Sort by
Refine Your Search
-
Listed
-
Category
-
Employer
- ;
- University of Nottingham
- Cranfield University
- University of Cambridge
- University of Manchester
- ; Swansea University
- ; The University of Manchester
- ; University of Birmingham
- ; University of Nottingham
- University of Sheffield
- ; University of Exeter
- ; University of Reading
- ; University of Southampton
- ; University of Warwick
- ; Cranfield University
- ; Newcastle University
- ; University of Surrey
- ; The University of Edinburgh
- ; City St George’s, University of London
- ; Loughborough University
- ; University of Bristol
- ; University of Cambridge
- ; University of Leeds
- ; University of Oxford
- Harper Adams University
- ; Brunel University London
- ; EPSRC Centre for Doctoral Training in Green Industrial Futures
- ; University of Sussex
- AALTO UNIVERSITY
- University of Newcastle
- University of Oxford
- ; King's College London
- ; University of Sheffield
- University of Liverpool
- ; Aston University
- ; Imperial College London
- ; Lancaster University
- ; University of East Anglia
- ; University of Greenwich
- ; University of Hertfordshire
- Heriot Watt University
- Imperial College London
- THE HONG KONG POLYTECHNIC UNIVERSITY
- UNIVERSITY OF VIENNA
- ; Coventry University Group
- ; Durham University
- ; Royal Northern College of Music
- ; St George's, University of London
- ; UCL
- ; University of Bradford
- ; University of Huddersfield
- ; University of Plymouth
- ; University of Stirling
- ; University of Strathclyde
- Abertay University
- Aston University
- Brunel University
- Durham University
- KINGS COLLEGE LONDON
- Nature Careers
- Nottingham Trent University
- UNIVERSITY OF MELBOURNE
- University of Glasgow
- 53 more »
- « less
-
Field
-
cultures—a powerful 3D ex vivo model—this project will dissect the mechanistic links between mTOR signalling, reactive glial phenotypes, and complement activation. The project will also incorporate human
-
specific motifs within the glycan chains defining binding sites for critical signalling and structural molecules. Unravelling the ways in which these motifs are encoded into GAGs by their biosynthetic
-
multi-scale shape changes, applicable to biomedical, micromechanical, or optoelectronic applications. Advantages: This studentship will take place in world-leading research laboratories for additive
-
DEPARTMENT OF HEALTH TECHNOLOGY AND INFORMATICS Research Assistant Professor in Medical Laboratory Science / Biomedical Science / Medical Imaging and Radiation Science / Medical Physics / Medical
-
materials and develop new design methods, for functional 4D-printed devices with either fast self-resetting responses or complex multi-scale shape changes, applicable to biomedical, micromechanical
-
a growing field, with many applications in biomedical devices, electronics, and autonomous machines. Actuators to drive these robots utilise electronic, chemical, pressure, magnetic, or thermal
-
genetics training, is preferred. LMB has a collaborative working culture and state-of-the-art building on the Cambridge Biomedical Campus. We have on-site parking, cycle enclosures and excellent public
-
) offer new avenues to tackle this problem. AI models have demonstrated strong potential in clinically relevant insights from electrical signals such as ECGs, and from cardiac imaging modalities including
-
the extracellular matrix, as well as advancing related technologies toward biomedical applications. The successful candidate will contribute to our lab’s microscale studies on the role of extracellular
-
the interpretability of these models can be enhanced to support clinical decision-making. This project will leverage the complementary expertise of both supervisory teams in EEG signal processing, graph deep learning