The��study was sponsored by the��National Institutes of Health’s National Institute on Aging��and��was led by �鶹ԭ�� Nanoscience Technology Center��Professor��James Hickman��and��Research��Professor��Xiufang “Nadine” Guo. In collaboration with��researchers at��healthcare tech company Hesperos, the team used��lab-grown,��human-cell systems designed to model how the body functions��to��examined��how genetic mutations associated with��familial��Alzheimer’s��affects��movement.��Today, the��study was published in��Alzheimer’s & Dementia: The Journal of the Alzheimer’s Association.

“Motor deficits may be an earlier indication��[of Alzheimer’s],” she��says. “If we can detect those changes and intervene earlier, that could help delay the onset of central nervous system symptoms.”

How��Movement and Alzheimer’s Are Connected

Familial Alzheimer’s is��a��rare��form of the disease that��is��hereditary and appears��earlier��(from��40 to 65 years of age)��in people affected than those��with the typical��condition.

While��Alzheimer’s disease is widely��associated with��memory loss and dementia,��clinicians have long��observed��that some patients show changes in balance, gait��(manner of walking)��or movement years before cognitive symptoms appear. These��early motor changes��raise��questions about whether��parts of the disease begin��outside the brain.

Through a tech-powered approach, the��team found that the diseased motor neurons��—��even without involvement from the brain��—��disrupted��the neuromuscular junction, which is��central to daily movement.

“This is the first time it’s been demonstrated that deficits in the peripheral nervous system can arise directly from these mutations,” Hickman��says. “It means drugs that target the brain may not fix problems in the rest of the body.”

Maintaining��motor function may also��support overall��brain��health,��as��physical activity is known to��play a role in cognitive well-being, Guo notes.

How Researchers Build Human Disease Models in the Lab

To explore how these mutations affect movement, the researchers turned to a��cutting-edge��approach called “human-on-a-chip” technology, which is manufactured��through Hesperos, a company co-founded by Hickman.��These miniature lab systems recreate the way human cells interact and function in the body, allowing scientists to study disease in a more realistic way than traditional lab or animal models.

The team built a neuromuscular junction-on-a-chip — a small system that mimics the connection between motor neurons and muscle cells.��What makes��this system powerful is��what’s��left out: the brain and spinal cord. By isolating motor neurons and muscle cells, the researchers could��determine��whether movement problems could arise without the central nervous system being involved.

To test this, the researchers��paired��healthy��muscle cells��with��motor neurons��that were��created from stem cells��and��carried��familial Alzheimer’s disease��mutations.��The��findings suggest that Alzheimer’s-related movement issues may begin in the network of nerves outside the brain and spinal cord rather than being caused solely by brain degeneration.

Why the��Nerve-to-Muscle Connection Matters

The neuromuscular junction is the point where a nerve cell signals a muscle to contract, making movement possible.��If that connection is damaged, the body may lose strength,��coordination��or endurance.

In the study, the researchers measured several aspects of neuromuscular function, including how reliably nerve signals triggered muscle contraction and how long muscles could remain contracted before fatiguing. These measurements mirror the kinds of tests doctors use to evaluate movement disorders.

“You can’t move unless the motor circuit works,” Hickman��says. “When a doctor taps your knee to check your reflex, they’re testing that exact connection.”

The Future of��‘Human-on-a-Chip’��Technology

The researchers believe their approach will become increasingly important as drug developers look for more��accurate��ways to study human disease.

Because the models use human cells and measure real biological��function, they can reveal effects that may not appear in animal studies.

For Hickman, the work reflects��30 years of research to��better understand disease and help people.

“These systems let us study disease in a way that’s closer to what actually happens in the human body, and that’s what we need to develop better treatments,”��he says.

Research reported in this article was supported by the National Institutes of Health’s National Institute on Aging under award number R01AG077651 and R44AG071386. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health

“�鶹ԭ�� is being trusted to lead, and Barry’s investment reinforces that �鶹ԭ�� is a place where talent is developed at scale, where opportunity is expanded, and where our graduates don’t just succeed in the world — they come back to help build what’s next.” — Alexander N. Cartwright, �鶹ԭ�� President

The investment will accelerate a bold new model of business education designed for a world where technology, data and decision-making are inseparable, and it will position �鶹ԭ�� as a national leader in emerging fields that prepare students to lead with the skills the marketplace demands.

“This is a defining moment for �鶹ԭ�� and for the College of Business,” says Board of Trustees Chair Alex Martins ’01MBA. “As an alumnus, I have seen firsthand how �鶹ԭ�� transforms lives by opening doors to opportunity, and this extraordinary gift takes that mission to an entirely new level, giving future generations of Knights access to a world-class business education and an opportunity to achieve their full potential.”

“We are deeply grateful to Barry for his extraordinary belief in this university and in the impact our students make. This is a defining moment for �鶹ԭ�� and a powerful signal of who we are and where we are going,” says �鶹ԭ�� President Alexander N. Cartwright. “�鶹ԭ�� is being trusted to lead, and Barry’s investment reinforces that �鶹ԭ�� is a place where talent is developed at scale, where opportunity is expanded, and where our graduates don’t just succeed in the world — they come back to help build what’s next.”

“�鶹ԭ�� gave me the opportunity to build my future,” Miller says. “This investment is about creating that same opportunity for others — and ensuring students are prepared for a world where technology and business are constantly evolving.”

A Defining Moment for �鶹ԭ��

Few universities of �鶹ԭ��’s��young��age��have alumni giving back at this level.

At the center of this��milestone��is longtime��supporter and entrepreneur Barry S. Miller,��president of��the Florida-based����and��Voloridge��Health.��Miller is��a first-generation��college��graduate whose early partnership and belief in the university helped accelerate �鶹ԭ��’s trajectory.

His leadership and commitment to widening��opportunity helped lay the groundwork for a future-focused strategy that will transform how students learn, innovate and launch their careers. Miller’s��latest��investment reflects �鶹ԭ��’s ability to��produce��talent that succeeds at the highest levels and inspires��that talent to return��not just with pride, but with capacity and conviction to shape��what’s��next.

