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Two BE Seniors Win the President’s Engagement and President’s Innovation Prizes

The Department of Bioengineering is proud to congratulate two of our graduating seniors on their 2019 President’s Engagement Prize and President’s Innovation Prize. Awarded annually, the Prizes empower students to design and undertake post-graduation projects that make a positive, lasting difference in the world. Each Prize-winning project will receive $1000,000, as well as $50,000 living stipend per team member.

Senior Oladunni Alomaja (right) with her partners Princess Aghayere and Summer Kollie, Rebound Liberia

BE senior Oladunni Alomaja (BSE 2019) and her partners Princess Aghayere and Summer Kollie won a President’s Engagement Prize for Rebound Liberia. Ola and her partners will use basketball as a tool to bridge the literacy gap between men and women and as a mechanism for youth to cope with the trauma and stress of daily life in post-conflict Liberia. Rebound Liberia will build an indoor basketball court in conjunction with a community resource center, and its annual three-month summer program will combine basketball clinics with daily reading and writing sessions and personal development workshops. The team is being mentored by Ocek Eke, director of global and local service-learning programs in the School of Engineering and Applied Science.

Senior Malika Shukurova (left) with her partner Katherine Sizov, Strella Biotechnology

BE senior Malika Shukurova (BSE 2019, also pursuing a MSE in BE) and her partner Katherine Sizov won a President’s Innovation Prize for Strella Biotechnology. Strella is developing a bio-sensor that can predict the maturity of virtually any fresh fruit. Strella’s sensors are installed in controlled atmosphere storage rooms, monitoring apples as they ripen. This enables packers and distributors to identify the ripest apples and fruit for their customers, thus minimizing spoilage and food waste and promoting sustainability. Strella’s current market is U.S apple packers and distributors, which represent a $4 billion produce industry. The startup is looking to expand to other markets, such as bananas and pears, in the future. Malika and Katherine are being mentored by Jeffrey Babin, Practice Professor and Associate Director of the Engineering Entrepreneurship Program. Katherine, a Biology major in the College of Arts and Sciences, developed the company as a sophomore in the George H. Stephenson Foundation Educational Laboratory, the primary teaching lab for the Department of Bioengineering.

Another winner of the President’s Innovation Prize, Wharton student Michael Wong for InstaHub, also has BE connections: One of the co-founders, Oladayo (Dayo) Adewole, graduated with a BSE in Bioengineering in 2015, went on to achieve his master’s in Robotics, and is currently back in BE pursuing his PhD. InstaHub’s mission is to eliminate energy waste through snap-on automation that enhances, rather than replaces, existing building infrastructure. Founded at Penn in 2016, InstaHub is focused on fighting climate change through energy conservation efforts with cleantech building automation technology. The initial development work for InstaHub was also done in the George H. Stephenson lab here in BE.

Congratulations once again to all the winners of this year’s President’s Engagement Prize and President’s Innovation Prize! Read more about the awards and all the winners at Penn Today and the Penn Engineering Medium Blog.

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Bioengineering Chair and Students Honored at the 2019 SEAS Awards

Each spring, the School of Engineering and Applied Science at the University of Pennsylvania hosts an awards recognition dinner to honor exceptional work in the school: The Faculty honor students for outstanding service and academics, while the students choose faculty members for their commitment to teaching and advising. This year, the Department of Bioengineering won big with honors for both our Department Chair and our undergraduates. Read about each of the award winners and see photos from the awards ceremony below. Congratulations to all the winners!

David F. Meaney, Ph.D.

Dr. David F. Meaney, Solomon R. Pollack Professor and Chair of Bioengineering, was awarded with the Ford Motor Company Award for Faculty Advising, which recognizes “dedication to helping students realize their educational, career and personal goals.” Dr. Meaney is beloved by the students in BE for his engaging teaching style, his commitment to student wellness and advancement, as well as his weekly Penn Bioengineering spin classes, and so we are delighted to see him recognized in this way by the wider student body  Read more about the award here and Dr. Meaney here.

