-
nanoparticle formulation, polymer chemistry, or cell culture is advantageous Interest in vaccine delivery, AMR, and translational biomedical research How to apply This project is offered as part of the Centre
-
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
-
principles molecular dynamics simulations. You will contribute to the development of novel work flows as well as to the training, testing and application of latest neural network methodologies. Applications
-
to “trick” resistant strains into becoming drug-sensitive. This interdisciplinary research combines synthetic biology, molecular biology, and biochemical engineering to pioneer sustainable, non
-
learning and machine learning for biological data Sequence and structure analysis of large-scale datasets Functional annotation and evolutionary analysis Collaborative research with experimental virology
-
leveraging acoustic streaming and cavitation effects induced by ultrasound, the system will enhance drug transport and biofilm disruption. This interdisciplinary project builds on prior EPSRC-funded research
-
reasoning and interdisciplinary communication Research Environment The project will be hosted in two collaborative, interdisciplinary labs with expertise in: Evolutionary microbial genomics and phylogenetics
-
PhD Studentship: Nanopore Technology for Rapid and Accurate Measurement of Antibiotic Concentrations
analysis of nanopore signals Microfabrication and device integration Collaborative research in biophysics, biotechnology, and molecular diagnostics The student will work across the Bell and Husain labs
-
engineering and nano/microfabrication Materials characterisation techniques Microbiology and cell culture Translational research and clinical collaboration Regulatory considerations for medical devices
-
to inform next-generation therapies for TB and NTM infections. By exploring combination strategies and targeting underexploited pathways, the research could contribute to overcoming resistance and improving