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developmental signaling pathways (Notch, Hippo) support tumorigenesis and might reveal novel therapeutic vulnerabilities. Every project incorporates the evaluation of novel pharmacologic agents to shepherd
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activity in a broad array of applied therapeutics. Job Responsibilities: The Center for Applied Therapeutics develops dendritic cell and T-cell-based therapies for various cancers. We collaborate across
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include analyzing clinical and simulated data, developing pulmonary disease models, and manuscript preparation. The position offers opportunities for professional development, mentorship, and collaboration
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, publish in top CompBio/CS conferences and high impact journals, and obtain training on career development in a supportive environment. Preferred qualifications: · PhD to expect in one year, or PhD completed
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neuroinflammation and neurovascular interactions using mouse models and micro physiological systems. Some of these scientific questions span into characterizing molecular changes in the blood-brain barrier, glia
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laboratory documentation of experiments, including raw experimental data and laboratory notebooks. Adhere to University standards regarding use of isotopes, chemicals, infectious agents, animals, human
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good scholarly and research practice. Adhere to University standards regarding use of isotopes, chemicals, infectious agents, animals, human subjects, and the like. Comply with all applicable University
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pharmacological manipulations in mouse models. · Perform behavioral assays related to neuropsychiatric disease models. · Combine DART with modern imaging and behavioral tools to examine neurobiological mechanisms
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computational models of the immune response for multi-scale epidemic models. This position offers an excellent opportunity for recent graduates interested in applying quantitative and computational methods
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required. Experience in the generation of single cell sequencing data including preparation of high quality single cell/nucleus suspensions from patient tissue, running droplet based microfluidic platforms