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joint multi-state models for health care processes and disease progression”. The central aim of this 36 month project is to develop new methods for the joint modelling of disease or other healthcare
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that are essential for Mycobacterium tuberculosis to cause disease. As a group we are applying an integrated systems approach of microbiology, biochemistry, molecular biology, multi-omics and mathematical modelling
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, molecular biology, multi-omics and mathematical modelling to understanding the role of metabolic pathways in the virulence and antimicrobial susceptibility of mycobacteria with the overall goal of developing
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that are essential for Mycobacterium tuberculosis to cause disease. As a group we are applying an integrated systems approach of microbiology, biochemistry, molecular biology, multi-omics and mathematical modelling
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Caenorhabditis elegans as a model. Cell and Developmental Biology https://www.ucl.ac.uk/life-sciences/cdb Prof Barbara Conradt https://profiles.ucl.ac.uk/71722-barbara-conradt About the role The main purpose
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before 19th February 2022 are not eligible unless they have since had a career break. Please check the eligibility and person specification guidance in the scheme notes to establish suitability
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preliminary data, it combines mechanistic and translational immunology with bespoke in vivo models to define and exploit therapeutically relevant subsets. The Research Fellow will lead studies on cytotoxic T
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for precision targeting of AML, an aggressive leukaemia with poor survival outcomes. Building on strong preliminary data, it combines mechanistic and translational immunology with bespoke in vivo models to define
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control technologies—particularly model predictive control—can be integrated with established low-carbon heating systems like heat pumps. These technologies aim to address both grid-level and end-user
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. As an essential part of the project team, you will work on: Designing and testing novel metamaterial unit cells tailored for transformer enclosures. Numerical modelling using advanced FEM/BEM