Eshwar Inapuri (BAS 2019), a graduating senior completing his Bachelor of Applied Science degree in BE with minors in Biophysics and Chemistry, was awarded the Ben and Bertha Gomberg Kirsch Prize. This competitive award is decided by the SEAS faculty from among the Engineering undergraduate body and distinguishes a member of the B.A.S. senior class in  who “in applying the flexibility of the program, has created a personal academic experience involving the most creative use of the resources of the University.”

The Hugo Otto Wolf Memorial Prize, awarded to one or more members of each department’s senior class, distinguishes students who meet with great approval of the professors at large through “thoroughness and originality” in their work. This year, BE chose to share the award between Ethan Zhao (BSE 2019) and Shelly Teng (BSE 2019).

The Herman P. Schwan Award is decided by the Bioengineering Department and honors a graduating senior who demonstrates the “highest standards of scholarship and academic achievement.” The 2019 recipient of the Schwan Award is Joseph Maggiore (BSE 2019).

Every year, four BE students are recognized with Exceptional Service Awards for their outstanding service to the University and their larger communities. Our winners this year are Dana Abulez (BSE 2019), Daphne Cheung (BSE 2019), Lamis Elsawah (BSE 2019), and Kayla Prezelski (BSE 2019). All four of these recipients are also currently in the Accelerated Master’s program in BE.

And finally, BE also awards a single lab group (four students) with the Albert Giandomenico Award which reflects their “teamwork, leadership, creativity, and knowledge applied to discovery-based learning in the laboratory.” This year’s group consists of Caroline Atkinson (BSE 2019), Shuting (Sarah) Cai (BSE 2019), Rebecca Kellner (BSE 2019), and Harrison Troche (BSE 2019).

A full list of SEAS award descriptions and recipients can be found here.

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Junior Bioengineering Students Filter ECG Signals for Use in Astronaut Fatigue-Monitoring Device

by Sophie Burkholder

Every undergraduate student pursuing a B.S.E. in Bioengineering participates in the Bioengineering Modeling, Analysis, and Design Laboratory I & II courses, in which students work together on a series of lab-based design challenges with an emphasis on model development and statistical analysis. Recently, junior undergraduates enrolled in this course taught by Dr. Brian Chow and Dr. David Issadore (both of whom recently received tenure) completed a project involving the use of electrocardiography (ECG) to innovate a non-invasive fatigue-monitoring device for astronauts that tend to fall asleep during long operations in space.

Using ECG lead wires and electrodes with a BioPac M-35 data collection  apparatus, students collected raw data of their own heart and respiration rates, and loaded the data into MATLAB to analyze and calculate information like the heart rate itself, and portions of it like the QT-interval. “I think it was cool that we could measure signals from our own body and analyze it in a way that let us use it for a real-world application,” said junior Melanie Hillman about the project.

After taking these preliminary measurements, students used a combination of circuitry, MATLAB, and data acquisition boards to create both passive and active filters for the input signals. These filters helped separate the user’s breathing rate, which occurs at lower frequencies, from the heart rate, which occurs at higher frequencies, allowing for the data to be read and analyzed more easily. In their final design, most students used an active filter circuit chip that combined hardware with software to create bandpass filters of different frequency ranges for both input signals.

“It was nice to be able to do a lab that connected different aspects of engineering in the sense that we both electronically built circuits, and also modeled them theoretically, because normally there’s a separation between those two domains,” said junior Emily Johnson. On the final day of the project, Demo Day, groups displayed their designs ability to take one input from the ECG cables connected to a user, and filter it out into recognizable heart and respiration rates on the computer. This project, conducted in the in the Stephenson Foundation Bioengineering Educational Laboratory here at the University of Pennsylvania’s Department of Bioengineering, is just one of many examples of the way this hallmark course of the bioengineering curriculum strives to bring together all aspects of students’ foundational engineering coursework into applications with significance in the real world.

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Week in BioE: April 5, 2019

by Sophie Burkholder

Tulane Researchers Use Cancer Imaging Technique to Help Detect Preeclampsia

Preeclampsia is potentially life-threatening pregnancy disorder that typically occurs in about 200,000 expectant mothers every year. With symptoms of high blood pressure, swelling of the hands and feet, and protein presence in urine, preeclampsia is usually treatable if diagnosed early enough. However, current methods for diagnosis involve invasive procedures like cordocentesis, a procedure which takes a sample of fetal blood.

