BIOE Seminar: Emilia Entcheva (GWU)

Friday, October 26, 2018
9:00 a.m.-10:00 a.m.
A. James Clark Hall, Room 2132
Dr. Giuliano Scarcelli
scarc@umd.edu

Emilia Entcheva
Professor
Department of Biomedical Engineering
George Washington University

Highly Parallel All-Optical Cardiac Electrophysiology Technology

Optical targeting (stimulation or recording) allows distributed parallel access to thousands and even millions of cells and locations at the same time, and within the tissue setting; optical targeting is high-throughput by nature. In this talk, I will discuss and demonstrate the combination of optogenetic stimulation with optical imaging of electrical activity in cardiomyocytes, i.e. the realization of “all-optical electrophysiology” in a high-throughput manner (HTS). Examples will include demonstration of cardiac “wave steering” by light and the use of a new fully-automated all-optical HTS platform (OptoDyCE) for drug screening using patient-derived cardiomyocytes (iPS-CMs). The impact of such approaches on removing bias, increasing reproducibility and strengthening predictive power will be illustrated by a blind drug testing study under the CiPA initiative.

About the Speaker

Dr. Emilia Entcheva is a Professor of Biomedical Engineering at George Washington University; she recently moved her laboratory to Washington DC, after 15 years as faculty at Stony Brook University. She directs the Cardiac Optogenetics and Optical Imaging Laboratory. Her research group has contributed to the development of new tools for optical mapping of cardiac excitation, computational modeling of cardiac electrophysiology, as well as innovative techniques to engineering cardiac tissue and its functional characterization using lab-on-a-chip platforms. Since 2010, her group has spearheaded efforts in shaping a new field, cardiac optogenetics (the genetically-mediated light sensitization of cardiac cells and tissue), and the development of highly-parallel all-optical cardiac electrophysiology. These developments open new possibilities for mechanistic studies in cardiac arrhythmias using “live tissue simulations” and “wave control” by light; importantly, they enable high-throughput cardiac cell electrophysiology as a much-desired tool in (personalized) cardiotoxicity screening and in drug development. This research is funded by NIH and NSF and has resulted in multiple publications and intellectual property for some of the technology.

 

Audience: Public 

 

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