Building the Future of Business Education

“�鶹ԭ�� gave me the opportunity to build my future. This investment is about creating that same opportunity for others.” — Barry Miller ’95, ��Voloridge Investment Management and Voloridge Health president

will��operate��as a hub for technology-driven business leadership where students, faculty and industry collaborate in real time to solve complex challenges��in emerging fields like artificial intelligence,��fintech��and digital risk.

The focus is not simply on technical skills, but on empowering graduates to take action to address organizational obstacles and lead in fields fueled by rapid technological change.

This vision is grounded in the region �鶹ԭ�� calls home.

Orlando has rapidly��emerged��as one of the nation’s fastest-growing technology hubs,��with��demand for talent in fintech and��AI continuing��to��evolve.��Across Florida, one of the largest clusters of banking and insurance firms in the country is fueling new opportunities in financial technology,��risk��and data-driven decision-making.

�鶹ԭ�� sits at the center of this momentum,��uniquely positioned to develop the talent and ideas that will power��the future.

The investment will support��a multi-phase strategy designed to position �鶹ԭ�� as��the��destination for business and technology education, including:

• Five endowed faculty chairs in fintech, AI strategy, cyber risk,��trust��and disinformation
• A new��master’s��in��technology��leadership and��innovation
• Expanded access to applied learning, including internships, simulations, Bloomberg��training��and industry-led projects
• Growth of �鶹ԭ��’s corporate partnership ecosystem.

Together, these investments will create a learning environment that mirrors modern workplaces — fast��moving, data��driven and deeply connected to industry.

“Technology is advancing rapidly, and the real opportunity is in how organizations use it to perform,” says��College of Business Dean��Paul��Jarley. “This investment allows us to build a business school focused on how the work actually gets done��—–��where students learn to apply judgment, navigate ambiguity, and lead in environments shaped by technology, data, and organizational complexity.”

Accelerating Momentum

Miller’s leadership gift��marks a milestone in����— a��$3.5 billion��campaign to��expand��opportunity,��advance��discovery,��and drive impact across the university.

It sets the tone��for what comes next,��accelerating the pride and vision that will inspire others to invest in �鶹ԭ��’s future.

“This is what momentum looks like,” says��Rodney Grabowski, senior vice president for advancement and partnerships and CEO of the �鶹ԭ�� Foundation. “It reflects confidence in �鶹ԭ��’s vision and signals to partners, alumni and investors that this university is building something meaningful and worth being part of.”

Together, talent, opportunity and partnership are converging,��positioning���鶹ԭ����to��be a leading force in shaping��what’s��next in business,��technology��and innovation.

“�鶹ԭ�� is not waiting to be recognized. We are being chosen, invested in and trusted to lead,” Cartwright says. “This milestone gift reflects a growing sense of pride across the university and signals the momentum others will want to help build — and it is only the beginning.”

Now, the U.S. Department of Energy (DOE) has taken notice.

Deneé Lichtenberg was awarded the DOE’s Science Undergraduate Laboratory Internship, giving her the opportunity to further her research at Los Alamos National Laboratory in New Mexico. This premier multidisciplinary research institution is advancing breakthroughs in science and technology to address national security challenges.

The opportunity brings her closer to achieving one of her biggest goals: working at a national laboratory, where she’ll collaborate with experienced researchers and learn how large-scale scientific projects are conducted.

Raised in Titusville, less than an hour away from �鶹ԭ��’s main campus, Lichtenberg says she always knew she’d attend �鶹ԭ��, especially given the strength of its engineering programs. What she didn’t yet know was how far that decision would take her.

“The ability to design and improve materials that impact a variety of fields really motivated me to pursue this discipline.”

She found her path in materials science — a field where physics, chemistry and engineering intersect — which would allow her to study materials from the atomic level to real-world applications.

“Ultimately, everything is made up of materials,” she says. “By changing a material’s structure or composition, you can drastically alter its performance. The ability to design and improve materials that impact a variety of fields really motivated me to pursue this discipline.”

That curiosity has evolved into something bigger: tackling the challenge of sustainably recovering rare earth metals that are vital to the future of energy and technology.

Advancing Sustainable Extraction

Over the past year in the , led by Assistant Professor of Engineering Kausik Mukhopadhyay, Lichtenberg has focused on a breakthrough approach that uses a naturally occurring protein, lanmoudulin.

“The protein can capture rare earth elements from dilute waste streams, and then a small temperature change can trigger the protein to release them so they can be collected,” she says. “This could create a more energy-efficient and environmentally friendly way to recover valuable materials.”

Those materials are critical to everything from renewable energy systems to manufacturing; however, traditional extraction methods rely heavily on large amounts of energy and chemicals sourced from acid mine drainage, coal byproducts and electronic waste.

Lichtenberg’s work points to a sustainable future.

“By developing protein-based systems that selectively capture and release these elements, we could potentially reduce the reliance on traditional extraction,” she says.

At Los Alamos National Laboratory, Lichtenberg will take that work further, designing modified proteins, producing them in the lab and testing how effectively they bind and release rare earth elements.

“It is a very exciting interdisciplinary project that combines protein engineering, materials science and sustainability,” she says. “I hope to continue this research after the internship ends.”

It Takes a Lab — and a Team

But just as impactful as the research has been, the environment that’s shaped it has been.

“Dr. Mukhopadhyay is a fantastic mentor who creates a very supportive and positive environment that encourages learning [both] in and out of the lab,” Lichtenberg says. “The graduate students in the lab have [also] played a huge role in … helping me learn new techniques and [understand] the experiments and science itself.”

Next, she plans to continue her journey as a Knight by pursuing a doctoral degree at �鶹ԭ��, advancing her research as a graduate member of the KM Lab.

For Lichtenberg, this internship isn’t the finish line — it’s just the beginning of reimagining how the world sources its most essential materials.

Presented by the SCHOTT Group and the Ernst Abbe Fund, the award recognizes outstanding contributions to research and technology in glass, glass-ceramics and advanced materials. Richardson shares this year’s honor with Iowa State University researcher Steve Martin.

Together, their work reflects how advances in material structure can translate into real-world applications across industries including healthcare, energy, electronics and advanced technologies.

A Career of Innovation

Over the course of her career, Richardson has focused on advancing the science of optical materials, helping to expand how glass can be used in increasingly complex and demanding environments.

