Sort by
Refine Your Search
-
Listed
-
Employer
- University of Oxford
- ;
- KINGS COLLEGE LONDON
- Durham University
- Heriot Watt University
- Nature Careers
- University of Cambridge
- University of London
- King's College London
- University of Liverpool
- University of Nottingham
- AALTO UNIVERSITY
- DURHAM UNIVERSITY
- University of Birmingham
- University of Oxford;
- University of Sheffield
- ; University of Copenhagen
- Aston University
- Heriot-Watt University;
- Imperial College London
- John Innes Centre
- Medical Research Council
- Northumbria University;
- Oxford Brookes University
- Queen Mary University of London
- Royal College of Art
- Royal College of Art;
- Sheffield Hallam University
- St George's University of London
- Swansea University
- The University of Edinburgh;
- UNIVERSITY OF VIENNA
- University of Bristol
- University of Cambridge;
- University of Exeter;
- University of Glasgow
- University of Nottingham;
- University of Reading
- 28 more »
- « less
-
Field
-
, with experience of microbiology and scientific imaging, to conduct research into bacterial circadian rhythms. This will contribute to the ERC-funded programme “MicroClock” and an affiliated BBSRC project
-
have access to state-of-the art core facilities and expertise, including facilities for high-throughput screening and high content imaging, multimodality in vivo imaging, proteomics, integrative
-
biological questions about how cytoskeletal proteins are used by disease-relevant organisms. We have access to excellent facilities such as the Central Oxford Structural and Molecular Imaging centre (COSMIC
-
verification further advancing security and authenticity. In 2020 our pioneering solid-state CPL spectrometer (Nat. Commun., 2020, 11, 1676) triggered a paradigm shift in CPL spectroscopy that has been hindered
-
cytoskeletal proteins are used by disease-relevant organisms. We have access to excellent facilities such as the Central Oxford Structural and Molecular Imaging centre (COSMIC), as well as the Micron imaging
-
crystalline resins for use in two-photon polymerization. New forms of imaging hardware will be utilized in collaboration with partners to provide greater understanding of the polymer network morphology and how
-
on investigates the materials science surrounding liquid crystalline resins for use in two-photon polymerization. New forms of imaging hardware will be utilized in collaboration with partners to provide greater
-
processing in the mammalian cochlea in vivo , and how these influence central auditory neuronal pathways. The project will primarily involve using in vivo 2-photon imaging and AAV-gene delivery applied to a
-
focused on developing tools for quantitative imaging of epithelial cell biology and biophysics. Moreover, you will support and develop novel workflows of bioimaging analysis to quantify advanced imaging
-
fluorescence-lifetime detection (Fast-FLIM) and temporal focusing. This instrument will deliver quantitative, sub-second imaging of live three-dimensional cell-culture and organoid models, advancing fundamental