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responses using imaging and electrophysiology. Multi-channel stimulation optimization will be achieved using a closed-loop, semi-automated experimental paradigm. The findings from these experiments will feed
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new skills in biochemistry and molecular and cellular biology, including fluorescence microscopy, live-cell imaging, ratiometric calcium imaging, transcriptomics, proteomics, mammalian cell culture
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a brain imaging laboratory that studies the neural bases of stuttering and other related speech-language and developmental disorders. Why Join Michigan Medicine? Michigan Medicine is one
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imaging tools. Our goal is to understand how specific RNA molecules are spatially and temporally organized within cells to regulate eukaryotic gene expression and cellular function. This research is based
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, including the most recent papers. Preference may be given to candidates with knowledge in machine/deep learning, statistical inference, image analysis, survival analysis, causal inference, and high
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diffraction (EBSD), energy dispersive microscopy (EDS), image quantification, correlative microscopy, and electron probe microanalysis (EPMA). Prior experience is desirable but not required given a strong
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protocols. Perform photoacoustic imaging of the mouse brain. Maintain accurate and detailed records of experimental procedures and results. Collaborate with and assist other lab members on related projects
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Principles and has three critical components; patient care, education and research that together enhance our contribution to society. Who We Are About the Division of Hospital Medicine: The Division
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, including gene therapy and imaging technologies. Central to our studies is the lethal pediatric brain tumor, Diffuse Intrinsic Pontine Glioma (DIPG), particularly targeting cancer stem cells to address
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models, bioluminescence Imaging, and animal necropsy. Other wet-lab techniques or assays maybe involved depending on how the project progresses. Required Qualifications* PhD (or equivalent) in Biomedical