Her work has contributed to the development of materials that can be precisely engineered for performance, supporting innovations in imaging, sensing and optical systems.

“This award recognizes a lifetime of investment in know-how, specialized facilities creation and professional development of skilled personnel, which has resulted in unique prototype materials and technology development,” Richardson says. “These efforts have resulted in products that have gone on to be licensed to partners in this critical application space. I am truly honored to be recognized by one of the global leaders in advanced optical materials for our team’s sustained work in IR materials.”

Advancing Optical Materials

Richardson is recognized for her contributions to the development of optical glasses and infrared materials — specialized materials that control how light is transmitted and detected.

Her research focuses on designing glass compositions at the atomic level to achieve precise optical properties, enabling high-performance systems for infrared imaging, sensing technologies and advanced optics.

“Dr. Richardson’s sustained career has driven significant advancement in infrared material technologies, laying the foundation for next-generation sensing capabilities,” says Winston Schoenfeld, vice president for research and innovation at �鶹ԭ��. “Her relentless pursuit of discovery in optical and infrared materials illuminates �鶹ԭ��’s expanding impact on the frontiers of advanced technologies that continue to shape the future.”

From Fundamental Science to Application

The Otto Schott Research Award highlights the critical connection between fundamental research and industrial application, a hallmark of Richardson’s work. By advancing how glass materials are engineered and processed, her research helps expand the performance limits of existing materials while opening the door to entirely new classes of optical systems.

These innovations include glasses with improved infrared transmission and tailored properties that support emerging technologies in fields including aerospace, electronics, energy production and medical technologies.�� Her work has benefited from diverse support ranging from government to industry (local and international) as well as state funding from Florida’s High Technology Corridor (FHTC) which has provided extensive matching funds that have leveraged state funds to support education and training of several dozen graduate and undergraduate students from the Richardson group, over her career.

Why Infrared Materials Matter

Infrared materials play a critical role in technologies that rely on detecting and transmitting light beyond the visible spectrum. These systems are used in applications ranging from medical diagnostics and environmental monitoring to advanced imaging and sensing technologies.

Unlike conventional optical materials, infrared (IR) glasses must be carefully engineered to maintain transparency and performance under demanding conditions, including extreme temperatures and radiation.���� Their chemistry is difficult requiring specialized facilities unique to �鶹ԭ��, present in the University’s Optical Material Laboratory, which houses the Glass Processing and Characterization Laboratory (GPCL). ��As a result, workforce training in such novel optical material science benefits not only local industry, a stronghold in IR optical materials manufacturing and systems, but government agencies as well.

Richardson’s work focuses on developing glass compositions that meet these challenges while offering greater flexibility than traditional crystalline materials, which are often more expensive and difficult to manufacture.

By enabling more adaptable and scalable materials, her research supports continued advances in imaging systems, sensing technologies and other applications that rely on precise optical performance.

A Global Recognition

The award, endowed with about $29,000, was presented April 13 during the annual meeting at the International Commission on Glass in Lyon, France.

“The research of Steve Martin and Kathleen Richardson clearly shows how essential a deep understanding of material structures is for technological progress,” says Matthias Müller, head of research and development at SCHOTT. “These insights form the basis for developing new glass solutions that perform reliably in real-world applications and expand the boundaries of what is possible.”

Awarded every two years, the Otto Schott Research Award recognizes scientists whose work bridges scientific discovery and practical innovation.

About the Awardee

Richardson is a �鶹ԭ�� trustee chair and Pegasus Professor of optics and materials science and engineering in CREOL. She is also Director of �鶹ԭ��’s Glass Processing and Characterization Laboratory (GPCL).

She earned her bachelor’s degree in ceramic engineering and her master’s and doctoral degrees in glass science from Alfred University. Richardson has spent more than two decades at �鶹ԭ��, following earlier work at Clemson University.

Under a high-stakes, simulated cyberattack and mounting pressure, the �鶹ԭ�� Collegiate Cybersecurity Competition (C3) team proved it can defend, adapt and outperform — earning first place at the 2026 Southeast Collegiate Cyber Defense Competition (CCDC).

The team rose above nine competitors, including Tennessee Tech University, Clemson University, the University of South Florida and the University of Florida. With the win, �鶹ԭ�� advances to the National Collegiate Cyber Defense Competition, which will be held virtually next month.

Twelve students make up this year’s C3 team: sophomore information technology (IT) majors Gabriel Edwards and Maksim Shostak; junior IT majors Logan Autry, Anthony Donnelly, Joseph Durand, Adam Raczynski and Jonathan Styles; senior IT major Ardian Peach; sophomore computer science major Tyler Waddell; junior computer science major Benjamin Williams; cyber security and privacy master’s student Andy Pompura ’23; and senior prelaw major Noah Magill, who serves as team captain.

�鶹ԭ��’s Legacy of Cybersecurity Success

Their stellar performance marks �鶹ԭ��’s ninth first-place finish at the Southeast CCDC regional since 2013. �鶹ԭ�� earned runner-up finishes in 2017 and 2025, along with first-place titles in special at-large CCDC regionals during the COVID-19 pandemic in 2020 and 2021.

“�鶹ԭ�� has historically maintained high service availability levels while under attack by the red team.” — Tom Nedorost ’02MS, senior instructor and C3 team coach

The team not only clinched the top spot but also swept all three categories, winning Best in Uptime Service, Best in Business and Best in Defense.

“�鶹ԭ�� has historically maintained high service availability levels while under attack by the red team,” says Tom Nedorost ’02MS, C3 team coach and senior instructor of computer science and IT. “We lived up to that expectation again this year, which resulted in winning the Best in Uptime Service award.”

Nedorost adds that the team strengthened its ability to complete technical service requests while hardening systems against vulnerabilities to protect their network, key improvements that led to the two additional category wins.

Putting Cyber Defense Skills into Practice

At each competition, teams are tasked with defending a fictional company’s network against cyberattacks launched by red team members attempting to infiltrate it. All the while, competitors must maintain business operations and respond to customer service requests.

Each obstacle mimics real-world scenarios cybersecurity professionals face, allowing competitors to demonstrate their technical skills, business acumen and ability to collaborate.

