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Field
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molecular techniques (e.g. qPCR, metabarcoding) to characterise pathogen life cycles, host responses and environmental tolerances. Fieldwork will be conducted at selected coastal sites to assess natural
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structures affecting their fundamental modes within conventional sensing limits. As per published research, these effects are mostly investigated under dynamic loads on different boundary conditions
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at the molecular scale, even breaking covalent bonds. Indeed, mechanical force is a formidable source of energy that, with its ability to distort, bend and stretch chemical bonds, is unique in its ability to promote
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central question in evolutionary biology and has profound implications for predicting host–pathogen dynamics in changing environments and biodiversity conservation. In this project, you will investigate
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, interdisciplinary research group, including a postdoc, DTP students, and technicians. Training will include fieldwork, bird handling, ringing, lab techniques in molecular biology, microbiome sequencing
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to “trick” resistant strains into becoming drug-sensitive. This interdisciplinary research combines synthetic biology, molecular biology, and biochemical engineering to pioneer sustainable, non
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critical resistance dynamics. The project will use molecular microbiology and bioinformatics to compare traditional indicators with metagenomic data, assessing the validity of current monitoring practices
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the synergistic effects of monoclonal antibodies and colistin. Building on extensive preliminary data, the project aims to uncover the mechanisms behind this synergy using advanced biophysical and molecular
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. We aim to combine Raman spectroscopy, a powerful label-free analytical technique that measures the molecular composition of tissue by using light to excite molecular vibrations, with imaging techniques
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interatomic-potentials (MLIPs), refined for molten salt mixtures hosting other nuclear material solutes. We will perform density functional theory (DFT) calculations and molecular dynamics (MD) simulations