Researchers at Tulane School of Medicine led by assistant professor of bioengineering Carolyn Bayer, Ph.D., hope to improve diagnostics for preeclampsia with the use of spectral photoacoustic imaging. Using this technique, Bayer’s team noticed a nearly 12 percent decrease in placental oxygenation in rats with induced preeclampsia when compared to normal pregnant rats after only two days. If success in using this imaging technology continues at the clinical level, Bayer plans to find more applications of it in the detection and diagnosis of breast and ovarian cancers as well.

New CRISPR-powered device detects genetic mutations in minutes 

Two groups of researchers from the University of California, Berkeley and the Keck Graduate Institute of the Claremont Colleges recently collaborated to design what they call a “CRISPR-Chip” –  a combination of the CRISPR-Cas9 System with a graphene transistor to sequence DNA for the purpose of genetic mutation diagnosis. While companies like 23andMe made genetic testing and analysis more common and accessible for the general public in recent years, the CRISPR-Chip looks to streamline the technology even more.

This new chip eliminates the long and expensive amplification process involved in the typical polymerase chain reaction (PCR) used to read DNA sequences. In doing so, the CRISPR-Chip is much more of a point-of-care diagnostic, having the ability to quickly detect a given mutation or sequence when given a pure DNA sample. Led by Kiana Aran, Ph.D., the research team behind the CRISPR-Chip hopes that this new combination of nanoelectronics and modern biology will allow for a new world of possibilities in personalized medicine.

New Method of Brain Stimulation Might Alleviate Symptoms of Depression

Depression is one of the most common mental health disorders in the United States, with nearly 3 million cases every year. For most patients suffering from depression, treatment involves prolonged psychotherapy, antidepressant medication, or even electroconvulsive therapy in extreme cases. Now, scientists at the University of North Carolina School of Medicine study the use of transcranial alternating current stimulation (tACS) to alleviate symptoms of depression.

Led by Flavio Frohlich, Ph.D., who has an adjunct appointment in biomedical engineering, this team of researchers based this new solution on information from each patient’s specific alpha oscillations, which are a kind of wave that can be detected by an electroencephalogram (EEG). Those who suffer from depression tend to have imbalanced alpha oscillations, so Frohlich and his team sought to use tACS to restore this balance in those patients. After seeing positive results from data collected two weeks after patients in a clinical trial receives the tACS treatment, Frohlich hopes that future applications will include treatment for even more mental health disorders and psychiatric illnesses.

University of Utah Researchers Receive Grant to Improve Hearing Devices for Deaf Patients

Engineers at the University of Utah are part of team that recently received a $9.7 million grant from the National Institute of Health (NIH) to design new implantable hearing devices for deaf patients, with the hope to improve beyond the sound quality of existing devices. The work will build upon a previous project at the University of Utah called the Utah Electrode Array, a brain-computer interface originally developed by Richard Normann, Ph.D., that can send and receive neural impulses to and from the brain. This new device will differ from a typical cochlear implant because the Utah Electrode Array assembly will be attached directly to the auditory nerve instead of the cochlea, providing the patient with a much higher resolution of sound.

People & Places

Vivek Shenoy, Eduardo D. Glandt President’s Distinguished Scholar in the Department of Materials Science and Engineering and Secondary Faculty in Bioengineering, has been named the recipient of the 2018–19 George H. Heilmeier Faculty Award for Excellence in Research for “for pioneering multi-scale models of nanomaterials and biological systems.”

The Heilmeier Award honors a Penn Engineering faculty member whose work is scientifically meritorious and has high technological impact and visibility. It is named for George H. Heilmeier, a Penn Engineering alumnus and advisor whose technological contributions include the development of liquid crystal displays and whose honors include the National Medal of Science and Kyoto Prize.

Read the rest of the story on Penn Engineering’s Medium blog.

We would also like to congratulate Jay Goldberg, Ph.D., from Marquette University on his election as a fellow to the National Academy of Inventors. Nominated largely for his six patents involving medical devices, Goldberg also brings this innovation to his courses. One in particular called Clinical Issues in Biomedical Engineering Design allows junior and senior undergraduates to observe the use of technology in clinical settings like the operating room, in an effort to get students thinking about how to improve the use of medical devices in these areas.

