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involving signaling between nociceptors and non-neuronal cells in models of bladder dysfunction, as well as work closely with mechanical, electrical, and biological engineers to develop tools to study and
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that surrounds them using both animal models and cell-based assays. Currently, the lab is focused on pancreatic cancer studies. The lab also investigates the cellular control of proliferation and is focused
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the harnessing and optimizing of T cell function for cancer immunotherapy using genetically modified mouse models, flow cytometry, q-PCR, RNA-seq, western blot, single cell RNA seq, bioinformatics, and
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models for viral infection (if applicable) Record of scientific publications or conference presentations Experience preparing grant proposals and regulatory submissions (e.g., IBC) Preferred Schedule: Full
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: Preferred Experience: Familiarity with genetic mouse models, mouse handling, breeding and genotyping. Tissue culture experience. Counting and cryopreservation of mammalian cells. Experience in purifying
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samples, laboratory cell lines and animal models. Ongoing and future projects include (i) genomic and functional characterization of molecular drivers of women’s cancers, (ii) biology and therapy
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resilient adaptation from PGD. Current projects include developing predictive models of chronic grief outcomes in acutely grieving adults, characterizing the heterogeneity in grief trajectories, and
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diseases including coarctation of the aorta. This work will involve processing of medical image data, creation of idealized and subject-specific computational models, and/or implementation of a computational
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biology, super-resolution microscopy, live-cell imaging, multi-omics, and mouse disease models to understand insulin-secretion deficiency and synapse degeneration. (See https://www.mcw.edu/departments/cell
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regeneration by integrating state-of-the-art omics approaches with genetic mouse models and human cell culture systems. Specifically, the postdoc will work on investigating molecular mechanisms of direct cardiac