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possible with current methodologies. With a number of research institutes and companies throughout Europe, we will develop and validate a tumor-lymph node-on-chip (Tumor-LN-oC) platform composed of 3D tissue
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tumor-lymph node-on-chip (Tumor-LN-oC) platform composed of 3D tissue models and microfluidic chips which will connect surgically removed human primary tumors and LN tissue from the same lung cancer
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the team in hands-on practices such as cell and tissue culture, biochemistry, molecular biology, and histology. Used techniques will include: cell culture of stem cells, including 3D cultures and 3D culture
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, biochemistry, molecular biology, and histology. Used techniques will include: cell culture of stem cells, including 3D cultures and 3D culture assays, organoids; microRNA analysis; single cell analysis including
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combination of ductility, strength, etc. These properties result from the underlying complex polycrystalline microstructure. Simulation of artificially generated, 3D synthetic microstructures supports
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, etc. The methods to develop this prototype will consist of circuit simulations, sub-system-prototype development and 3D electromagnetic simulations. The candidate will be responsible
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. These properties result from the underlying complex polycrystalline microstructure. Simulation of artificially generated, 3D synthetic microstructures supports the design of novel steel grades. However, generating
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various techniques to investigate fiber-reinforced structures in nature, including additive manufacturing, computer simulations, materials testing, and characterization of 3D structures using tomographic
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in nature, including additive manufacturing, computer simulations, materials testing, and characterization of 3D structures using tomographic techniques. You will also work with architects, designers
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triggering and control method, the best HV connection method, etc. The methods to develop this prototype will consist of circuit simulations, sub-system-prototype development and 3D electromagnetic simulations