 

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Week in BioE: March 29, 2019

by Sophie Burkholder

New Studies in Mechanobiology Could Open Doors for Cellular Disease Treatment

When we think of treatments at the cellular level, we most often think of biochemical applications. But what if we began to consider more biomechanical-oriented approaches in the regulation of cellular life and death? Under a grant from the National Science Foundation (NSF),Worcester Polytechnic Institute’s (WPI) Head of the Department of Biomedical Engineering Kristen Billiar, Ph.D., performs research that looks at the way mechanical stimuli can affect and trigger programmed cell death.

Billiar, who received his M.S.E. and Ph.D. from Penn, began his research by first noticing the way that cells typically respond to the mechanical stimuli in their everyday environment, such as pressure or stretching, with behaviors like migration, proliferation, or contraction. He and his research team hope to find a way to eventually predict and control cellular responses to their environment, which they hope could open doors to more forms of treatment for disorders like heart disease or cancer, where cellular behavior is directly linked to the cause of the disease.

Self-Learning Algorithm Could Help Improve Robotic Leg Functionality

Obviously, one of the biggest challenges in the field of prosthetics is the extreme difficulty in creating a device that perfectly mimics whatever the device replaces for its user. Particularly with more complex designs that involve user-controlled motion for joints in the limbs or hands, the electrical circuits implemented are by no means a perfect replacement of the neural connections in the human body from brain to muscle. But recently at the University of Southern California Viterbi School of Engineering, a team of researchers led by Francisco J. Valero-Cuevas, Ph. D.,  developed an algorithm with the ability to learn new walking tasks and adapt to others without any additional programming.

The algorithm will hopefully help to speed the progress of robotic interactions with the world, and thus allow for more adaptive technology in prosthetics, that responds to and learns with their users. The algorithm Valero-Cuevas and his team created takes inspiration from the cognition involved with babies and toddlers as they slowly learn how to walk, first through random free play and then from pulling on relevant prior experience. In a prosthetic leg, the algorithm could help the device adjust to its user’s habits and gait preferences, more closely mimicking the behavior of an actual human leg.

Neurofeedback Can Improve Behavioral Performance in High-Stress Situations

We’re all familiar with the concept of being “in the zone,” or the feeling of extraordinary focus that we can sometimes have in situations of high-stress. But how can we understand this shift in mindset on a neuroengineering level? Using the principal of the Yerkes-Dodson law, which says that there is a state of brain arousal that is optimal for behavioral performance, a team of biomedical engineering researchers at Columbia University hope to find ways of applying neurofeedback to improving this performance in demanding high-stress tasks.

Led by Paul Sajda, Ph.D., who received his doctoral degree from Penn, the researchers used a brain-computer interface to collect electroencephalography (EEG) signals from users immersed in virtual reality aerial navigation tasks of varying difficulty levels. In doing so, they were able to make connections between stressful situations and brain activity as transmitted through the EEG data, adding to the understanding of how the Yerkes-Dodson law actually operates in the human body and eventually demonstrating that the use of neurofeedback reduced the neural state of arousal in patients. The hope is that neurofeedback may be used in the future to help treat emotional conditions like post-traumatic stress disorder (PTSD).

Ultrasound Stimulation Could Lead to New Treatments for Inflammatory Arthritis

Arthritis, an autoimmune disease that causes painful inflammation in the joints, is one of the more common diseases among older patients, with more than 3 million diagnosed cases in the United States every year. Though extreme measures like joint replacement surgery are one solution, most patients simply treat the pain with nonsteroidal anti-inflammatory drugs or the adoption of gentle exercise routines like yoga. Recently however, researchers at the University of Minnesota led by Daniel Zachs, M.S.E., in the Sensory Optimization and Neural Implant Coding Lab used ultrasound stimulation treatment as a way to reduce arthritic pain in mice. In collaboration with Medtronic, Zachs and his team found that this noninvasive ultrasound stimulation greatly decreased joint swelling in mice who received the treatment as opposed to those that did not. They hope that in the future, similar methods of noninvasive treatment will be able to be used for arthritic patients, who otherwise have to rely on surgical remedies for serious pain.

