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characterization of 3D structures using microscopic and tomographic techniques. You will also work with architects, designers, and engineers to develop biomimetic models of fiber-reinforced structures in order to
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expertise in organoid models of neurodevelopment to join our team and be involved in a MRC funded project aimed at generating region-specific brain organoids and assembloids from multiple gene-edited human
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that will be affiliated with one of six possible multidisciplinary projects. The ideal postdocs will have expertise in some of the following areas: computational modeling, computational biology, computational
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designed biomaterials. In vitro studies will be performed to study viability, morphology, cell proliferation, cytokine secretion, immunostaining, and drug release. In vivo studies will involve
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of chemical and electrochemical principles to control and improve product morphology, product quality, and process efficiency at engineering scales. With guidance, the appointee will : Develop novel process
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collaboration aiming at preparing battery electrode materials from bio waste. Main duties of the position include: Perform structural and morphological analysis of the anode materials using e.g. X-ray powder
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of phylogenomics to work with Professor Tiago Simões. The Simões lab is broadly interested in phylogenetic methods and applications, using morphological and genomic data for reconstructing evolutionary
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analyzing whole organism models (zebrafish and mouse) to dissect the pathophysiology of a recently identified rare pediatric neurometabolic disorder. The approach involves mainly deep longitudinal phenotyping
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the mechanisms regulating mitochondrial fission in megakaryocytes, and will use mouse models to determine how mitochondrial fission affects platelet production and function. The other project involves developing
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their activity can be modulated during embryonic development to shape anatomical structures. This is an issue important for evolution of morphological diversity across different species and understanding