![]() ![]() "New Molecular Scaffolds for Fluorescent Voltage Indicators." ChemRxiv. 2018, Preprint. "Optical determination of absolute membrane potential." bioRxiv. 2019, Preprint. ![]() Throughout, these approaches will be integrated into systems ranging from primary cell culture to tissue slices to whole animals in order to not only show-case the utility of our new tools, but also to explore new dimensions of neuronal communication and information transfer. Secondly, we will investigate new synthetic and genetically encoded indicators for optically monitoring voltage changes in neurons. First, we will develop activity-dependent neuronal tracer dyes for following signal transduction through neural circuits and within cells. This approach to studying neuronal communication and information flux in the brain is two-pronged. We seek to address how the brain transmits information from cell to cell and develop tools to track neuronal activity with high spatial and temporal resolution. ![]() This multi-faceted approach engages a diverse group of researchers from differing scientific backgrounds, both expanding our understanding of basic chemical and biological processes and using these discoveries to investigate the brain. We seek to exploit expertise in synthetic chemistry, probe design, imaging, molecular biology, and electrophysiology to create and deploy molecular tools for mapping brain activity. Research in the Miller lab operates at the interface of molecular and cell biology, synthetic chemistry, and neuroscience. Associate Professor of Biochemistry, Biophysics and Structural Biology*įull Directory Information Research Interests ![]()
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