It’s fun to go up against people [who, collectively,] would be a force to reckon with in the cyber world .” — Noah Magill, prelaw major and C3 team captain

Magill says the Southeast CCDC is among the most competitive, with red team members from leading companies such as Amazon Web Services and Cisco.

“All of them put together make up one of the scariest real-world life adversaries,” Magill says. “It’s fun to go up against people [who, collectively,] would be a force to reckon with in the cyber world — and a lot of [them] are [�鶹ԭ��] alumni.”

Next Up: Nationals

As the team sets its sights on the national competition, the work is far from over. Magill says a few more 100-hour weeks are likely ahead.

“Everyone on the team is incredibly adept at what they do and world-class [in] their specialty,” Magill says. “Leading this team [and relying] on such amazing teammates with such a diverse amount of skills has been really awesome.”

Justin Press ’24, a �鶹ԭ�� photonic science and engineering major, may have developed a solution that benefits both employers and applicants. His brainchild, Hire Match AI, is an analytics layer that integrates with existing applicant tracking systems to better analyze and interpret hiring data.

“We reparse resumes, structure candidate data more accurately and use statistics to identify which combinations of skills and experiences tend to stay longer and perform better in a company over time,” Press says. “That helps teams look past what I call ‘checklist champion’ resumes, where a candidate appears perfect on paper but is really just optimized for a filter.”

Press says what sets his digital tool apart is its focus on analytics, fit and compliance.

From Frustration to Framework

He developed the idea as head of professional development for the Engineering Leadership and Innovation Institute — part of �鶹ԭ��’s College of Engineering and Computer Science — where students develop professional skills through a certificate program, specialized courses, maker spaces and mentorship. In that role, he helped students optimize their resumes for job listings and quickly realized the process wasn’t as straightforward as it seemed.

“At �鶹ԭ��, I was going through hundreds of applications and postings each year, and it became obvious how much of the process was turning into a game,” Press says. “That gave me a firsthand look at how inefficient and frustrating the process was for both applicants and the people trying to help them.”

Launching What Hiring Lacks

From that frustration came Hire Match AI. Press brought the idea to the Center for Entrepreneurial Leadership, where he received guidance on turning the concept into a business. Now, as he prepares for launch, several businesses have already expressed interest in using the platform to analyze their hiring data more deeply. Press says the goal is to make data analytics more accessible, no matter which ATS a company uses.

“The bigger vision is to make hiring more data-driven, more transparent and less dependent on surface-level filtering.”

“We want Hire Match AI to plug into every major ATS so companies can get better visibility into candidate fit, hiring patterns and compliance risk without having to switch the systems they already rely on,” he says. “Down the line, that means expanding into larger platforms like Workday and other major enterprise systems. The bigger vision is to make hiring more data-driven, more transparent and less dependent on surface-level filtering.”

Engineering with Purpose

Press says he was drawn to the field of photonic science and engineering by a desire to create technology that improves people’s lives. His advice to students with similar ambitions: focus on what makes their idea unique.

“For engineering students especially, having a wide range of experiences is a huge advantage,” Press says. “A lot of the best ideas come from [understanding] how technical problems connect to business problems, user behavior or broken systems in the real world. That matters even more now, with tools like large language models making it easier to build quickly.”

Companies interested in using Hire Match AI can or sign up for early access.

The National Leader in Emergency and Crisis Management

�鶹ԭ�� earned the No. 1 Homeland/National Security and Emergency Management Graduate Program ranking in the nation for the�� third consecutive year.

At the forefront of this year’s ranking is the College of Community Innovation and Education (CCIE)’s online emergency and crisis management program, signaling �鶹ԭ��’s long-standing leadership in programs that keep people safe from disasters of all kinds.

“To maintain the U.S. News No. 1 ranking of graduate programs in homeland security and emergency management is truly a team endeavor,” Associate Professor of Public Administration Yue ‘Gurt’ Ge says. “It reflects our nationally and internationally renowned faculty in education and research, our stellar students and alumni — who have become the backbone of the emergency management profession in Florida and beyond — and our signature staff members and advisory board representing government, nonprofit, and business sectors across Central Florida.”

That strong connection to practice is central to the program’s success. Faculty research influences policy nationwide, while students gain real-world insight through close partnerships with emergency managers at the local, state and federal levels. Graduates leave prepared to respond to complex crises, from natural disasters to public health emergencies, at a time when the need for highly trained professionals continues to grow.

A Top-10 School Preparing Student Counselors

�鶹ԭ��’s College of Community Innovation and Education also earned the No. 9 ranking for Student Counseling and Personnel Services Graduate Programs in the nation.

Recognition for CCIE’s student counseling�� graduate program reflects �鶹ԭ��’s high-touch faculty mentorship model and its emphasis on integrating research, service, and professional preparation.

For Benoit Aubin, a first-year doctoral student in counselor education, that support has been transformative. A former firefighter and medic, Aubin now works as a mental health clinician for his former fire station while serving as a graduate research assistant with �鶹ԭ��’s Marriage and Family Research Institute (MFRI).

With guidance from Department of Counselor Education and School Psychology Chair and MFRI Executive Director Sejal Barden, Aubin has conducted clinical research focused on trauma and relationship stress among first-responder couples. His work has already contributed to a funded grant, conference presentations, a published book and the development of a training program — achievements he credits to a highly supportive learning environment.

“�鶹ԭ�� knows how to prepare us to compete professionally,” Aubin says.

A 34-Spot Rise in Advanced Nursing Education

�鶹ԭ��’s College of Nursing jumped ��34 spots to No. 37 for Doctor of Nursing Practice Graduate Programs in the nation — the highest ranking in the college’s history.

�鶹ԭ��’s Doctor of Nursing Practice program (DNP) improved ranking reflects a continued investment in academic rigor, faculty expertise and hands-on clinical training designed to address the nation’s growing need for nurse practitioners.

Graduates from the DNP program consistently outperform national first-time pass rates on nurse practitioner certification exams. They also often receive job offers before they even complete their degrees, according to Christopher Blackwell ’00 ’01MSN ’05PhD, director of �鶹ԭ��’s adult-gerontology acute care nurse practitioner program. All full-time faculty hold at least one doctoral degree, more than half remain actively practicing clinicians and many are nationally recognized fellows. Through partnerships with healthcare organizations across Central Florida students gain applied experience alongside expert preceptors in varied clinical settings.

