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of precision fermentation or cell culture - Affinity towards technical tasks and bioprocess control - Advantageous: Experience in mathematic modeling, programming, CAD, microfluidic or bioreactor systems
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and implantable sensors o Microfluidic-based electrochemical platforms o Data-driven sensor signal processing Fluent English proficiency (B2/C1 level or higher). Strong analytical, problem-solving
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(batteries, fuel cells, supercapacitors) o Microfluidic and lab-on-a-chip electrochemical platforms o Advanced electrode materials and surface modifications o In situ and operando electrochemical
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techniques, including fluorescence microscopy, microfluidics, and biomolecular encapsulation. You will collaborate with leading scientists at the University of Surrey and international research partners (Prof
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expects to develop an analytical description of electrolyte flows required in various microfluidic applications such as magnetohydrodynamic (MHD) micro-stirring and micro-pumping. About Swinburne University
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the foundations of ultrasensitive molecular manipulations techniques within microfluidic environments. What You Will Do Design and conduct thermofluidic manipulation experiments using plasmonic substrates Work with
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tools in heat and mass transfer, microfluidics, thermodynamics, bioengineering, micro/nanotechnology, and computational modeling. We are passionate about developing novel translational platform
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These models are technology platforms that facilitate drug discovery and fundamental research. Our research is funded by Australian Research Council. This project aims to develop bio-microfluidic
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Optimizing a 3D microfluidic IVD model to study cell responses to wear particles, refining culture conditions, and analysing cytotoxic and inflammatory mechanisms. Optimizing a 3D microfluidic IVD
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, including members specialising in biology, microfluidics, machine learning and clinical research from RMIT University and Leading Technology Group (LTG). LTG is an Australian group of medical research