People and Places

Leadership and Inspiration: EDAB’s Blueprint for Engineering Student Life

To undergraduates at a large university, the administration can seem like a mysterious, all-powerful entity, creating policy that affects their lives but doesn’t always take into account the reality of their day-to-day experience. The Engineering Deans’ Advisory Board (EDAB) was designed to bridge that gap and give students a platform to communicate with key decision makers.

The 13-member board meets once per week for 60 to 90 minutes. The executive board, comprised of four members, also meets weekly to plan out action items and brainstorm. Throughout his interactions with the group, board president Jonathan Chen, (ENG ‘19, W ‘19), has found a real kinship with his fellow board members, who he says work hard and enjoy one another’s company in equal measure.

Bioengineering major Daphne Cheung (ENG’19) joined the board as a first-year student because she saw an opportunity to develop professional skills outside of the classroom. “For me, it was about trying to build a different kind of aptitude in areas such as project management, and learning how to work with different kinds of people, including students and faculty, and of course, the deans,” she says.

Read the full story on Penn Engineering’s Medium Blog. Media contact Evan Lerner.

Purdue University College of Engineering and Indiana University School of Medicine Team Up in New Engineering-Medicine Partnership

The Purdue University College of Engineering and the Indiana University School of Medicine recently announced a new Engineering-Medicine partnership, that seeks to formalize ongoing and future collaborations in research between the two schools. One highlight of the partnership is the establishment of a new M.D./M.S. degree program in biomedical engineering that will allow medical students at Indiana University to receive M.S.-level training in engineering technologies as they apply to clinical practice. The goal of this new level of collaboration is to further involve Purdue’s engineering program in the medical field, and to exhibit the benefits that developing an engineering mindset can have for medical students. The leadership of this new partnership includes

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BE Grace Hopper Lecture: Powering Tumor Cell Migration Through Hetergeneous Microenvironments

We hope you will join us for the 2019 Bioengineering Grace Hopper lecture by Dr. Cynthia Reinhart-King.

Date: Thursday, April 4, 2019
Time: 3:30-4:30 PM
Location: Glandt Forum, Singh Center, 3205 Walnut Street

Dr. Cynthia Reinhart-King, Engineering, BME, Photo by Joe Howell

Speaker: Cynthia Reinhart-King, Ph.D.
Cornelius Vanderbilt Professor of Engineering, Director of Graduate Studies, Biomedical Engienering
Vanderbilt University

Title: “Powering Tumor Cell Migration Through Heterogeneous Microenvironments”

Abstract:
To move through tissues, cancer cells must navigate a complex, heterogeneous network of fibers in the extracellular matrix. This network of fibers also provides chemical, structural and mechanical cues to the resident cells. In this talk, I will describe my lab’s efforts to understand the forces driving cell movements in the tumor microenvironment. Combining tissue engineering approaches, mouse models, and patient samples, we create and validate in vitro systems to understand how cells navigate the tumor stroma environment. Microfabrication and native biomaterials are used to build mimics of the paths created and taken by cells during metastasis. Using these platforms, we have described a role for a balance between cellular energetics, cell and matrix stiffness, and confinement in determining migration behavior. Moreover, we have extended this work into investigating the role of the mechanical microenvironment in tumor angiogenesis to show that mechanics guides vessel growth and integrity. I will discuss the mechanical influences at play during tumor progression and the underlying biological mechanisms driving angiogenesis and metastatic cell migration as a function of the ECM with an eye towards potential therapeutic avenues.

