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-specific developmental timing and synchronization shape the formation of the human thalamocortical system. The project combines endogenous prenatal tissue, advanced human stem cell models, organoid and
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. or MD/Ph.D. scientist to join our team as a postdoctoral research fellow. We investigate the origins of lung disease, with a particular focus in stem cell biology and tissue regeneration. Our approach is
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the laboratory of Dr. David Hoffman. The Researcher will contribute to an active research program focused on single-molecule biophysics, super-resolution microscopy, human stem cell engineering, membrane
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applicants to visit https://shyam.lab.uiowa.edu/ We welcome applicants from a wide range of backgrounds, including stem cell biology, biomedical engineering, cellular/molecular biology, bioinformatics
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organization in cells, copper homeostasis, subcellular redox biology, membrane trafficking, and human stem cell engineering. This position requires a scientist with advanced technical expertise in the Chen
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-unions remain significant clinical challenges, reflecting an incomplete understanding of the complex biological processes governing bone regeneration. Critical factors such as stem cell dynamics
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to develop 2D and 3D NMJ models for DM1, consisting of different combinations of patient-induced pluripotent stem cell (hiPSC)-derived neuronal and muscle cells, allowing the dissection of pathological
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, mesenchymal stem cells and patient‑derived chondrocytes. You will join Newcastle University’s Faculty of Medical Sciences, with access to state-of-the-art facilities and specialist training in genomics
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post-mortem human brain tissue and map these states in relation to disease pathology in AD tissue. In parallel, immune responses will be modeled in human stem cell–derived systems to identify regulatory
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related field. Experience in microfluidics, stem cell technologies, electrophysiology, or advanced imaging is an advantage but not required. We value a collaborative mindset, strong analytical and problem