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Vacancies PhD-student position on mass production of pancreatic organoids using microfluidic micromaterials Key takeaways Are you passionate about combining material science, microfluidic technology
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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
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-content imaging, electrophysiology, microfluidics, organ-on-chip systems or optogenetics will be considered a plus. You work accurately and independently at the bench, while also enjoying teamwork in a
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-content imaging, electrophysiology, microfluidics, organ-on-chip systems or optogenetics will be considered a plus. You work accurately and independently at the bench, while also enjoying teamwork in a
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-occurring signals using phospho-proteomics. Proteins that are potential hubs of signal integration will be characterized through molecular- and biochemical methods. Using microfluidics coupled with advanced
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; apply microfluidics to formulate, track, and analyse milk fat globule mimics in a controlled manner. You will work here The research is part of the HARMOny project, which is carried out between Wageningen
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rheology protocols to investigate the mechanical properties of milk fat and plant lipid droplet interfaces; apply microfluidics to formulate, track, and analyse milk fat globule mimics in a controlled manner
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controlled instructional gradients. Your work will include designing and optimizing experimental protocols, advancing microfluidic encapsulation methods, testing novel polymer materials, and employing cutting
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bulk rheological characterization of SAC films and microfluidics for assessing resistance to gas transfer. The results of this PhD project will form a fundamental basis for the improved biological
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include microwell arrays for 3D cell culture, as well as microfluidic organs-on-chips (OoCs) and microphysiological systems (MPSs) in various forms. The demands on these culture platforms continue to grow