Bio:
Cynthia Reinhart-King is the Cornelius Vanderbilt Professor of Engineering and the Director of Graduate Studies in Biomedical Engineering at Vanderbilt University.  Prior to joining the Vanderbilt faculty in 2017, she was on the faculty of Cornell University where she received tenure in the Department of Biomedical Engineering. She obtained undergraduate degrees in chemical engineering and biology at MIT and her PhD at the University of Pennsylvania in the Department of Bioengineering as a Whitaker Fellow working with Daniel Hammer. She then completed postdoctoral training as an Individual NIH NRSA postdoctoral fellow at the University of Rochester.  Her lab’s research interests are in the areas of cell mechanics and cell migration specifically in the context of cancer and atherosclerosis. Her lab has received funding from the American Heart Association, the National Institutes of Health, the National Science Foundation and the American Federation of Aging Research.  She has been awarded the Rita Schaffer Young Investigator Award in 2010 and the Mid-Career Award in 2018 from the Biomedical Engineering Society, an NSF CAREER Award, the 2010 Sonny Yau ‘72 Excellence in Teaching Award, a Cook Award for “contributions towards improving the climate for women at Cornell,” and the Zellman Warhaft Commitment to Diversity Award from the Cornell College of Engineering. She is a fellow of the Biomedical Engineering Society and the American Institute for Medical and Biological Engineering, and she is a New Voices Fellow of the National Academies of Science, Engineering and Medicine. She is currently a standing member of the NIH CMT study section panel and Secretary of the Biomedical Engineering Society.

Information on the Grace Hopper Lecture:
In support of its educational mission of promoting the role of all engineers in society, the School of Engineering and Applied Science presents the Grace Hopper Lecture Series. This series is intended to serve the dual purpose of recognizing successful women in engineering and of inspiring students to achieve at the highest level.
Rear Admiral Grace Hopper was a mathematician, computer scientist, systems designer and the inventor of the compiler. Her outstanding contributions to computer science benefited academia, industry and the military. In 1928 she graduated from Vassar College with a B.A. in mathematics and physics and joined the Vassar faculty. While an instructor, she continued her studies in mathematics at Yale University where she earned an M.A. in 1930 and a Ph.D. in 1934. Grace Hopper is known worldwide for her work with the first large-scale digital computer, the Navy’s Mark I. In 1949 she joined Philadelphia’s Eckert-Mauchly, founded by the builders of ENIAC, which was building UNIVAC I. Her work on compilers and on making machines understand ordinary language instructions lead ultimately to the development of the business language, COBOL. Grace Hopper served on the faculty of the Moore School for 15 years, and in 1974 received an honorary degree from the University. In support of the accomplishments of women in engineering, each department within the School invites a prominent speaker to campus for a one or two-day visit that incorporates a public lecture, various mini-talks and opportunities to interact with undergraduate and graduate students and faculty. The lecture is open to everyone!

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Penn Bioengineers: Cells Control Their Own Fate by Manipulating Their Environment

by Lauren Salig

In these images, the researchers labeled new proteins white, and antibodies against other proteins in different colors. The co-localization of new proteins and antibodies show how cells can impact their local environments.

As different as muscle, blood, brain and skin cells are from one another, they all share the same DNA. Stem cells’ transformation into these specialized cells — a process called cell fate determination — is controlled through various signals from their surroundings.

A recent Penn Engineering study suggests that cells may have more control over their fate than previously thought.

Jason Burdick, Robert D. Bent Professor of Bioengineering, and Claudia Loebel, a postdoctoral researcher in his lab, led the study. Robert Mauck, Mary Black Ralston Professor for Education and Research in Orthopaedic Surgery at Penn’s Perelman School of Medicine, also contributed to the research.

Their study was published in Nature Materials.

Read the full story in the Penn Engineering Medium Blog. Media contact Evan Lerner.

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Week in BioE (March 22, 2019)

by Sophie Burkholder

A New Microscopy Technique Could Reduce the Risk of LASIK Surgery

Though over ten million Americans have undergone LASIK vision corrective surgery since the option became available about 20 years ago, the procedure still poses some risk to patients. In addition to the usual risks of any surgery however, LASIK has even more due to the lack of a precise way to measure the refractive properties of the eye, which forces surgeons to make approximations in their measurements during the procedure. In an effort to eliminate this risk, a University of Maryland team of researchers in the Optics Biotech Laboratory led by Giuliano Scarcelli, Ph. D., designed a microscopy technique that would allow for precise measurements of these properties.

Using a form of light-scattering technology called Brillouin spectroscopy, Scarcelli and his lab found a way to directly determine a patient’s refractive index – the quantity surgeons need to know to be able to measure and adjust the way light travels through the eye. Often used as a way to sense mechanical properties of tissues and cells, this technology holds promise for taking three-dimensional spatial observations of these structures around the eye. Scarcelli hopes to keep improving the resolution of the new technique, to further understanding of the eye, and reduce even more of the risks involved with LASIK surgery.

