242 structural-engineering-"https:" "https:" "https:" "https:" "https:" "https:" "https:" "Dip" uni jobs at University of Glasgow
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celebrated and shared. 2 An excellent employment package with generous terms and conditions including 41 days of leave for full time staff, pension - pensions handbook https://www.gla.ac.uk/myglasgow
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and conditions including 41 days of leave for full time staff, pension - pensions handbook https://www.gla.ac.uk/myglasgow/payandpensions/pensions/, benefits and discount packages. 3 A flexible approach
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information please visit: https://www.gov.uk/skilled-worker-visa. As a valued member of our team, you can expect: 1 A warm welcoming and engaging organisational culture, where your talents are developed and
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, silver and gold awards across the University. We are investing in our organisation, and we will invest in you too. Please visit our website https://www.gla.ac.uk/explore/jobs/ for more information
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Job Purpose To make a leading engineering contribution to the EPSRC Photonics & Quantum Accelerator project “Nanophotonic MIPs for contaminant detection in the whisky industry .” The postholder will
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that provides essential structural support to blood vessels. We and others have shown that mutations in COL4A1 or COL4A2 (encoding collagen IV proteins) cause familial and sporadic haemorrhagic, indicating
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to understand the fundamental mechanisms of inflammation triggered by permeabilized mitochondria. It will entail a variety of cutting-edge methods including genome-engineering, high-resolution microscopy and in
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synovial tissue organoids, and cocultures of human tissue macrophages with autologous antigen-specific TCR-engineered T cells, and humanised macrophage–sensory neuron co-cultures. The candidate will also
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, chemistry, materials science, engineering, or a related discipline. We are open to experimental experience in relevant topics, for example, spin systems and their control (e.g., spin resonance, solid-state
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the localisation of inflammation in the joints. The project is based on a bed-to-bench-and-back approach , utilising human tissue single-cell and spatial multi-omics , engineered CAR-T cells,human organoids , and