Nearly four years ago, when Angelica Du was a freshman, she recalled being completely “awestruck” upon walking into her first Scholarship Celebration.
“It’s just really warm,” the now-senior noted at this year’s event, which took place Wednesday, Nov. 20. “My donors have always been so warm with me.”
Du—with a smile that’s constant, as well as contagious—scanned the red-and-blue draped walls of the John R. Rockwell Gymnasium, completely transformed for the yearly event on campus, and eyed the appetizers being passed. She glanced at her proud mom, a few folks over. Hosted by the Undergraduate Named Scholarship Program, the Celebration is one that has grown to attract hundreds of scholarship donors and their recipients and families, for an evening of networking and good-old-fashioned catching up.
“[Angelica] tells me that she’s proud,” said Jerry Riesenbach, a Wharton School alumnus who helped support Du’s cost of education through the Class of 1960 scholarship fund. “And I said to her, she makes us proud. Being able to provide funds is one thing, but seeing the benefit that goes to these young people, who have such tremendous aspirations and are so grateful, is another.”
At Penn, Du, who will graduate with her bachelor’s in bioengineering in May and her master’s in December 2020, designs robots and conducts neurobiology research. She teaches thermodynamics and critical writing to her peers. She sings for a Disney-themed a cappella group, serves her community in a Christian union, celebrates her culture in the Penn Philippine Association, and advocates within several honor societies. This past summer, she worked at Thermo Fisher Scientific, running experiments for a next-generation sequencer that will take a patient’s DNA, sequence it, and diagnose it within 24 hours.
Detecting Infectious Diseases with Paper-Based Devices
Despite great advancements in diagnostics technology over the past few decades, patient accessibility to these technologies remains one of the biggest challenges of the field today. Particularly in low-resource areas, even simple processes can end up taking weeks or months to return results from tests that are normally completed in days. But what if these tests could be simplified to smaller, at-home tests based on properties of microfluidics – something like a pregnancy test but for infectious diseases like HIV?
Jacqueline Linnes, Ph.D., and her team of researchers at Purdue University are working towards finding a way to do just that by creating paper-based devices that use microfluidics to help carry out the necessary diagnostic tests. Specifically, her lab designed such a paper-based system that can detect HIV nucleic acids within 90 minutes of receiving a drop of patient blood. The success of this design shows promise for producing devices for diseases whose diagnostics process involve similar pathways of pathogen detection, opening the door to more applications of at-home tests based in the properties of paper microfluidics.
Here at Penn, undergraduate bioengineering students enrolled in the two-semester laboratory course Bioengineering Modeling, Analysis, and Design (BE 309 & BE 310) have the chance to create their own models of paper microfluidics delivery systems based on given time constraints in a multi-step process. Though the students’ challenge only involves water as a substrate, Linnes’ research demonstrates the later implications of studying fluid flow through a medium as cheap and accessible as paper.
Watch the video below demonstrating Dr. Linnes’ device:
Funding for Cancer Research in Tumor Mimicry and Imaging
Two of the deadliest forms of cancer today are breast cancer and pancreatic cancer, with the latter having a five-year survival rate of only about 8%. Because cancer treatments are often adjusted according to a unique patient-to-patient basis, learning how to improve predictions of tumor behavior could help determine proper therapies sooner.
Chien-Chi Lin, Ph.D., an associate professor of biomedical engineering at Indiana University – Purdue University Indianapolis, recently received a grant from the National Institute of Health to advance his research in pancreatic cancer treatment. His project under the grant involves the development of bio-inspired, responsive, and viscoelastic (BRAVE) cell-laden hydrogels to help understand cell interactions in pancreatic ductal adenocarcinoma, which is the most common form of malignancy in the pancreas. These hydrogels mimic tumor tissue, as well as model tumor development over time, helping to eventually find better ways of treating pancreatic cancer.
Penn’s Women in Computer Science (WiCS) Hosts FemmeHacks
Penn President Amy Gutmann and Penn Engineering Dean Vijay Kumar stopped by FemmeHacks at the Pennovation Center Feb. 9. The annual event is a beginner-friendly collegiate hackathon for women-identifying people with an interest in computer programming, and featured a day of all-levels workshops Feb. 8. The event is sponsored by Penn’s Women in Computer Science student organization.
Though the event is not specifically tailored towards applications in bioengineering, skills relating to coding and software development are increasingly important for those interested in pursuing a career in medical device design. In fact, in the evaluation of new medical devices, the FDA often focuses more on software over hardware, as the former is associated with more security liabilities, due to its relative novelty.
Case Western Reserve University and Cleveland Clinic announced the launch of an alliance last year with the goal of creating better synergy across the two renowned institutions, hoping to provide more opportunities for students with interest in medicine at all levels, from high school to postdoctoral education. Though researchers from both institutions frequently partner on projects, this new alliance will create a more structured platform for future collaborations.
We would like to commend Steven George, M.D./Ph.D., on his new position as the chair of the Department of Biomedical Engineering at the University of California at Davis. His research involves the development of “organ-on-a-chip” technologies using stem cells and microfluidics to mimic human organ functions of vascularized cardiac, tumor, and pancreatic tissues.
Finally, we want to congratulate Paul Yock, M.D., on his being chosen to receive the National Academy of Engineering’s 2019 Fritz J. and Dolores H. Russ Prize. The prize honors two of Dr. Yock’s inventions from his research in interventional cardiology, one of which is Rapid Exchange, which is a kind of stenting and balloon angioplasty system. Dr. Yock is the Martha Meier Weiland Professor in the School of Medicine and Professor of Bioengineering.