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approach: integrating mechanical and enzymatic antibiofilm mechanisms into medical-grade polymers to create next-generation single-use medical consumables with built-in, robust antibiofilm properties. By
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) alter resistance mechanisms. Use high-throughput screening and biofilm models to identify conditions that reduce multidrug resistance (MDR). Build a systems-level understanding of how these mechanisms
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interest are also welcome. Motivation to learn about nanoparticle formulation, microfluidics, or data analysis is highly valued. Motivation to work in AMR and nanomedicine and to learn how AI can guide
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basic microbiology, immunology, and/or microscopy would be an advantage, but not essential. How to apply This project is offered as part of the Centre for Doctoral Training in Engineering Solutions
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, numerical methods, molecular biology methods (e.g. cloning, PCR) and bacterial plasmid mating. How to apply This project is offered as part of the Centre for Doctoral Training in Engineering Solutions
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, ultrasound, or nanoparticle synthesis is advantageous Interest in antimicrobial delivery, dental health, and interdisciplinary research How to apply This project is offered as part of the Centre for Doctoral
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£23,466 in 2026/27 rises each year) Research Training Support Grant of £5,000 to cover additional costs of training e.g. courses, project costs, conferences, travel Part-time students (minimum 50% of full