Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- Empa
- Institute of Nuclear Physics Polish Academy of Sciences
- CNRS
- Istituto Italiano di Tecnologia
- Leibniz
- Maastricht University (UM)
- Medical University of Gdańsk
- Queensland University of Technology
- Technical University of Denmark
- The University of Manchester;
- Trinity College Dublin
- UNIVERSITATEA DE MEDICINA SI FARMACIE IULIU HATIEGANU
- University of Beira Interior
- University of Exeter;
- University of Newcastle
- Uppsala universitet
- 6 more »
- « less
-
Field
-
further both professionally and personally in an interdisciplinary setting. Position DWI invites applications for a position as PhD student (f/m/d) in Electrospinning of Hydrogel Fibers for Biomedical
-
multidisciplinary team and possess a proactive, innovative approach to problem-solving in research. Desirable skills: Prior experience with hydrogel development, 3D cell culture techniques, and a thorough
-
1 Research fellowship for MSc (BI), to a PhD student or MSc enrolled in a non-academic degree course
enrolled in a non-academic degree course, within the Research Project entitled “Polymer-IR780 conjugate based Tetrazine-Norbornene click injectable in situ forming hydrogels: fine-tuning the polymer
-
. Empa is a research institution of the ETH Domain. The Biointerfaces Laboratory is offering a PhD position focused on development of engineered antimicrobial hydrogels. This project aims to tackle
-
include peptide design and synthesis, incorporation of the novel peptides on nanocellulose-based hydrogels, followed by the evaluation of the functionalized hydrogels in terms of physicochemical and
-
materials, conjugation chemistry, nanoscale characterisation, and immunomodulatory system development. They will design, synthesise, and characterise electroactive collagen-based hydrogels and fibrous
-
, the concept of "slow sound" (reduced group velocity) can be naturally achieved through the propagation of shear waves in very soft media (hydrogels, complex fluid suspensions) or via acoustic metamaterials
-
designing, developing, and characterizing advanced bioinks for cellular agriculture, contributing to both fundamental understanding and applied biofabrication technologies. Design and engineer hydrogel-based
-
incorporated into engineered matrices such as hydrogel-based biobeads or nanocellulose fibres to create reusable adsorption platforms suitable for continuous-flow operation. These systems will be evaluated in
-
sustainable alternatives to conventional biomaterials. The project will focus on engineering collagen-based hydrogels and bioinks with precisely tunable mechanical, viscoelastic, and degradation properties