“The incredible amount of support I’ve received from �鶹ԭ��’s nursing professors and the opportunities to make an impact through my research and clinical practice solidified that I made the best choice in my graduate degree,” says Mimi Alliance ’21, a family nurse practitioner doctoral student who provides care and conducts research on the �鶹ԭ�� Mobile Health Clinic.

Some of that training is anchored in the college’s Helene Fuld Health Trust STIM Center, an internationally recognized simulation facility that strengthens clinical skills and decision-making before students enter patient-care environments. The STIM Center, as well as �鶹ԭ��’s nursing programs, are housed in the Dr. Phillips Nursing Pavilion, which opened in Lake Nona in Fall 2025 thanks to generous state and industry support — a proof point of �鶹ԭ��’s ability to solve real-world issues.

Building on a Legacy of Aerospace Engineering Excellence

As Florida’s Technological University, �鶹ԭ�� continues to build on our strength in technology-driven fields by ranking No. 38 for Aerospace Engineering Graduate Programs in the nation.

The �鶹ԭ�� College of Engineering and Computer Sciences‘ aerospace engineering graduate program ranking reinforces the university’s legacy in a field deeply tied to Florida’s Space Coast and NASA’s recent Artemis II launch.

“It is gratifying to see the hard work and exciting research of our faculty and students recognized by our peers,” says Associate Professor of Mechanical and Aerospace Engineering Jeffrey Kauffman, noting that since launching the aerospace engineering doctoral program in 2019, �鶹ԭ�� has steadily climbed in rankings while program enrollment has grown to more than 100 doctoral students.

Fueling that growth are advances in hypersonic flight, space exploration and defense research, with �鶹ԭ��’s HyperSpace Center serving as a catalyst for interdisciplinary collaboration. Faculty success in securing competitive federal research funding has strengthened infrastructure and expanded opportunities for both graduate and undergraduate students.

The result is a vibrant research environment where students engage directly in cutting-edge projects and build industry connections well before entering the workforce.

Across disciplines, �鶹ԭ��’s growth in the U.S. News & World Report’s graduate rankings reflects a shared commitment to student success — driven by faculty who mentor closely, curricula that align with real-world needs and an institutional culture focused on impact. As �鶹ԭ��’s graduate programs continue to climb, they reinforce the university’s role as a national leader preparing professionals to tackle society’s most urgent challenges.

That’s because every dollar ripples far beyond a single day. Every gift opens doors: for students to chase a dream, create unforgettable memories, boldly invent the future and be recognized for their hard work. And every donor does more than give — they ignite potential, spark inspiration and elevate Knights for generations.

With �鶹ԭ�� Day of Giving 2026 right around the corner — Thursday, April 9 — we’re reflecting on the transformational effects and personal stories of triumph that emerged from last year’s show of support, knowing that shortly, our collective contributions will set another wave of Black & Gold breakthroughs, successes and discoveries into motion.

Prioritizing Unique Opportunities

Area of Support: College of Engineering and Computer Science Dean’s Excellence Fund
Amount Raised: $67,421
Impact: Learning experiences

Growing up in rural Ohio, Jordan Hires, an aerospace engineering major and Burnett Honors College Scholar, often gazed at the boundless night sky, inspired by the astronauts from her home state of Ohio. Moving 1,000 miles away for college was daunting, but manageable. With her sights set on becoming a chief engineer for deep space flights, �鶹ԭ�� offered two key benefits: a renowned aerospace engineering program and proximity to NASA.

“It’s the best decision I’ve made,” she says.

Since becoming a Knight, she’s done backstage tours at NASA, met with industry leaders from Mitsubishi, Siemens Energy and Lockheed Martin, and even talked to a former astronaut at an awards ceremony. This past summer, she worked alongside Professor Kareem Ahmed in the Propulsion and Energy Research Lab as a U.S. National Science Foundation Research Experiences for Undergraduates (REU) fellow, testing a solution to remove heat from engines — research that could make hypersonic aircraft safer and cheaper. It was her second research experience as an undergrad.

“I don’t know if it’s every little girl’s dream to work on classified projects with military and civilian applications, but it definitely was this little girl’s dream,” she says. “Thanks to �鶹ԭ��, I’ve had experiences that most students don’t get until graduate school.”

Many of those opportunities are made possible by the College of Engineering and Computer Science Dean’s Excellence Fund, which supports hands-on learning, cutting-edge research equipment and innovative initiatives.

Supporting Lasting Memories

Area of Support: Marching Knights Scholarship Fund
Amount Raised: $14,067
Impact: Multiple scholarships for band members

For �鶹ԭ�� Marching Knights President Zoie Taverna, two moments define her �鶹ԭ�� experience: the rush of running onto the field for her first game and the bittersweet joy of singing the alma mater song alongside her best friend for their final game before graduation.

“For three whole years, we stood next to each other in the stands, screaming, feeding off each other’s energy,” Taverna says. “For her last game, we went all out. We couldn’t even talk by the end of it. We cried while singing the alma mater.”

Taverna is among the Marching Knights whose experiences at �鶹ԭ�� are bolstered by the Branen Band Endowed Scholarship, which helps cover essentials like textbooks, meals and rent that her Bright Futures scholarship does not. As a mechanical engineering major, band leader and corresponding secretary for the national chapter of Kappa Kappa Psi, she packs her days with coursework, practice and student engagement.

During the summers, she works full-time at a summer camp for kids, and she spends her weekends and evenings at Panera Bread to save up enough to cover the expenses to allow her to stay focused while in school.

“Without scholarships, I wouldn’t have the time to do extracurriculars, such as Marching Knights, where I get to represent �鶹ԭ�� in Central Florida and around the world,” she says. “And I wouldn’t get to spend every Saturday in the Bounce House with all of my friends, immersed in the band life we love.”

Illuminating Pathways

Area of Support: College of Optics and Photonics (CREOL)
Amount Raised: $54,880
Impact: $4,880 Went Toward Supporting 19 scholarships for attendees

This summer, high school student Chloe Phung left the bright lights of Ho Chi Minh City, Vietnam, to spend a week immersed in the study of light on �鶹ԭ��’s campus. As part of the third Laser and Photonics Summer Camp hosted by CREOL, she joined more than 50 high school students from across Central Florida — and around the world.

