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Dr. Susanne Rafelski, Ph.D. is Deputy Director, Scientific Programs at the Allen Institute for Cell Science ( https://alleninstitute.org/division/cell-science/ ) and was named to this position in December, 2020. Dr. Rafelski began imaging live cells and visualizing intracellular dynamics in 3D when she was only 17 and hasn't been able to stop since. Her life-long scientific goal is to decipher the patterns and rules that transform the overwhelming complexity found inside cells into functioning units of life and believes that to do this we must understand the organization of the structures within the cell in space and time. Dr. Rafelski's team takes an interdisciplinary, quantitative approach to cell biology, combining live-cell image-based assays, molecular genetics, and computational methods. Prior to joining the Institute in 2016, Dr. Rafelski was an Assistant Professor in the Department of Developmental and Cell Biology, the Department of Biomedical Engineering, and the Center for Complex Biological Systems at UC Irvine. Dr. Rafelski obtained her B.S. in Biochemistry and Molecular & Cellular Biology with an additional emphasis in Mathematics from the University of Arizona. She then completed her Ph.D. in Biochemistry at Stanford University, followed by a postdoc at the Center for Cell Dynamics at the Friday Harbor Labs, University of Washington, where she learned computational modeling approaches. Her research focused on integrating bacterial polarity with host-cell cytoskeletal dynamics to understand Listeria actin-based motility. She then initiated her current research program on mitochondrial structure-function as a postdoc at UCSF, where she developed 3D microscopy and image analysis methods to quantify mitochondrial morphology and applied these to investigate mitochondrial size control regulation. As a model system for intracellular organization her lab extended this work to studying the size, topology, and function of mitochondrial networks in budding yeast and mammalian cells.
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Dr. Susanne Rafelski, Ph.D. is Deputy Director, Scientific Programs at the Allen Institute for Cell Science ( https://alleninstitute.org/division/cell-science/ ) and was named to this position in December, 2020. Dr. Rafelski began imaging live cells and visualizing intracellular dynamics in 3D when she was only 17 and hasn't been able to stop since. Her life-long scientific goal is to decipher the patterns and rules that transform the overwhelming complexity found inside cells into functioning units of life and believes that to do this we must understand the organization of the structures within the cell in space and time. Dr. Rafelski's team takes an interdisciplinary, quantitative approach to cell biology, combining live-cell image-based assays, molecular genetics, and computational methods. Prior to joining the Institute in 2016, Dr. Rafelski was an Assistant Professor in the Department of Developmental and Cell Biology, the Department of Biomedical Engineering, and the Center for Complex Biological Systems at UC Irvine. Dr. Rafelski obtained her B.S. in Biochemistry and Molecular & Cellular Biology with an additional emphasis in Mathematics from the University of Arizona. She then completed her Ph.D. in Biochemistry at Stanford University, followed by a postdoc at the Center for Cell Dynamics at the Friday Harbor Labs, University of Washington, where she learned computational modeling approaches. Her research focused on integrating bacterial polarity with host-cell cytoskeletal dynamics to understand Listeria actin-based motility. She then initiated her current research program on mitochondrial structure-function as a postdoc at UCSF, where she developed 3D microscopy and image analysis methods to quantify mitochondrial morphology and applied these to investigate mitochondrial size control regulation. As a model system for intracellular organization her lab extended this work to studying the size, topology, and function of mitochondrial networks in budding yeast and mammalian cells.
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