Penn Bioengineering Blog

Each year, the Department of Bioengineering at Penn Engineering proudly recognizes outstanding doctoral students whose research exemplifies innovation, impact, and academic excellence. The Solomon R. Pollack Award for Excellence in Graduate Bioengineering Research celebrates the achievements of students who have advanced our understanding of biological systems through engineering.

In 2025, four exceptional Ph.D. students—Nikolas Di Caprio, Harshini Chandrashekar, David Gonzalez-Martinez, and Kelsey Swingle—have been honored with this prestigious award. Their work spans neuroscience, oncology, maternal health, and tissue engineering, reflecting the breadth and interdisciplinary nature of the field.

Nikolas Di Caprio: Engineering Injectable Platforms for Cartilage Repair

Dissertation Title: “Engineering Dynamic Granular Composites for the Repair of Cartilage Tissue”

Nikolas Di Caprio earned his B.S. in Bioengineering with a minor in Chemistry from Temple University in 2019, where he conducted undergraduate research on 3D in-vitro models of adipose tissue. 

Building on this foundation, his doctoral work in Dr. Jason Burdick’s lab focused on developing an injectable system using stem cell aggregates and hydrogel microparticles to repair cartilage. His work addressed both the biological and mechanical aspects of tissue regeneration, incorporating automated testing tools he designed to probe particle mechanics. The research offers new strategies for minimally invasive musculoskeletal treatments.

“I would like to thank Jason Burdick for the nomination, the committee for selecting me for the generous award, and my family, friends, and previous advisors for all the support during my Ph.D.“

Nikolas’s research embodies the intersection of material science and regenerative medicine, pushing the boundaries of bioengineering innovation.

Harshini Chandrashekar: Mapping the Genome’s Architecture in Alzheimer’s

Dissertation Title: “Addressing the Genome’s Structure-Function Relationship in Neural Activation and Neurological Disorders”

Harshini Chandrashekar completed her B.Tech. in Biotechnology from Vellore Institute of Technology, India, before moving to the U.S. in 2017 to pursue a master’s degree in Bioinformatics at the Georgia Institute of Technology. In 2019, she joined Dr. Jennifer Cremins lab as a Computational Scientist and began her Ph.D. in Bioengineering at Penn in 2020. In the Cremins lab, she investigated how the three-dimensional genome architecture—particularly chromatin loops—regulates gene expression in the context of familial Alzheimer’s disease (FAD). Her innovative combination of experimental and computational approaches uncovered early-stage disruptions in genome folding that may precede classical disease hallmarks.

Her findings are available on bioRxiv and have already garnered accolades, including the Young Talented and Developing (TAD) Scientist Award from Genome Organization Australia and the Best Research Presentation Award at the 2024 Penn Bioengineering Graduate Research Symposium.

“I’m grateful to my Ph.D. advisor, Dr. Jennifer Cremins, for nominating me for this award and for her support — especially during the challenging moments that are part and parcel of everyday research.. I would also like to thank Dr. Yale Cohen, my thesis committee chair, for his support and encouragement over the years, and Dr. Erin Berlew, whom I had the pleasure of TAing for, for being a generous mentor and role model in teaching. Their support played a meaningful role in both my academic and professional growth at Penn.”

Harshini now works as a Bioinformatics Scientist at the Benaroya Research Institute in Seattle.

David Gonzalez-Martinez: Revealing Drug Tolerance Pathways in Cancer

Dissertation Title: “Dissecting Mechanisms and Consequences of Oncogenic RTK Fusion Signaling”

David Gonzalez-Martinez began his academic journey at Florida State University, where he studied biochemistry. He went on to earn a master’s degree in Microbiology and Cell Science from the University of Florida before joining the Bioengineering Ph.D. program at Penn

Under the mentorship of Dr. Lukasz Bugaj, he used synthetic biology, optogenetics, and live-cell imaging to explore how oncogenic RTK fusions drive aberrant signaling and evade cancer treatment. His research pinpointed key mechanisms underlying drug resistance and identified drug combinations that improve therapeutic response. His recent publication in Nature Communications highlights these findings.

“I would really like to thank the department for the recognition and Dr. Lukasz Bugaj, who has been a fantastic mentor throughout my Ph.D. as well as all of my lab mates who have been great friends and collaborators.”

David’s contributions provide crucial insights into the dynamic nature of cancer signaling and potential avenues for more effective treatments.

Kelsey Swingle: Targeting the Placenta to Treat Pre-eclampsia

Dissertation Title: “Engineering Placenta-Tropic VEGF mRNA Lipid Nanoparticles for the Treatment of Pre-eclampsia”

Kelsey Swingle earned her B.S.E. in Biomedical Engineering from Case Western Reserve University in 2020. As a Ph.D. student in the lab of Dr. Mike Mitchell, her research focused on developing new biomaterial strategies for targeted drug delivery to the placenta. Her dissertation work involved engineering VEGF mRNA lipid nanoparticles designed to home specifically to placental tissue, with the goal of treating pre-eclampsia—a major cause of maternal and fetal morbidity for which no clinical treatments currently exist.

