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microfluidic technology that cultures cells and tissues inside microfluidic devices to mimic the structure and microenvironment of tissues in the body. These platforms can be used to study disease progression
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, NMR spectroscopy, microfluidics, and neurophysiology to uncover a fundamentally new mechanism of sensory adaptation in neurons. Biomolecular condensates are dynamic, membraneless organelles formed
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discovery and basic research to clinical translation. The PhD student will be part of the Organs-on-Chip Technologies Lab (Prof. O. Guenat), which integrates microfluidic engineering with advanced cell
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-resistant pathogens. In this position as a postdoc you will develop innovative microfluidic habitats that generate precisely controlled oxygen and nutrient dynamics for high-throughput microbial invasion
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imaging system. The work requires strong hands-on experimental skills, creativity in experimental design, and an interest in combining microfluidics, acoustics, and ultrasound imaging. Where to apply
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on single- and multi-species biofilms conducted in the Translational Oral Biology laboratory based at the School of Dental Sciences. You will have opportunities to drive the development of microfluidics and
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the subsurface. Join three teams of excellence! This thesis work will benefit from the combined expertise of several leading research structures (IFPEN, IPGG’s technological platform for microfluidics and Mines
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available for 3-years to work with Florian Hollfelder at the Biochemistry Department of Cambridge University (https://hollfelder.bioc.cam.ac.uk/ ). The project is part of the Horizon Europe Eu Marie Curie
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involves a mix of field, laboratory, and experimental work. The successful candidate will conduct field sampling, perform follow-up aquatic chemistry analyses, and integrate microfluidic experiments
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consortium also includes industrial and clinical partners. This particular PhD project aims to develop the in-vitro vasculature-on-chip models, microfluidic chips in which controllable and physiologically