“I had the chance to learn many things, to learn more about optics, lenses and lasers,” Phung says.

In addition to learning opportunities, the camp shines a light on the photonics industry, where more than 10,000 jobs open each year in the U.S., despite only 80 to 100 students in the nation graduating with bachelor’s degrees in photonics annually. A third of those graduates come from CREOL.

Paying it Forward

Area of Support: Dr. Michelle R. Dusseau Communication and Community Impact Endowed Scholarship Fund
Amount Raised: $1,780
Impact: $1,500 scholarship for one communication major, awarded annually

Beatrix Alerte transferred to �鶹ԭ�� in Spring 2024 with a plan: build community on campus, explore a career in media, stay active in service and say yes to every opportunity.

The first three goals came naturally. She enrolled in classes, mentored two freshmen as part of the �鶹ԭ�� chapter of Big Sister Little Sister mentoring program and served as a trip coordinator for the Alternative Spring Break Program. Alerte also gained work experience as a marketing ambassador for Project BEST, a Student Support Services project that supports first generation students, and as an intern with �鶹ԭ�� Athletics.

Her final goal was made easier this summer when Alerte was named the inaugural recipient of the Dr. Michelle R. Dusseau Communication and Community Impact Endowed Scholarship, created this past year by longtime the College of Science‘s Nicholson School of Communication and Media faculty member Michelle Dusseau.

“This scholarship has given me the freedom to say yes to career-building opportunities, many of which are unpaid, while worrying less about covering

personal living expenses,” Alerte says. “That support makes all the difference.”

This �鶹ԭ�� Day of Giving, we’re launching Knights to new heights! Save the date to on Thursday, April 9, 2026. Check out the to maximize your impact. And get ready to join your Knight Nation family as we Bounce, Stomp, Splash and Cheer our way to more impact than ever before.

The mission will include multiple health studies on the four astronauts to determine how radiation, microgravity, isolation and other factors impact their physical health, mind and behavior — crucial information that will help pave the way for future lunar surface missions and develop our understanding about humans’ deep space capabilities.

Thanks to new technology and modern medicine, researchers have better ways to understand the impact of space flight on human health.

“Artemis II is both a historic and biomedically important mission,” says ��Emmanuel Urquieta, the �鶹ԭ�� College of Medicine’s vice chair for aerospace medicine and director of the university’s new Center for Aerospace and Extreme Environments Medicine (CASEEM).

“For the first time since Apollo 17, humans will travel beyond the Earth’s magnetic field. That matters enormously from a research perspective, because now we have technology to thoroughly understand the health impact of embarking into deep space. The knowledge gained from Artemis II will help shape the future of safe human space exploration and drive innovations that can benefit medicine here on Earth and help us start preparing us for a mission to Mars.”

The Space Coast’s College of Medicine

As the closest medical school to the Kennedy Space Center, �鶹ԭ��’s College of Medicine is charting a new frontier in healthcare as humans prepare for longer missions to the moon and Mars, and commercial space flights take more civilians into space.

The goal: explore how factors such as microgravity, radiation and isolation impact the human body in space and how that knowledge can drive innovation into diagnostics, treatment and disease prevention on Earth.

To further those efforts, �鶹ԭ��’s CASEEM includes faculty experts in medicine, engineering, computer science, psychology, arts and educational leadership. This interdisciplinary group will work together to research and develop new technologies for keeping space travelers healthy, as well as soldiers on military missions, deep sea explorers and mountain climbers.

What Lies Ahead for Artemis II’s Astronauts

• Understanding Radiation Exposure Effects

Traveling to the moon — which humans haven’t returned to since 1972 — means astronauts will go beyond Earth’s Van Allen belts, which protect humans from cosmic radiation and solar storms. Space travelers to the International Space Station stay within Earth’s magnetic field. During their 10-day mission, Artemis II is anticipated to break Apollo 13’s record (248,655 miles) for the farthest distance humans have traveled from Earth.

Fifty years ago, researchers could do little more than measure radiation. This time will be different, says �鶹ԭ��’s William “Ed” Powers, chief medical officer of CASEEM and the former chief of NASA’s Medical Operations branch where he was a primary medical support physician for six shuttle missions.

“Medical knowledge, technology and the ability to diagnose disease have advanced significantly since then,” he says.

Physicians and scientists will be able to determine how radiation impacts cells, organs, blood proteins and other molecular functions.

Artemis crew members will carry dosimeters in their pockets that measure radiation exposure in real time. Monitors inside the Orion spacecraft will also gather radiation information throughout the flight for future analysis.

An astronaut suffering a medical condition in space is always a concern, but deep space travel brings additional challenges, Powers explains. While astronauts on the International Space Station can be returned to Earth in about a day, as happened recently when a crew member became ill, returning from the moon may take several days or more.

“None of the four astronauts on this flight is a physician,” Powers says. “And a space capsule certainly doesn’t have the same equipment you’d have in a hospital emergency room.”

• Does Space Flight Reduce Immunity?

Previous research has shown that spaceflight missions alter the and reactivate dormant viruses in the human body. As part of the Artemis II mission, NASA will conduct an AVATAR (A Virtual Astronaut Tissue Analog Response) experiment that will investigate how deep space impacts specific cells and tissues as well as some vital bodily functions including immune system responses.

For this experiment, NASA-funded scientists created “organ-on-a-chip” devices that contain each astronaut’s bone marrow cells. This technology allows scientists to examine molecular changes and cell function.

“With this technology we can see how the body responds to stimuli across the whole mission,” says Jennifer Fogarty, CASEEM’s chief scientist who came to �鶹ԭ�� after serving as chief scientist for NASA’s Human Research Program. “This capability will help us map the body’s molecular changes with tissue/organ function and much better predictive capabilities.”

As the “organ-on-a-chip” technology advances and proves accurate, it will allow NASA physicians to provide personalized and proactive medicine to astronauts because they will be able to predict a crew member’s biological response to space flight. Such technology could be used before NASA sends an actual crew to Mars. The space agency could place the crew’s personalized chips on unmanned flights to the Red Planet to better understand the potential health risks for each individual.