“I’m incredibly grateful to my advisor Dr. Mike Mitchell, everyone in the Mitchell Lab, my mentors, friends, and family for their support throughout my PhD. While my PhD was both a rewarding and challenging personal experience, I leaned on and learned from my support system every step of the way.”

Her studies demonstrated the therapeutic potential of this targeted approach in mouse models, offering promising insight into a long-standing challenge in maternal health. In July 2025, Kelsey will begin a faculty position as Assistant Professor in the Department of Bioengineering at Rice University.

Looking Ahead

The 2025 Pollack Award recipients exemplify the best of Penn Bioengineering: rigor, creativity, and a drive to improve human health. Through their diverse research, each has made significant contributions to science and society. We congratulate Nikolas, Harshini, David, and Kelsey on their achievements and look forward to seeing how they will continue to shape the future of bioengineering.

2025 Team PRIME – Engineering a Smarter Response to Sepsis

The final feature in the 2025 Senior Design Awards Spotlight highlights Team PRIME, who earned Second Place at the Minnesota Design of Medical Devices Competition. 

Team Members: Majd Ayyad, Shriya Boyapati, McKenzie Davis, Sophie Gu, Sophie Klessel

Senior design in Penn Bioengineering is a yearlong capstone experience in which bioengineering seniors identify an unmet bioengineering need, design a solution to address the need, and create a high quality prototype that demonstrates their design. The course consists of BE4950 and BE4960, and was most recently taught by Dr. Erin Berlew, Dr. David Meaney, and Dr. Michael Siedlik.

For Team PRIME, the mission was clear: create a tool that could help detect sepsis earlier—when timing can mean the difference between life and death. Their project centers around a device that automatically measures capillary refill time, a simple but powerful indicator of blood perfusion and circulation quality. By providing continuous, automated monitoring, PRIME aims to improve clinical decision-making in intensive care units and emergency settings.

The team’s inspiration came from their clinical mentor, Dr. John Greenwood, whose passion for improving sepsis detection was contagious.

Sophie Klessel shared, “We had a great clinical mentor (Dr. John Greenwood) who was really passionate about creating a device for earlier detection of sepsis, and we knew we wanted to work with him. Additionally, sepsis was an issue that resonated with our group and an issue that we were excited about.”

Team PRIME approached the work with a strong sense of collaboration, blending individual strengths across software, hardware, and systems integration. One member led the development of the user interface and application logic, while another focused on designing and assembling the physical and electrical components.

Working on PRIME revealed to the team just how demanding and rewarding bioengineering can be.

“Bioengineers need to understand it all from interviewing clinicians for needs findings, to studying the physiology of the human body, to designing all the technical components including hardware and software and finally towards producing a medical device. It is such a difficult job to be all the engineers at once but the final results are rewarding!” Majd Ayyad explained. 

As the project concluded, their work was already gaining traction. Dr.  Michael Siedlik, one of the bioengineering senior design instructors, shares, “This technology could greatly surpass the current standard of care, as it provides much needed automation, reproducibility, and clinician-free measurements in hectic medical environments where quick and reliable measurements are critical for preventing the negative outcomes of sepsis.”

PRIME earned Second Place at the Minnesota Design of Medical Devices Competition, a national recognition of the team’s thoughtful engineering and strong clinical relevance. Development of the device will continue in partnership with their clinical mentor—bringing them one step closer to impacting real patient care.

2025 Team Prism Optics – Bringing Vision Care Within Reach

In Part 2 of the 2025 Senior Design Awards Spotlight, we turn to Team Prism Optics, winners of the Leadership Prize at Penn Engineering’s Senior Design Competition.

Team Members: Daniel Botros, Fady Fahmy, Daniel Jacobsohn Serebrinic, Danish Mahmood, Aarush Sahni

Senior design in Penn Bioengineering is a yearlong capstone experience in which bioengineering seniors identify an unmet bioengineering need, design a solution to address the need, and create a high quality prototype that demonstrates their design. The course consists of BE4950 and BE4960, and was most recently taught by Dr. Erin Berlew, Dr. David Meaney, and Dr. Michael Siedlik.

Across the globe, more than a billion people lack access to basic vision care, often simply because there aren’t enough optometrists to perform eye exams (Staff, One billion have preventable vision impairment 2019). Team Prism Optics took on this challenge by building a device that automates the process of determining an eyeglass prescription, offering a low-cost, portable solution that can be used without the need for a trained clinician.

