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disinfectants. With antimicrobial resistance (AMR) on the rise, there is an urgent need for non-antibiotic strategies to prevent and control biofilm formation on medical devices. This PhD project proposes a novel
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could be applied in biotechnology, healthcare, and environmental contexts. Employ synthetic and molecular biology tools to design and test new methods of controlling fungal behaviour. Impact and Outlook
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integration, and real-time optimisation, the project will ultimately help develop an adaptive system that helps pilots and controllers make smarter decisions mid-flight. The research will advance through three
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challenging. This project aims to develop an ultrasound-assisted nanoparticle-based drug delivery system for targeted, controlled release of antimicrobials within these hard-to-reach oral microenvironments. By
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processing, advanced materials characterisation, control and bio-inspired materials/structures. The outcomes will contribute to the development of next-generation autonomous systems, advancing embedded sensing
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to improve mechanical performance in composite structures under extreme loads. Emphasis will be placed on the design of hybrid configurations capable of promoting controlled and progressive failure modes