializing anatomically accurate, MRI-derived brain phantoms for neuromodulation and neuroimaging applications. These brain phantoms help test and tune transcranial magnetic and deep brain stimulation technologies, improving clinical safety and enabling personalized therapy for patients. RAM Phantoms is also developing a highly-skilled workforce for employment in Virginia’s growing biomedical device industry. Beyond commercialization, Hadimani maintains a productive research program with more than $4.5 million in funding resulting in 125 original peer-reviewed publications, 17 current and pending patents, a book, and several book chapters. His biomagnetics lab serves as a training ground for undergraduate, graduate and Ph.D. students to hone their skills in innovation management, intellectual property strategy and startup development. Several students from Hadimani’s lab have engaged in translational research, patent co-authorship and start-up formation, cultivating a new generation of engineer-entrepreneurs equipped to drive future technological advances. Before joining VCU, Hadimani led the development of hybrid piezoelectric–photovoltaic materials that established FiberLec Inc., which commercialized multifunctional energy-harvesting fibers capable of converting solar, wind and vibrational energy into usable electricity. Worth Longest, Ph.D. Alice T. and William H. Goodwin, Jr. Distinguished Chair Department of Mechanical & Nuclear Engineering Uniting aerosol science, biomedical engineering and computational modeling, Longest is revolutionizing inhaled drug delivery. Working with collaborators, his lab has developed novel devices, formulations and delivery platforms that precisely target medications to the lungs, addressing conditions like cystic fibrosis, pneumonia, acute respiratory distress syndrome and neonatal respiratory distress syndrome. These innovations have resulted in multiple patents. Some of them have been licensed through commercial partnerships like Quench Medical, an organization advancing inhaled therapies for applications like lung cancer. Collaborating with the Gates Foundation and the lab of Michael Hindle, Ph.D., from the VCU Department of Pharmaceutics, Longest’s team developed a low-cost, high-efficacy aerosol surfactant therapy for pre-term infants based entirely on technology developed at VCU. The invention eliminates intubation, reduces dosage by a factor of 10, and cuts treatment costs. Over 9 million infant lives are projected to be saved by this technology between 2030 and 2050. Through a long-term collaboration with the U.S. Food and Drug Administration, Longest’s in vitro and computational methods provide federal regulatory guidance for generic inhaled medications. The VCU mouth-throat airway models developed under his leadership are used globally across the pharmaceutical industry and in government laboratories. Hong Zhao, Ph.D. Associate Professor Department of Mechanical & Nuclear Engineering Zhao holds 40 patents with innovations spanning additive manufacturing, stretchable electronics, inkjet printing technologies and superoleophobic materials that repel oils, greases, and low-surface-tension liquids. Her research has applications across health care, sustainable energy and advanced manufacturing. Prior to joining the College of Engineering, Zhao served as a senior research scientist and project leader at the Xerox Research Center, where she developed high-performance materials and printing technologies for commercial deployment. Her industry experience makes Zhao’s lab a hub for innovation and mentorship, with students engaging in innovative research and co-authoring publications. Zhao is an invited reviewer for more than 50 premier journals and grant agencies. “Working with distinguished researchers and innovators like those inducted into the National Academy of Inventors is a great honor for me,” said Arvind Agarwal, Ph.D., chair of the Department of Mechanical & Nuclear Engineering and NAI fellow. “They are an inspiration and showcase the kind of impact engineers can make. Having all five of these innovators as part of our department amplifies the scientific richness of our college and its societal impact. They advance the college’s mission of Engineering for Humanity, with research that brings a positive change to our world.” The 2026 NAI class of senior members, composed of 231 emerging inventors from NAI’s member institutions, is the largest to date. Hailing from 82 NAI member institutions across the globe, they hold over 2,000 U.S. patents.

