Sort by
Refine Your Search
-
Listed
-
Category
-
Employer
- ;
- Cranfield University
- University of Nottingham
- University of Manchester
- ; University of Surrey
- ; Swansea University
- Harper Adams University
- University of Newcastle
- ; University of Birmingham
- ; University of Nottingham
- ; The University of Manchester
- University of Cambridge
- ; University of Warwick
- AALTO UNIVERSITY
- ; Newcastle University
- ; University of Exeter
- University of Oxford
- ; Lancaster University
- ; The University of Edinburgh
- ; University of Cambridge
- ; University of Sheffield
- University of Liverpool
- ; Coventry University Group
- ; Cranfield University
- ; Durham University
- ; EPSRC Centre for Doctoral Training in Green Industrial Futures
- ; Imperial College London
- ; University of Bristol
- ; University of Greenwich
- ; University of Hull
- ; University of Leeds
- ; University of Oxford
- ; University of Plymouth
- ; University of Reading
- ; University of Southampton
- Aston University
- Brunel University
- Durham University
- Heriot Watt University
- Imperial College London
- UNIVERSITY OF VIENNA
- University of Glasgow
- University of Sheffield
- 33 more »
- « less
-
Field
-
explore ways to control their motion in 3D space. Synthetic microswimmers have many potential biomedical applications, including targeted drug delivery and non-invasive medical treatments. The swimmers
-
mattresses are standard rescue equipment, which are product tested with a fixed mass applied between two points 90cm apart which has little basis for the applied nature of rescue. Where new mattresses have
-
their swimming dynamics and the mechanical deformations caused by the encapsulated active biomolecules, you will explore ways to control their motion in 3D space. Synthetic microswimmers have many potential
-
Prostheses with Real-Life Colour Appearance". The aim of the programme is to produce high-fidelity silicone-based facial prostheses by modern additive manufacturing (3D printing) techniques. The purpose
-
bind to protein ligands via sulphated residues that interact with positively charged regions within the protein ligand(s). The 3D organisation of these domains is therefore critical for their function
-
place to monitor its evolution and variability. To correctly interpret the observed AMOC variability, however, it is essential to be able to disentangle the buoyancy-driven variability from the wind
-
ligand(s). The 3D organisation of these domains is therefore critical for their function. The object of our studies is to gain a fundamental understanding of this incredible family of glycans, opening
-
of 3D-printed prototypes, which will be tested in wind tunnels to validate the simulation results and assess the practical implications of the porous designs. Both compressible and incompressible flow
-
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
-
student will take advantage of state-of-the-art soft polymer fabrication (3D/4D printing) and characterisation (i.e. electro-mechanical multi-axial testing rigs) equipment and the latest computational