Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- Technical University of Munich
- Nature Careers
- ; University of Surrey
- University of Antwerp
- University of Luxembourg
- ; The University of Edinburgh
- CEA
- California Institute of Technology
- Forschungszentrum Jülich
- Institute of Molecular Biosciences (IMB)
- National Institute for Bioprocessing Research and Training (NIBRT)
- National Research Council Canada
- Purdue University
- Queensland University of Technology
- Swinburne University of Technology
- University of Graz
- University of Groningen
- Utrecht University
- VIB
- 9 more »
- « less
-
Field
-
: This role focuses on advancing single-molecule microfluidic approaches for protein biophysics, bioanalysis, and biosensing. Key tasks include: Development and optimization of single-molecule assays
-
Position: This role focuses on advancing single-molecule microfluidic approaches for protein biophysics, bioanalysis, and biosensing. Key tasks include: Development and optimization of single-molecule assays
-
of microfluidic cultivation platforms for co-cultures Live-cell microscopy (including fluorescence, phase contrast and time-lapse) for the analysis of cell interactions. Conducting cultivation experiments with
-
-pathogen interactions and feedback, using a combination of quantitative imaging, microfluidics, statistical analysis and machine learning tools. A specific focus will be put on discovering biophysical
-
of precision fermentation or cell culture - Affinity towards technical tasks and bioprocess control - Advantageous: Experience in mathematic modeling, programming, CAD, microfluidic or bioreactor systems
-
the fields of microsystem engineering, microdevices and microfluidics, intelligent systems programming and modeling, autonomous control and computer vision are preferred. The successful candidate should be
-
principles that regulate host-pathogen interactions and feedback, using a combination of quantitative imaging, microfluidics, statistical analysis and machine learning tools. A specific focus will be put
-
well as computational analysis to uncover biophysical principles that regulate host-pathogen interactions and feedback, using a combination of quantitative imaging, microfluidics, statistical analysis and machine
-
obesity. The matrices will support long-term cell culture in microfluidic systems to capture early tumorigenesis and will be functionalized with relevant tumor-promoting factors (e.g., pollutants, glucose
-
could take drugs right up to cancerous cells. This project offers hands-on training in cutting-edge techniques, including fluorescence microscopy, microfluidics, and biomolecular encapsulation. You will