The result is a self-administered vision screening platform that mimics the clinical process of subjective refraction. A user looks through a lens system and responds to a tumbling E eye chart using a joystick, indicating the direction of the letter. This interface, designed to be intuitive for users regardless of literacy, language, or age, was a major innovation in the team’s design. As Danish Mahmood explained, “Realizing the joystick input to indicate the direction of the tumbling E’s is functional for illiterate, non native English speaking, young and old people was our biggest logistical challenge.”

The device was designed and built through a deeply collaborative process. Mahmood developed the control software and mechanical precision of the lens adjustment system, while Fady Fahmy handled the acrylic housing and gears. Aarush Sahni envisioned the LCD interface and helped lead algorithm development alongside Daniel Jacobsohn Serebrinic and Daniel Botros, working closely with clinical mentors at Penn Medicine. The system is already being tested with classmates and is set to begin clinical trials with patients this summer.

Throughout the process, the team remained focused on their goal: to make vision care accessible in underserved communities. Their mentor noted that clinical trials beginning just months after graduation are almost unheard of for senior design teams—underscoring just how effectively Prism Optics aligned their design to a global need.

Dr. Michael Siedlik,  one of the bioengineering senior design instructors,  highlighted just how exceptional this trajectory is for a student team:

“Not many senior design teams are able to start clinical trials a few months after graduation… This is a testament to their ability to identify a bioengineering need that is very well suited to their expertise and to the resources available to them, as well as their ability to execute at a high level as a team.”

“We have prototyped a working self-administered eye exam that mimics the process of subjective refraction with an automated device… Our next step is to ensure many patients can use it successfully and achieve accurate results,” Mahmood shared. 

Team Prism Optics earned the Leadership Prize at Penn Engineering’s 2025 Senior Design Competition, a recognition of both their technical achievement and their clear path to real-world deployment.

References:
Staff, RO. (2019, October 8). One billion have preventable vision impairment. Review of Optometry. https://www.reviewofoptometry.com/article/one-billion-have-preventable-vision-impairment 

2025 Team ReFlex – Rewiring Stroke Rehabilitation

This series profiles three Penn Bioengineering senior design teams whose work received recognition at major competitions in 2025. In Part 1, we feature Team ReFlex, recipients of the Judge’s Choice Award at Penn Engineering’s Senior Design Competition. 

Team Members: William Qi, Ryann Joseph, Christopher Wun, Udit Garg, Aditya Gowd

Senior design in Penn Bioengineering is a yearlong capstone experience in which bioengineering seniors identify an unmet bioengineering need, design a solution to address the need, and create a high quality prototype that demonstrates their design. The course consists of BE4950 and BE4960, and was most recently taught by Dr. Erin Berlew, Dr. David Meaney, and Dr. Michael Siedlik.

From the beginning, Team ReFlex set out to do something ambitious: create a system that could help stroke patients regain motor function by aligning therapy with the brain’s intent to move. The idea emerged from a shared interest in neurotechnology, combined with a diverse set of technical backgrounds—bioengineering, robotics, computer science, electrical engineering, and data science. After months of conversations with professors, clinicians, and researchers, the concept took shape: an integrated platform that uses EEG signals and artificial intelligence to detect motor intent and trigger functional electrical stimulation (FES).

The team’s collaborative spirit was central to their progress. Each member brought complementary skills—some focused on the machine learning algorithms, others on signal processing, printed circuit board (PCB) design, or mechanical fabrication. Together, they built a noninvasive system designed for versatility, comfort, and real-world applicability.

“We knew from the start that we wanted to work on something in neurotechnology, as it was a space where all of our interests came together,” said William Qi. “With teammates in bioengineering, robotics, computer science, electrical engineering, and data science, we felt like we had a unique mix of skills to build something meaningful.”

The path wasn’t without challenges. The interdisciplinary nature of the project meant constantly stepping beyond individual comfort zones. Signal processing became a particular hurdle once the team moved to printed circuit boards—troubleshooting became more complex, but they leaned on strong communication and trust to navigate the setbacks.

As they developed the system, the team connected with a manufacturer of FDA-approved FES devices and successfully integrated one into their prototype—something that Dr. Michael Siedlik, one of the bioengineering senior design instructors, described it as a powerful example of vision meeting execution.

“They are a shining example of how our students can turn a plan that initially seems a little like science fiction into a high-quality biomedical device with the potential to address an important need,” Siedlik noted.

The result is a modular, user-friendly platform that allows patients to participate in their own rehabilitation more directly and independently. Designed to be compatible with existing clinical tools, ReFlex introduces a new level of personalization and responsiveness to therapy—advancing the potential of brain-computer interfaces in a field that clinicians themselves acknowledge as outdated.

ReFlex received the Judge’s Choice Award at Penn Engineering’s 2025 Senior Design Competition, a recognition not only of their technical achievement, but of their commitment to reshaping what recovery can look like for stroke survivors.