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conducting sweat analysis and is often more complex than the actual sweat detection. This PhD project aims to develop a new microfluidic approach that enables precise, reproducible, continuous, and autonomous
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at achieving multi-compartmentalization within cell-mimicking vesicles; use and design on-chip microfluidic systems for vesicle production and controlled experimentation; perform fluorescence (confocal
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lipid vesicles (phase-transfer, microfluidics), and then functionalizing it in a second step with an extracellular component for signal sensing and an intracellular component for signal propagation via
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sensor must be biocompatible and flexible. Using theoretical models, you will investigate the performance of different sensing principles and validate these using in vitro microfluidic experiments. Finally
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to maintain distinct reaction hubs within vesicles will constitute an important step towards building intracellular communication networks. We will use a bioengineering approach, applying our microfluidic and
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physiology, and cell growth. Each different project will focus on flow conditions ranging from linear shear flows in microfluidics to weak turbulence. In this project, you will design new multiscale
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position in the group of Dr. Burak Eral (www.erallab.com ) will be on microfluidics and separations in the Process & Energy Department of Mechanical Engineering department. In this project, you will develop
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. Each different project will focus on flow conditions ranging from linear shear flows in microfluidics to weak turbulence. In this project, you will design new multiscale experiments and analytical tools
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. Each different project will focus on flow conditions ranging from linear shear flows in microfluidics to weak turbulence. In this project, you will design new multiscale experiments and analytical tools
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research programme. The MagneticResonanceResearchCenter (MRRC) headed by Kentgens focuses on the development of hyperpolarization methodology in a microfluidic context, including advanced sample handling and