“It’s basically sending small versions of astronauts to Mars before we send astronauts to Mars,” Fogarty says.

• Teamwork and Behavior

Selecting an astronaut crew that will perform well under the stresses of space flight is always a top NASA priority. But deep space missions present additional personnel challenges, including communication delays, increased isolation and resource constraints.

Astronauts on moon and Mars missions also must live in a capsule that is significantly smaller than the International Space Station, highlighting the need for crews to work together seamlessly and be able to manage any conflicts.

The Artemis flight will conduct an experiment called ARCHeR (Artemis Research for Crew Health and Readiness) that will evaluate how astronauts perform individually and as a team during the mission.

They will wear sleep and movement monitors before, during and after the mission to evaluate their cognition and team dynamics.

“You watch the astronauts on TV, and it looks so easy,” Fogarty says. “But human performance is critical in space. You have multiple duties to conduct and you’re always pushing operations. So we need to understand how the team performs, their reserve and resilience. The mission itself is the experiment.”

Star Nona 2026

�鶹ԭ��’s leading space medicine experts, valued strategic partners and an astronaut who holds NASA’s record for spacewalks will gather April 10 in Lake Nona’s Medical City to discuss how they can work together to keep space travelers healthy and use that research to create groundbreaking clinical innovations on Earth.

The “Star Nona 2026” event is led by the Lake Nona Research Council, which is focused on encouraging interdisciplinary scientific partnerships between industry, academia and healthcare.

The council includes physicians and researchers from �鶹ԭ��, Orlando Health, AdventHealth, the Florida Space Institute, the Orlando VA Medical Center, Nemours Children’s Health, business and industry.

For more information, including how to register for the event, visit www.ucf.edu/news/progressing-the-final-frontier-of-medicine-space.

Big ideas don’t wait — and neither do the researchers behind them.

The 2026 Reach for the Stars honorees — six �鶹ԭ�� assistant professors — are already making a substantial impact on their respective fields through meaningful research and creative work that extends far beyond campus, with national and international influence.

Across disciplines, their work and research reflect a shared mission to advance ideas into impact — uncovering what shapes ethical decision-making in the workplace; exploring the origins of our solar system; developing computational solutions to meet future energy demands; designing more intuitive and reliable software experiences; strengthening education for students with disabilities; and engineering faster, more energy-efficient artificial intelligence (AI) systems.

Together, this brilliant group represents the kind of bold, forward-thinking innovation �鶹ԭ�� continues to champion.

Each year, the Reach for the Stars awards recognize early-career faculty opening new doors for what’s possible across their fields. The prestigious award is second only to Pegasus Professor as �鶹ԭ��’s highest faculty honor.

In recognition of their achievements, each honoree will receive a $10,000 annual research grant for three years in addition to the distinction of being an award recipient.

The �鶹ԭ�� community is cordially invited to come and congratulate the recipients from 3-5 p.m. Wednesday, April 1, in the Pegasus Ballroom at the Student Union as part of the 2026 Founders’ Day Faculty Honors Celebration.

This year’s Reach for the Stars honorees are:

John Bush

Assistant professor of management in the College of Business

What’s something few people know about you?

Working at �鶹ԭ�� is a homecoming for me. Growing up in Florida, I had the opportunity to experience all the great things this state and its universities have to offer. And while my younger self might not have predicted I’d end up in Black & Gold, �鶹ԭ�� and Orlando have been incredible homes.

What does your research focus on?

I study when, why, and how employees cross ethical lines, and what role leaders, management policies, and organizational systems play in those decisions. A big part of what makes my work unique is that I focus on an important puzzle: how things we typically think of as “good” can promote unethical behavior. We tend to assume that well-intentioned management practices will always lead to good outcomes. However, my research shows that’s not always the case, and the unintended consequences can be significant.

What drives you to take on this challenge?

Before I entered academia, I worked in corporate finance and accounting. That experience meaningfully shaped how I think about ethics in organizations.

There’s a common assumption that unethical behavior is a “bad apple” problem, or rather, that it comes down to an individual’s character or integrity. But as my work has shown, it’s often a “bad barrel” problem. The environments organizations create, the systems they put in place and the ways managers approach leadership profoundly influence how people behave.

What makes �鶹ԭ�� the right place for you to do this kind of work?

I’m a firm believer that the people make the place — and the faculty, staff and students of �鶹ԭ�� are truly what make it such a great place to be. The College of Business has a management department full of colleagues who are both excellent scholars and genuinely collaborative people.

What’s next for you or your research?

I’m excited about several new directions, each of which builds upon my existing work. I’m particularly interested in examining more nuanced, less studied drivers of ethical decision-making. For example, what happens when someone becomes an accidental witness to unethical behavior? How does that experience shape what they do next and the moral burden that’s placed on them?

Ana Carolina de Souza-Feliciano

Assistant professor at the

What’s something few people know about you?

While many people know I’m not afraid to face challenges, few know that I’m afraid of roller coasters.

What does your research focus on?

I study the small bodies of our solar system (objects such as asteroids, Trojans and trans-Neptunian objects) from an observational perspective to try to understand how our planetary system formed and evolved. The small bodies that remain from the early solar system still preserve clues about the materials and conditions that existed when planets formed. By observing their surfaces, compositions and physical properties, we can piece together the history of how the solar system came to be.

What drives you to take on this challenge?

The solar system still holds many unanswered questions, and every observation has the potential to reveal something completely new about its history. I’m especially motivated by the idea that these small and distant objects preserve a record of the earliest stages of planetary formation, and since we still don’t know much about them, we need to better characterize these groups to have a chance of getting closer to important scientific answers.

What makes �鶹ԭ�� the right place for you to do this kind of work?

�鶹ԭ�� provides a dynamic research environment with strong collaborations and access to facilities that help me achieve my scientific goals.

What’s next for you or your research?

I aim to expand my research group and continue developing new projects exploring the composition and physical properties of small bodies in the outer solar system.

Shyam Kattel

Assistant professor of physics in the College of Sciences

What’s something few people know about you?

I enjoy long, quiet walks or runs. It’s when I do my best thinking and come up with new ideas for teaching and research.

What does your research focus on?

