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to deepen our understanding of IAI mechanisms and develop innovative antibacterial biomaterials to improve patient outcomes. Structured around three core scientific pillars-regenerative medicine, biomaterial
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spaces and habits for them. This is a highly interdisciplinary project that combines computational modelling and behavioural science. The first part will be based on the use of state-of-the-art
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Funding providers: The FSE Doctoral Focal Award, Swansea University and Leaf Tech Ltd The subject areas: Materials Science, Chemistry, Chemical Engineering, Electronics, Mechanics, Polymers, other
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subsample of children with craniopharyngioma and healthy controls. Part 3 will involve an intervention neuroimaging study (EEG and/or fMRI) in healthy controls, aiming to illuminate the mechanisms through
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resistance and a profoundly immunosuppressive tumour microenvironment (TME). There is a critical need for novel therapeutic strategies that target both tumour-intrinsic mechanisms and immune evasion. Our
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this advanced manufacturing process will open new opportunities: devices with variable mechanical and chemical properties; fully 3D-printed electronics; and devices with mechanical or electrical responses encoded
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: This position is ideal for candidates with a background in civil engineering, structural engineering and mechanical engineering. Applicants should demonstrate: A strong interest in both experimental and numerical
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£20,780 per year, and includes a 3-month fusion engineering CDT training programme as part of the 2025 Cohort. This project is co-supervised by Dr Chris Hardie from UKAEA. The UoB Materials for eXtremes
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on the phase shift of vibration of the structure. However, the coupling effect of flow performance and vibration of structure, as the underlying mechanism of CMF operation, is not considered in the CMF
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Award summary 100% of home tuition fees paid and an annual stipend (living expenses) of £20,780 Overview Interested in developing new experimental systems for previously unknown disease mechanisms