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training of mice, in vivo two-photon imaging, viral circuit tracing, and computational analysis to study how fronto-sensory feedback microcircuits contribute to adaptive cognition. The successful applicant
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possess a doctorate in Biophysics, Biochemistry, Molecular Biology or related field. Experience in cell imaging, bacterial and molecular biology, fluorescence labelling, and protein-DNA/RNA interactions is
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. The project combines behavioural training of mice, in vivo two-photon imaging, viral circuit tracing, and computational analysis to study how fronto-sensory feedback microcircuits contribute to adaptive
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microscopies to address bacterial mechanisms. The ideal candidate should already possess a doctorate in Biophysics, Biochemistry, Molecular Biology or related field. Experience in cell imaging, bacterial and
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two-photon imaging systems, and working on a research project funded by the Wellcome Trust to investigate fronto-sensory feedback microcircuits in the brain and their relevance to behavioural
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imaging and data analysis. In this role, you will: Develop and apply AI tools to analyse eye images Work with hospitals across the UK to collect and study patient data Help create new methods to detect and
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central role in developing and validating these advanced human model systems, applying molecular, imaging and electrophysiological methods to characterise disease-relevant phenotypes and drug responses
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immunocytochemistry, electrophysiology & live cells imaging. The aim of the projects is to approximate cellular phenotypes in an in vitro model of Bipolar Disorder (BD), & attributing abnormal network activity
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central role in developing and validating these advanced human model systems, applying molecular, imaging and electrophysiological methods to characterise disease-relevant phenotypes and drug responses
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& Medicine. Department: Res Dept of Early Life Imaging. Contact details:Chiara Casella. Chiara.casella@kcl.ac.uk Location: St Thomas Hospital. Category: Research. About Us The post will be based at St Thomas