My research group is interested in understanding chemical processes through computer simulations. These chemical processes are central to many energy and fuel generation and energy conversion processes. We are exploring the design of catalytic materials that selectively convert abundant small molecules, such as CO2, N2, NO3, O2 and H2O, to a wide variety of synthetic chemicals and fuels in a carbon-neutral way to fulfill the growing energy demand of the future.

What drives you to take on this challenge?

I’m a huge advocate of sustainability. I’m fascinated by the rapid development and advancement of modern computers, machine learning (ML) and AI, which have enabled us to understand complex science on a time scale that’s impossible with traditional trial and error methods. This unique opportunity to utilize supercomputers with ML and AI to tackle energy and sustainability challenges keeps me awake at night.

What makes �鶹ԭ�� the right place for you to do this kind of work?

By training, I’m a physicist, but my research focuses on looking into chemical reactions. �鶹ԭ��’s physics department is among a handful of institutions in the U.S. with a very strong catalysis program. This allows me to collaborate within the department and teach a physics course, which I enjoy. Additionally, the university’s large size and research facilities present opportunities to recruit the best students and to collaborate both within and beyond the department.

What’s next for you or your research?

My lab is developing capabilities to integrate ML and AI into our methods for understanding structure-materials property relationships across a large set of materials, driving the development of the next generation of clean and sustainable energy and fuel generation technologies. Our goal is to develop an integrated materials design framework that anyone can use for their research and for teaching research-based undergraduate and graduate courses.

Kevin Moran

Assistant professor of computer science in the College of Engineering and Computer Science, director of the Software Automation, Generation and Engineering Research Lab and affiliate of the Cyber Security and Privacy faculty cluster initiative

What’s something few people know about you?

I was a Division 1 rower as an undergraduate at the College of the Holy Cross. Our team competed in the national championship regatta my senior year and was ranked among the top 20 teams in the country.

What does your research focus on?

If you’ve ever been frustrated by glitches in apps or websites, my students, collaborators and I aim to give engineers the tools they need to build more reliable software. My group has pioneered work in user interface engineering, focusing on user-facing systems and making software easier to use.

What drives you to take on this challenge?

Since I was young, I’ve enjoyed building things, taking them apart and understanding how they work. I view software as the ultimate engineering medium, where abstract ideas can quickly become reality. What excites me most is tackling the complexity of modern software systems by developing tools that engineers can easily adopt. Seeing those tools save engineers hours or days of time is truly fun.

What makes �鶹ԭ�� the right place for you to do this kind of work?

�鶹ԭ�� has been an excellent place to grow as an early-career researcher. I’ve received invaluable mentorship from department and college leadership, as well as senior faculty. The university’s connection to the local tech industry is also exciting, and I look forward to forming connections with local companies to put our tools into practice.

What’s next for you or your research?

Software engineering is rapidly shifting toward agentic workflows, where AI-powered agents perform engineering tasks autonomously. While this increases speed, it also introduces complex errors that are harder to spot. My lab aims to understand these software engineering agents, improve their reliability and create tools that help developers use them effectively.

Soyoung Park

Assistant professor of teacher education in the College of Community Innovation and Education (CCIE)

What’s something few people know about you?

When I travel for conferences, I love to explore local bookstores and cafes.

What does your research focus on?

My research focuses on transforming educator preparation to better support students with disabilities. Supported by more than $3.75 million in U.S. Department of Education funding, my work prepares special education teachers, speech-language pathologists and school psychologists to serve students with autism spectrum disorders and high-intensity needs. I also develop evidence-based mathematics interventions for students with learning disabilities.

What drives you to take on this challenge?

Mathematics remains an area where both research and practice need stronger alignment. Teachers need accessible, evidence-based guidance on how to teach effectively, but it isn’t always easy to find or interpret. Students need consistent access to high-quality instruction that meets their individual needs. I’m interested in helping bridge that gap so that research can better support educators and the students they serve.

What makes �鶹ԭ�� the right place for you to do this kind of work?

�鶹ԭ��’s strong infrastructure for research and collaboration further amplifies my work. Support from the Office of Research has been instrumental in advancing my research development, grant capacity and interdisciplinary collaboration. As a CCIE research fellow and affiliated faculty member at the Toni Jennings Exceptional Education Institute, I have valuable opportunities to engage in interdisciplinary collaboration across colleges.

What’s next for you or your research?

Our next project focuses on synthesizing large data sets to help educators identify mathematics interventions that align with their students’ needs. We’re also exploring how AI can support this process through pedagogical AI chatbots and interactive web-based platforms that guide educators in interpreting and applying research evidence in practice. Ultimately, this work aims to strengthen both instruction and student outcomes at scale.

Hao Zheng

Assistant professor of electrical and computer engineering in the College of Engineering and Computer Science

What’s something few people know about you?

I enjoy traveling, especially visiting national parks and exploring new cities. Each trip helps me recharge, and I often come back with fresh perspectives and new ideas.

What does your research focus on?

My research focuses on making today’s AI systems faster, more energy-efficient and more reliable by bridging the gap between algorithms and hardware. AI has reshaped daily life, but behind the scenes, modern AI models require enormous amounts of computation and energy. My work explores new ways to co-design hardware and software so AI can run efficiently, especially for irregular or sparse data structures, such as graphs.

What drives you to take on this challenge?

I’m driven by both the importance and the difficulty of the problem. We’re at the turning point of rethinking future computing systems. Defining a new computing paradigm, despite its challenges, can have a far-reaching impact across society. Our research can fundamentally reshape how future computers are designed and how AI is deployed at scale.

What makes �鶹ԭ�� the right place for you to do this kind of work?

�鶹ԭ�� is an ideal place to pursue bold research ideas, supported by strong momentum in engineering, computing and interdisciplinary collaboration. The university also offers an exceptional and supportive community of mentors and collaborators, including students, who set a high bar for excellence. I’ve been fortunate to work with many outstanding colleagues, and those experiences have shaped how I think about building a high-impact research program and growing as a scholar.

What’s next for you or your research?

Next, we’re expanding our work toward real-world deployments, including applications in healthcare and robotics. We’re also continuing to strengthen our research in building processors for AI and scientific computing so that our ideas can translate into improvements in performance and energy efficiency.