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Field
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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
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microenvironments has advanced tremendously. State-of-the-art approaches now include microwell arrays for 3D cell culture, as well as microfluidic organs-on-chips (OoCs) and microphysiological systems (MPSs) in
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well as membrane embedded and encapsulated proteins. To do so, the student will develop methodologies for lipid vesicle formation, including bulk techniques such as water-in-oil emulsions, and microfluidic systems
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signals from cells flowing in microfluidic chips (Göllner, ACS Applied Materials & Interfaces, 2025). Such a chip format combined with cheap and small laser diodes for excitation of the photoacoustic
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microfluidic techniques and 3D cell culture, you will grow human microvascular tissue on chip whose architecture self-organizes in response to vasoactive substances. Your work will lead the way to applications
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or microfluidics and ideally in quantitative data analysis. As a theoretical candidate, you have knowledge in quantitative biology, soft matter/complex systems physics or statistical physics. You enjoy working in
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or comparable degree in physics, biology, bioengineering, material engineering or a related discipline. You have experimental experience in cell/tissue culture, microfluidics, or a related discipline. You enjoy
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within the vents? You will grow two-dimensional hydrothermal vents on a microfluidic chip and quantify the vent geometry from your data. You will assess how geochemical mineral composition and inflow rate