Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- Technical University of Munich
- Maastricht University (UM)
- UNIVERSIDAD CATÓLICA DE MURCIA - FUNDACIÓN UNIVERSITARIA SAN ANTONIO DE MURCIA
- University of Cambridge
- CNRS
- DAAD
- Eindhoven University of Technology (TU/e)
- Instituto de Investigação e Inovação em Saúde da Universidade do Porto (i3S)
- International PhD Programme (IPP) Mainz
- Nature Careers
- Sorbonne Université, CNRS, Inserm
- Technical University Of Denmark
- Technical University of Denmark
- Technische Universität Dresden
- University of Helsinki
- University of Porto
- University of Twente (UT)
- 7 more »
- « less
-
Field
-
UNIVERSIDAD CATÓLICA DE MURCIA - FUNDACIÓN UNIVERSITARIA SAN ANTONIO DE MURCIA | Spain | 2 months ago
. • Proven experience in one or more of the following areas: o Electrochemical biosensors o Bioelectroanalysis and bioelectronics o Wearable and implantable sensors o Microfluidic-based electrochemical
-
elaboration of biocatalysis for synthesis. A doctoral position is available for 3-years to work with Professor Florian Hollfelder at the Biochemistry Department of Cambridge University (https
-
Requirements For the purposes of determining the appropriate profile for the activity to be carried out, the following are special requirements: Experience in cell culture, molecular biology, microfluidics
-
Biotechnology (BEB) group at the Section for Microbial and Chemical Ecology (MCE) at DTU Bioengineering. MCE hosts internationally leading groups in microbial ecology, environmental biotechnology, microfluidics
-
generated FUS-eGFP reporter iPSCs for live-cell imaging of RNP granules, facilitating compound screening to identify novel drugs for repurposing as ALS therapeutics. We also generated a microfluidic device
-
characteristics. In vitro microfluidic models will use disease-specific flow conditions and blood samples from DVT patients. Your work will ultimately contribute to a risk prediction tool for recurrent DVT and PTS
-
in hemodialysis patients. Your work will involve: Developing in silico models using computational fluid dynamics combined with macroscopic thrombus formation modelling. Creating in vitro microfluidic
-
to identify novel drugs for repurposing as ALS therapeutics. We also generated a microfluidic device enabling the study of axonal RNP granules as well as the functionality of neuromuscular junctions. Here, we
-
for live-cell imaging of RNP granules, facilitating compound screening to identify novel drugs for repurposing as ALS therapeutics. We also generated a microfluidic device enabling the study of axonal RNP
-
adaptation is crucial for optimal perfusion. In living systems, network architecture constantly changes in response to environmental stimuli towards uniform flow to optimize transport. Combining microfluidic