“Traditionally, the nose has been used as a route for delivery of locally acting drugs,” Laleh Golshahi, Ph.D., explained. “But recently, there has been a great deal of interest in the direct pathway through the olfactory region. That’s the same region where we smell, and that route is a direct pathway to the brain.” Golshahi, associate professor in VCU’s Department of Mechanical and Nuclear Engineering, leads the collaboration. Other members of the group are Worth Longest, Ph.D., the Louis S. and Ruth S. Harris Exceptional Scholar and Professor in the Department of Mechanical and Nuclear Engineering; Michael Hindle, Ph.D., the Peter R. Byron Distinguished Professor in VCU’s Department of Pharmaceutics; and Arya Bazargani, a Ph.D. student in VCU’s Interdisciplinary Center for Pharmaceutical Engineering and Sciences. The project is supported by a $200,000 internal grant from VCU Breakthroughs, a new internal funding mechanism as part of the Optimizing Health thrust of the One VCU Research Strategic Priorities Plan being implemented by the university’s Office of the Vice President for Research and Innovation. Hindle said that studies of nasally administered insulin have shown some promise for reducing the effects of Alzheimer’s. Unfortunately, delivery by injection, the most common way to deliver insulin, is ineffective for Alzheimer’s and other cerebral conditions because of the blood-brain barrier. Bazargani explained that nose-to-brain delivery of pharmaceuticals circumvents the blood-brain barrier, the lining of the blood vessels that surround the brain, guarding the central nervous system against a host of pathogens. “It’s usually a good thing,” he said. “But not when you’re trying to induce therapeutic effects into the brain.” Bazargani explained that insulin molecules are so large that the blood-brain barrier filters out most of the insulin. Hindle pointed out that even though the VCU team is avoiding the blood-brain barrier, insulin delivery still presents a number of challenges. “Insulin is a pretty fragile molecule, you know. It’s stored in the fridge,” Hindle said. “We need to include insulin in some sort of stable formulation — either a powder or a liquid nasal spray. We have to create the right particle or droplet size to get it into the right area of the nose.” Formulation development is only half of a two-pronged challenge, Golshahi said. The second aspect is the creation of a device that can deliver a dose way up to the olfactory region. “The nose is a challenge, because it’s designed as a filter to keep aerosols out of the body,” said Longest, who, along with Golshahi and Hindle, brings expertise in computational fluid dynamics to the team. “And the olfactory region is an especially troubling or difficult region to target, because it’s designed just to let a few molecules of what we inhale deposit.” Chief among the nasal filtering defenses, Golshahi said, is mucociliary clearance. Nasal passages are lined with mucous-coated cilia — moving microscopic projections on cells — sweeping foreign substances out of the air we breathe. The cilia do an excellent job, she said, but their efficiency makes it difficult to achieve a consistent delivery to the olfactory region. Another challenge, she added, lies in the fact that all noses are different. The collaborators are using in vitro and in silico methodologies. For the in vitro work, they have an array of 3D printed nose models, based on computed tomography (CT) scans. Golshahi said they have multiple anatomical casts of human nasal airways to test likely device/formulation combinations for their insulin/Alzheimer’s initiative. “We are going to use three of those nasal casts as our starting point,” she said. “We’ll connect the casts to a breathing simulator, which is basically a machine you can program to add the air going through — sort of bringing them to life.” Golshahi added that data from the casts will inform the in-silico component of the work — computational analysis that is expected to verify or challenge observations from the lab. Hindle said that once the team has developed a satisfactory formulation-device system, they can tackle the next challenge: identifying the dominant pathway from the olfactory region to the brain. “There are a variety of theories out there,” he said. “It could go along the nerve passageway. It could go between the nerve walls and the cells linking them.” “We have all the equipment and all the expertise necessary to be able to develop a formulation, and to put it in a device that leads to the highest amount of delivery to the target region,” Golshahi said. “And we are able to quantify how successful that combination of formulation and device is.”

Michael Hindle, Ph.D., a professor in the VCU Department of Pharmaceutics, and P. Worth Longest, a professor in the VCU Department of Mechanical and Nuclear Engineering, have invested years of time and millions of dollars to address challenges found in the field of medical aerosols. In particular: While smaller particles are more effective in delivering drugs into the lungs and airways, these tiny particles are often exhaled out immediately when taking a dose. Current aerosol delivery systems — think asthma inhalers — effectively deliver just 10 percent of an aerosolized dose. That’s fine for most asthma and COPD sufferers who use standard inhalers with existing medications, as these patients only need a small amount of the potent drugs to reach the lungs and have an effect. “But the medical world wants to use the lungs for delivery of other drugs, whether it’s locally to the airways or systemically to the body, and for that, you need more efficient devices,” Hindle says. To effectively use inhaled drugs for complex medical conditions requires more of the aerosol to reach the airways and to potentially target different regions of the airways — plus the devices to get them there. “Our work is about doing something different — changing that ballgame from having 90% of the drug wasted and 10% make it to the lungs, and flip it so that we get just 