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staff position within a Research Infrastructure? No Offer Description TOPIC: Development of vascularized microfluidic in vitro skin models. PROFILE: biomedical physics, material science, biomedical
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intelligence (AI)-assisted image analysis for bioinformatics and medicine. The project is highly interdisciplinary, involving areas of microfluidics, fluidic mechanics, biomedical imaging, and machine learning
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quantitative image analysis, numerical modeling, and explainable AI (XAI) with state-of-the-art biophysical methods. Using techniques such as traction force microscopy, microfluidics, 3D bioprinting, and
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provide everything that will need such as sonicator for gDNA physical fragmentation, enzymes for end-blunt repair, ligation to adapters and Nested-PCR, microfluidic eletrophoresis machine, DNA purification
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milli-/microfluidic reactive experiments relevant to the DLRI process. • Implement and optimize ZnO nanoparticle synthesis under controlled conditions. • Perform optical measurements (UV-Vis, PL) and
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supercapacitors, Nano porous materials, Microfluidic-based biosensors, Nano-electrocatalysts - Energy nanomaterials, Biomaterials and their biomedical applications, High-throughput screening, Carbohydrates
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perform functional readouts such as calcium imaging and electrophysiology. Where to apply Website https://www.academictransfer.com/en/jobs/356705/phd-researcher-development-of-h… Requirements Specific
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staff and ~60 Ph.D. students. Please read more about the department’s work at https://www.uu.se/en/department/cell-and-molecular-biology . The Elf group works across traditional disciplinary boundaries
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response especially with applications in microfluidics, organ-chip, and microphysiological systems. Hands-on experience with research protocols relating to human endothelial cells and neutrophils is required
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effectiveness and safety. This PhD project aims to address this challenge through biomimetic engineering design, combining predictive in silico modelling with machine-learning techniques and microfluidic