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Medical School. The research team focuses on the application of cutting-edge technologies in tissue engineering, microfluidics, and bioengineering to develop advanced in vitro models for studying urogenital
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advanced technology cores, animal facilities, and high-performance computational resources to conduct their experiments. Houston is among the most diverse cities in the country, with many cultural amenities
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-world impact in natural sciences and engineering-related disciplines. Our program intends to support research that is driven by the fellow and enables them to pursue their own creative ideas in
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molecular biology and immunology techniques along with multi-omics approaches, including sc-RNA-seq, bulk RNAseq, epigenomics, metabolomics, proteomics, CRISPR screens and genetically engineered mouse models
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gain new insights into biological concepts and disease targets. We will combine advanced cellular and molecular techniques in immunology and neurobiology with genetic-engineering tools, quantitative
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, and animal models preferred. The lab leverages genetically engineered mouse models, patient-derived xenografts, human and mouse tumor and primary cell lines as well as induced pluripotent stem cells as