Taking Tissue Models to the Final Frontier

Space flight is likely to cause deleterious changes to the composition of bacterial flora, leading to an increased risk of infection. The environment may also affect the susceptibility of microorganisms within the spacecraft to antibiotics, key components of flown medical kits, and may modify the virulence of bacteria and other microorganisms that contaminate the fabric of the International Space Station and other flight platforms.

“It has been known since the early days of human space flight that astronauts are more prone to infection,” says Dongeun (Dan) Huh, Wilf Family Term Assistant Professor in Bioengineering at Penn Engineering. “Infections can potentially be a serious threat to astronauts, but we don’t have a good fundamental understanding of how the microgravity environment changes the way our immune system reacts to pathogens.”

In collaboration with G. Scott Worthen, a physician-scientist in neonatology at the Children’s Hospital of Philadelphia, Huh will attempt to answer this question by sending tissues-on-chips to space. Last June, the Center for the Advancement of Science in Space (CASIS) and the National Center for Advancing Translational Sciences (NCATS), part of the National Institutes of Health (NIH), announced that the duo had received funding to study lung host defense in microgravity at the International Space Station.

Huh and Worthen aim to model respiratory infection, which accounts for more than 30 percent of all infections reported in astronauts. The project’s goals are to test engineered systems that model the airway and bone marrow, a critical organ in the immune system responsible for generating white blood cells, and to combine the models to emulate and understand the integrated immune responses of the human respiratory system in microgravity.

Read the rest of the article on Penn Engineering’s Medium Blog. Media contacts Evan Lerner and Janelle Weaver.

Sappi Limited Teams Up with the University of Maine to Develop Paper Microfluidics

At the Westbrook Technology Center of Sappi, a global pulp and paper company, researchers found ways to apply innovations in paper texture for medical use. So far, these include endeavors in medical test devices and patches for patient diagnostics. In collaboration with the Caitlin Howell, Ph.D., Assistant Professor of Chemical and Biomedical Engineering at the University of Maine, Sappi hopes to continue advances in these unconventional uses of their paper, especially as the business in paper for publishing purposes declines.

Sappi’s projects with the university focus on the development of paper microfluidics devices as what’s now becoming a widespread solution for obstacles in point-of-care diagnostics. One project in particular, called Sharklet, uses a paper that mimics shark skin as a way to impede unwanted microbial growth on the device – a key characteristic needed for its transition into commercial use. Beyond this example, Sappi’s work in developing paper microfluidics underscores the benefits of these devices in their mass producibility and adaptability.

New Observations of the WNT Pathway Deepen the Understanding of Protein Signaling in Cellular Development

Scientists at Rice University recently found that a protein signaling pathway called WNT, typically associated with its role in early organism development, can both listen for signals from a large amount of triggers and influence cell types throughout embryonic development. These new findings, published in PNAS, add to the already known functions of WNT, deepening our understanding of it and opening the doors to new potential applications of it in stem cell research.

Led by Aryeh Warmflash, Ph. D., researchers discovered that the WNT pathway is different between stem cells and differentiated cells, contrary to prior belief that it was the same for both. Using CRISPR-Cas9 gene editing technology, the Warmflash lab observed that the WNT signaling pathway is actually context-dependent throughout the process of cellular development. This research brings a whole new understanding to the way the WNT pathway operates, and could open the doors to new forms of gene therapy and treatments for diseases like cancers that involve genetic pathway mutations.

People and Places

In a recent article from Technical.ly Philly, named Group K Diagnostics on a list of ten promising startups in Philadelphia. Group K Diagnostics founder Brianna Wronko graduated with a B.S.E. from Penn’s Department of Bioengineering in 2017, and her point-of-care diagnostics company raised over $2 million in funding last year. Congratulations Brianna!

We would also like to congratulate Pamela K. Woodward, M.D., on her being named as the inaugural Hugh Monroe Wilson Professor of Radiology at the Washington University School of Medicine in St. Louis. Also a Professor of Biomedical Engineering at the university, Dr. Woodward leads a research lab with a focus on cardiovascular imaging, including work on new standards for diagnosis of pulmonary blood clots and on an atherosclerosis imaging agent.

