Sort by
Refine Your Search
-
Listed
-
Employer
- KINGS COLLEGE LONDON
- ;
- Durham University
- University of Oxford
- University of London
- Heriot Watt University
- Nature Careers
- King's College London
- University of Cambridge
- AALTO UNIVERSITY
- Oxford Brookes University
- University of Nottingham
- University of Sheffield
- Aston University
- DURHAM UNIVERSITY
- Heriot-Watt University;
- Medical Research Council
- Northumbria University;
- Oxford Brookes University;
- Queen Mary University of London
- Royal College of Art
- Sheffield Hallam University
- The University of Edinburgh
- University of Birmingham
- University of Liverpool
- University of Nottingham;
- 16 more »
- « less
-
Field
-
of expertise, ISSS aims to offer the full portfolio of expertise in the fields of signal and image processing, novel manufacturing technologies, microsystems, microwave engineering, mobile communications systems
-
research. We study the fundamental molecular, cellular, and physiological processes that underly normal and abnormal cardiovascular and metabolic function and drive the translation of this strong basic
-
of collegiality Desirable criteria Extensive experience with confocal microscopy and live imaging Experience with biomechanics concepts and techniques such as AFM, micropipette aspiration and/or nanoindentation
-
experience with confocal microscopy and live imaging Experience with biomechanics concepts and techniques such as AFM, micropipette aspiration and/or nanoindentation Current Home Office Personal Licence
-
and assessment of ocular inflammation models, such as intravitreal injections, ocular imaging techniques and flow cytometry. Moreover, applicants will perform a variety of additional procedures such as
-
or orthotopic tumour models Supporting preclinical treatment studies involving standard-of-care or experimental agents Applying in vivo imaging techniques (e.g., bioluminescence imaging) to monitor tumour
-
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
-
different physico-chemical environments to drive self-organisation processes, like condensates, that shape mesoscale structures enabling tissue function. As a Postdoctoral Researcher at the Rosalind Franklin
-
Project The Adaptive Design for AI-Driven Processes in Transforming Dynamic Landscapes (ADAPT) project develops scalable, data-driven design methodologies that transform dynamic environmental processes
-
recently developed in a commercial 65 nm CMOS imaging process by a large international consortium of engineers and scientists for the ALICE ITS3 upgrade and the future experiments, ePIC@EIC and ALICE3@LHC