Sort by
Refine Your Search
-
Country
-
Employer
- ;
- ; Newcastle University
- ; Swansea University
- ; The University of Manchester
- ; University of Nottingham
- ; University of Warwick
- ; University of West London
- AcademicTransfer
- CEA Cadarache
- Newcastle University
- University of Nottingham
- University of Twente
- University of Twente (UT)
- Uppsala University
- Uppsala universitet
- 5 more »
- « less
-
Field
-
technology and with reduced environmental impact. Within the project we study patches based on biomaterials, which are biodegradable without microplastic waste, as well as new methods for reusing electronic
-
environments. Project description The project is about developing smart patches with more sustainable technology and with reduced environmental impact. Within the project we study patches based on biomaterials
-
attitude. Knowledge or experience in biomaterials – cell interactions and membrane technology, which are preferred. The ability to work independently and possess excellent theoretical, experimental, and
-
part in interdisciplinary laboratory tasks including microalgae cultivation, biomaterial purification, mass spectrometry and X-ray/electron/laser-scanning microscopy techniques. The project will involve
-
) Biomaterials and regenerative medicine, (2) (Bio)artificial organs, (3) Engineered therapeutics. Its mission is: 1. To provide innovative technological solutions to patients suffering from chronic and malignant
-
Funding providers: EPSRC and Swansea University's Faculty of Science and Engineering Subject areas: Polymer and Glyco Chemistry, Biomaterials, Antimicrobials Project description: A significant
-
relevant discipline (Engineering, materials science, biomaterials healthcare technology etc), as well as experience in performing experimental work, collecting data and analysing research findings. How
-
will explore how polymerase based synthetic methods of designer DNA can lead to biomaterials with exploitable chemical handles for sensing and data storage applications. DNA has long had potential as a
-
response to various biomaterials. Understanding the time-and spatial-dependent molecular processes underpinning foreign body response is important for a broad range of applications, from the development
-
, biomaterials and in other important applications. Currently there are more than 80 peptide drugs approved world-wide, with many more in clinical trials, including essential antibiotics, antiviral and anticancer