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vivo experimental models (e.g. ticks and mice) to identify and characterize bacterial virulence factors and host cell machinery; molecular, cellular, and immunological mechanisms that facilitate
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lung fibrosis. The ideal candidate will independently perform studies utilizing established in vitro, ex vivo and in vivo preclinical models and will have the opportunity to develop and refine novel
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in iPSC-derived cellular models. The position is ideal for someone hoping to be involved in grant-funded research as well as increase their publication record during postdoc and launch an independent
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of his/her scientific mentor to investigate the molecular and circuit mechanism of epilepsy in mouse models; independently designs new analytical approaches and tools; performs experiments; independently
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laboratory methods for potential translation to radiation oncology clinics; develops and tests molecular diagnostic assays in pre-clinical models and in specimens collected from human patients receiving
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and non-myocyte cells; utilizes CRISPR-Cas9 genome editing to model genetic cardiovascular diseases; performs molecular biology techniques (qPCR, Western blotting, cloning, library preparation for omics
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industry. The applicant should preferably have a strong background in molecular biology and a track record of publications. Prior experience using animal models of lung injury and/or primary isolation and
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, Molecular Biology or related areas. Background in Mucosal Immunology, microbiota, allergy. Excellent communication skills in English. Proven ability to work independently within a research lab. Demonstrated
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glia for breast cancer brain metastasis. The successful candidate will leverage a combination of advanced molecular and systems neuroscience methodologies to advance our understanding of selective
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refinement of innovative research methodologies and will independently design, optimize, and execute complex immunologic and molecular experiments across in vitro, ex vivo, and in vivo model systems. Technical