Poster
Dr.
Blanka
Sharma
Assistant
Professor,
University
of
Florida
Title: Engineering Nanomaterials for Applications in Regenerative Medicine and Cancer Immunotherapy
Abstract
Biomaterials have the potential to improve therapeutic options for a wide range of clinical problems. Dr. Sharma’s laboratory investigates fundamental cell-material interactions to guide the development of targeted drug and cell delivery systems for applications in regenerative medicine and cancer. The first part of this talk will focus on osteoarthritis (OA), a prevalent, debilitating joint disease that has no cure or disease modifying treatment. OA is highly complex with maladaptive processes occurring within different tissues in the joint, each with their own unique drug delivery barriers and considerations. Dr. Sharma’s research seeks to overcome barriers to effective drug delivery within the joint, by exploiting specific nanoparticle-extracellular matrix interactions to improve tissue targeting and retention of therapeutic molecules within OA joints. This talk will describe the design of different nanoparticle systems that localize to the articular cartilage after injection into joints. Based on these studies, Dr. Sharma will highlight a manganese dioxide nanoparticle system that was engineered to scavenge reactive oxygen species in damaged articular cartilage, resulting in the protection of cartilage viability and tissue structure under inflammation-mediated oxidative stress. The second part of this talk will focus on the application of biomaterials to cancer, where a critical challenge in treating solid tumors is overcoming the immunosuppressive microenvironment that diminishes immune surveillance and facilitates tumor progression. Dr. Sharma’s laboratory seeks to understand how the tumor microenvironment impacts the homing and activation of natural killer (NK) cells, and develop strategies to harness their cancer killing functions. Towards this goal, Dr. Sharma’s will present work on engineering hydrogels to model the three-dimensional tumor microenvironment and interrogate the biochemical and biophysical cues that impact NK cell migration into tumors and recognition of cancer cells. These models are helping to identify immunotherapeutic strategies. For example, studies will be presented on the development of nanoparticles for delivery of siRNA that blocks immunosuppressive signaling cascades in NK cells, to reactivate their tumor homing and cancer killing functions. Mitigating dysfunctional inflammatory mechanisms is key to both tissue remodeling and cancer progression, and Dr. Sharma’s group works at the intersection of these fields.
Bio: Dr. Sharma is an Assistant Professor of Biomedical Engineering at the University of Florida. Her research focuses on the development of biomaterials and targeted therapies that direct the functions of stem and immune cells for applications ranging from tissue repair to cancer therapy. Dr. Blanka Sharma received her undergraduate degree in Chemical Engineering from the University of Waterloo (Waterloo, Ontario, Canada), her Ph.D. from Johns Hopkins University (Baltimore, MD) in the Department of Biomedical Engineering, and her postdoctoral training at the Cleveland Clinic (Cleveland, OH). Dr. Sharma served as Director of Research for Cartilix Inc. from 2005-2009, a start-up company based on her doctoral research, where she worked towards clinical translation of a hydrogel technology for cartilage repair in the knee. After starting her faculty position in 2014 at the University of Florida, Dr. Sharma was featured by the American Society for Engineering Education as one of “20 Under 40” Outstanding Junior Faculty in the U.S. In 2016, Dr. Sharma received the Faculty Teaching Excellence Award from the Department of Biomedical Engineering, and the award for “Outstanding Service to Graduate Students” by the UF Graduate Student Council. Dr. Sharma is also a recipient of the National Science Foundation Faculty Early Career Development Program (CAREER) award in 2019, one of the NSF’s most prestigious awards for junior faculty. Her research program is also supported by the National Institutes of Health, the Department of Defense, and the State of Florida.
Keywords: biomaterials, drug delivery systems, stem cell
This event is supported by the Chemical Engineering Department and CBB
Coffee and Timbits available - RSVP required