10% lost and 90% in the lungs,” Hindle says. “That’s always been our goal.” Taking aerosols from lab to lung Over more than a decade, the duo and their teams have created the three keys to making aerosol drug-delivery work: “developing the strategy, developing the device, and developing the formulation,” says Longest, the College of Engineering’s Louis S. and Ruth S. Harris Exceptional Scholar Professor. “When you see inhalation of aerosols fail, or a new pharmaceutical aerosol product fail, one of these areas has often been neglected. Between my lab and the Hindle lab, we have expertise in each of these different areas.” The fourth component — commercializing their inventions — is underway through a partner in Quench Medical in a deal signed in 2020 thanks to VCU Innovation Gateway. The Minnesota-based company, led by founder and CEO Bryce Beverlin II, Ph.D., has identified lung cancer, severe asthma, and cystic fibrosis as potential initial applications using VCU’s intellectual property, the licensing of which covers both the aerosols and the delivery devices. “It’s very difficult for an academic institution to develop a drug product,” says Hindle, the Peter R. Byron Distinguished Professor in Pharmaceutics. “So Bryce has moved forward with a team of manufacturers, clinical testing plans, and is talking to the Food and Drug Administration.” The VCU researchers had not previously pursued lung cancer as a possible application until Quench came along, Hindle says. “The idea that you could deliver a chemotherapy locally to the lungs is obviously very advantageous, because you don’t get the systemic side effects through the body like with traditional chemotherapy,” he says. “You’re just delivering drugs direct to that site of action for targeting the metastases in the lung.” In May, Quench presented data using the VCU technology to the Respiratory Drug Delivery conference in Florida showing that using a chemotherapeutic dry powder aerosol in rats was highly effective. It significantly reduced tumor burden but used half of the standard IV-delivered chemo dose. “This approach also aims to decrease the total drug delivered with reduced systemic drug levels in the circulation to decrease systemic toxicity,” the report read. It noted the efforts “solve a critical unmet medical need to develop new strategies to improve treatment outcomes in patients with lung cancer.” Heavy interest nationally Hindle and Longest have millions of dollars in funded projects underway, backed by the National Institutes of Health, U.S. Food & Drug Administration, and the Bill & Melinda Gates Foundation. Their work is building on the reputation of VCU’s Aerosol Research Group, founded in 1988 by emeritus professor Dr. Peter Byron (the name on Hindle’s professorship). The group’s work spans a wide variety of research areas in aerosol formulation and delivery. Hindle and Longest have worked together since 2006. While Hindle is focused on drug formulations, Longest is the engineering and computer modeling expert. His background is in biological fluid flow, and prior to joining VCU in 2004 had worked in the area of blood flow in vascular disease. But he wanted to differentiate his work, and found VCU’s reputation in medical aerosols was the place he could, in his words, “make an impact.” Through computer models, Longest and his team can understand how powders or liquids will turn into aerosol particles and the behaviors they will undertake when delivered into the body. “The lung is an area of the body where we have all these complex phenomena occurring with airflow and moving walls,’” he says. “It really takes high performance computers to understand it.” Drs. Longest and Hindle have developed a series of technology platforms that produce particles that are tiny when entering the lungs to minimize deposition losses in the mouth and throat — but grow in size as they travel down the warm, humid airways. One of the devices uses a mixer-heater to produce tiny particles, other technologies use a pharmaceutical powder or liquid containing a simple hygroscopic excipient such as sodium chloride; it is this excipient that attracts water from the lungs and makes the particles grow and deposit in the lungs with high efficiency. Eyes on infants Lately, the pair have been working on a method of aerosol drug delivery to newborns and prematurely born babies. “It’s a different set of challenges when you’re trying to deliver aerosols to infants who are born prematurely, and don’t have the ability to breathe on their own due to the lack of airway surfactant,” Hindle says. “And that’s something that, academically, we thought we were in a position to try and make a contribution to the field.” The group is working with funding from the NIH and the Bill and Melinda Gates Foundation to develop a method of delivering an aerosol surfactant to infants that will hopefully remove the need to intubate these fragile babies. In addition to striking licensing deals with Quench and building relationships with additional partners, Innovation Gateway has backed the pair’s work with an initial $25,000 from VCU’s Commercialization Fund as well as a just-awarded additional $35,000. “We turned that into a series of intellectual property that has resulted in three licensed patents and a whole family of IP in relation to both formulations and devices,” Hindle says. “There’s been lots of interest in delivering drugs to the lungs, it’s just been very difficult to institute any sea change, because the pharmaceutical industry is relatively risk averse.” And so their research continues, as Quench moves forward to bring their inventions to the bedside. “What I’m doing, I don’t really consider it work — it’s an opportunity to interact with great colleagues and contribute to a mission that will be very helpful to a broad range of people,” Longest says. “I also see it as a big responsibility. We want to do this in the right way. Because people’s health and lives are at stake. We want to make sure we approach this with a large sense of responsibility, and do our best.”