Functional Optical Imaging to Measure Drug Response in Cancer and Study Infrared Light Effects in Neurons

Monday, February 13, 2017 -
2:00pm to 3:00pm
The FUNG Auditorium
Alexandra Walsh

SPECIAL SEMINAR

Ph.D.

Bioeffects Division, Optical Radiation Branch

Air Force Research Lab

Functional Optical Imaging to Measure Drug Response in Cancer and Study Infrared Light Effects in Neurons

Abstract: 
Optical imaging techniques are advantageous for studying cellular behaviors due to the unique sources of contrast, non-invasive and non-damaging nature of light, and high spatial resolution. This talk will present two projects that utilize functional optical imaging techniques.  First, optical metabolic imaging (OMI) was developed to detect drug-induced metabolism changes in cancer.  OMI probes the auto-fluorescence intensity and lifetime of NADH and FAD, coenzymes of metabolism, to quantify fluorophore concentration and protein-binding dynamics.  For optimal clinical utility, an OMI drug screen was developed to test drug response on patient-specific organoids. Second, fluorescence imaging techniques were used to study infrared light effects in neurons. Short pulses (micro to milli-seconds in duration) of infrared light (1400-2100 nm) have been shown to stimulate and inhibit action potentials in neurons, but the mechanism remains unknown.  Direct action potential block by infrared light was observed in neurons for several seconds using optogenetic proteins in primary rat hippocampal neurons for non-contact and reliable action potential stimulation and recording.  Novel image acquisition and analysis techniques enabled time-correlated single photon counting fluorescence lifetime imaging at ~80 Hz to investigate calcium-induced-calcium release as a possible mechanism for infrared light effects in neurons.   
Bio: 

Alex Walsh's research interests include development of novel, functional optical imaging techniques for improved understanding of physiological phenomena. She earned her Bachelor’s Master’s and Doctorate at Vanderbilt University.  Her graduate work was funded by a National Science Foundation Graduate Fellowship.  For her doctorate research, she developed a fluorescence lifetime-based platform for predicting cancer treatment outcomes for individual patients.  Currently, she is a National Research Council Fellow at the Air Force Research Lab. In her current research, she is utilizing optical techniques to investigate the mechanisms that allow infrared-light activation and inhibition of action potential propagation in neurons.