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, automation, and multi-parameter optimization, and create a closed loop pipeline for the rapid design of protein-based binders to any target and simultaneously optimized for developability and manufacturability
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to: Design and build (e.g., rapid prototyping, 3D-printing, injection molding, multi-axis CNC milling) various flow cell designs and performance evaluations. Plan and develop a prototype that integrates QCM
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characterization of such devices. Responsibilities and qualifications The focus of this postdoc project is to help advance the development of a reliable and efficient dual-fuel HT-PEMFC systems using multi-physics
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one of the life science industry’s biggest challenges: Closed-Loop Design and Optimization of Biologics. The research program will build on the recent advances in protein design, automation, and multi
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one of the life science industry’s biggest challenges: Closed-Loop Design and Optimization of Biologics. The research program will build on the recent advances in protein design, automation, and multi
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next generation antibody engineering with bi-/ multi-specific and multimodal antibodies, phage display technologies, exosome engineering and drug delivery, gene therapy, NK- and DC- cell based therapies
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Design and Optimization of Biologics. The research program will build on the recent advances in protein design, automation, and multi-parameter optimization and create a closed loop pipeline able
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of the life science industry’s biggest challenges: Closed-Loop Design and Optimization of Biologics. The research program will build on the recent advances in protein design, automation, and multi-parameter
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Design and Optimization of Biologics. The research program will build on the recent advances in protein design, automation, and multi-parameter optimization and create a closed loop pipeline able