Lastly, we would like to congratulate all of the following researchers on their election to the National Academy of Engineering:

  • David Bishop, Ph. D., a professor at the College of Engineering at Boston University whose current research involves the development of personalized heart tissue as an all-encompassing treatment for patients with heart disease.
  • Joanna Aizenberg, Ph. D., a professor of chemistry and chemical biology at Harvard University who leads research in the synthesis of biomimetic inorganic materials
  • Gilda Barabino, Ph. D., the dean of the City College of New York’s Grove School for Engineering whose lab focuses on cartilage tissue engineering and treatments for sickle cell disease.
  • Karl Deisseroth, M.D., Ph. D., a professor of bioengineering at Stanford University whose research involves the re-engineering of brain circuits through novel electromagnetic brain stimulation techniques.
  • Rosalind Picard, Ph.D., the founder and director of the Affective Computing Research Group at the Massachusetts Institute of Technology’s Media Lab whose research focuses on the development of technology that can measure and understand human emotion.
  • And finally, Molly Stevens, Ph. D., the Research Director for Biomedical Material Sciences at the Imperial College of London with research in understanding biomaterial interfaces for biosensing and regenerative medicine.
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BE’s Michael Mitchell Wins Controlled Release Society T. Nagai Award

Michael Mitchell, Ph.D.

Michael Mitchell, Skirkanich Assistant Professor of Innovation in the Department of Bioengineering, is the recipient of the Controlled Release Society (CRS) 2019 T. Nagai Postdoctoral Research Achievement Award, which comes with a $3,000 honorarium.

According to the CRS website, “The Controlled Release Society T. Nagai Postdoctoral Research Achievement Award has been established to recognize an individual postdoctoral candidate who has recently completed outstanding postdoctoral research in controlled release science and technology, and the postdoc’s advisor who played an integral role in those achievements.”

Mitchell and his postdoctoral advisor at MIT, Robert Langer, will receive the award at the 2019 CRS annual meeting this July in Valencia, Spain.

The sole recipient of this award, Mitchell was recognized for his work on engineering controlled release technologies for cancer gene therapy and immunotherapy. Mitchell focuses on improving the way drugs are delivered within the body by combining approaches from engineering, biology, machine learning, and data science to better target diseased cells. Mitchell’s work helps to lay the foundation for a new class of therapeutic strategies against hematologic cancers such as multiple myeloma and leukemia.

For this research, Mitchell also received the Burroughs Wellcome Fund Career Award at the Scientific Interface in 2016, the NIH Director’s New Innovator Award in 2018, and a Rising Star Award in Cellular and Molecular Bioengineering from the Biomedical Engineering Society in 2019. He joined the Penn faculty in January 2018 after completing an NIH NCI postdoctoral fellowship at the Koch Institute for Integrative Cancer Research at MIT.

Originally posted on the Penn Engineering Medium blog. Media contacts Evan Lerner. 

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Penn BE Undergrads Make Biology More Accessible with Open-Source Plate Reader

The annual International Genetically Engineered Machine (iGEM) competition challenges students to expand the field of synthetic biology to solve tangible problems. While most iGEM projects involve imbuing microorganisms with useful new traits and adding them to a global toolkit, Penn Engineering students took a unique approach to the iGEM challenge by creating an open-source blueprint for a mechanical instrument that could make biological research more accessible.

Penn Bioengineering undergraduate Andrew Clark and recent graduates Karol Szymula, now a research assistant in Penn’s Complex Systems Lab, and Michael Patterson, now the lab engineer for Penn Bioengineering’s Instructional Laboratories, contributed to the project that originated through the 2017 iGEM challenge. Graduate student Michael Magaraci, who started Penn’s iGEM program as an undergraduate, and Sevile Mannickarottu, director of Instructional Laboratories, also participated. Brian Chow, Assistant Professor in Bioengineering at Penn, who helped create the iGEM competition when he was an MIT graduate student, oversaw the project.

Read the full story at Penn Engineering’s Medium Blog. Media contacts Evan Lerner and Lauren Salig.