School of Medicine
Showing 41-50 of 10,425 Results
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Geoffrey Abrams, MD
Assistant Professor of Orthopaedic Surgery at the Stanford University Medical Center
Current Research and Scholarly InterestsDr. Abrams' research is focused on elucidating the pathobiology behind tendinoapthy and developing new treatment modalities for the disease. Specifically, his team is studying the role of micro-RNA as it relates to chronic inflammation and stem cell differentiation in the development and perpetuation of chronic tendinopathy.
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Marwa Abu El Haija
Clinical Assistant Professor, Pediatrics - Gastroenterology
BioI am a pediatric gastroenterologist with clinical and research interest in childhood obesity. I believe that each patient is unique in their disease and background, that is why they deserve to be approached in an individualized way. I aspire to discover what's unknown about the pathophysiologic causes of obesity, and the mechanisms of which treatments work. My clinical and research interests in pediatric obesity found home within Stanford's distinctive position academically, medically and geographically.
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Monther Abu-Remaileh
Assistant Professor of Chemical Engineering and, by courtesy, of Genetics
BioThe Abu-Remaileh Lab is interested in identifying novel pathways that enable cellular and organismal adaptation to metabolic stress and changes in environmental conditions. We also study how these pathways go awry in human diseases such as cancer, neurodegeneration and metabolic syndrome, in order to engineer new therapeutic modalities.
To address these questions, our lab uses a multidisciplinary approach to study the biochemical functions of the lysosome in vitro and in vivo. Lysosomes are membrane-bound compartments that degrade macromolecules and clear damaged organelles to enable cellular adaptation to various metabolic states. Lysosomal function is critical for organismal homeostasis—mutations in genes encoding lysosomal proteins cause severe human disorders known as lysosomal storage diseases, and lysosome dysfunction is implicated in age-associated diseases including cancer, neurodegeneration and metabolic syndrome.
By developing novel tools and harnessing the power of metabolomics, proteomics and functional genomics, our lab will define 1) how the lysosome communicates with other cellular compartments to fulfill the metabolic demands of the cell under various metabolic states, 2) and how its dysfunction leads to rare and common human diseases. Using insights from our research, we will engineer novel therapies to modulate the pathways that govern human disease.
