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Skip to Main Content Press Control+M to start dragging object ptnbsid=MYt5Mr%2b6%2fvoyYjd7lTDTa0UlySQ%3d Back Accessibility Enable Screen Reader Mode Keyboard Shortcuts Accessibility Help Job
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well as electrical flow. Prototyping of the identified structures via stereolithographic, 3D printing and textile techniques like tufting, machine-based embroidery techniques or non-interlaced 3D pre-forming
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Predoctoral researcher at the Targeted Therapeutics & Nanodevices Research Group (Project BRAINZYME)
physiological conditions. • Examine their performance in 2D and 3D systems, including chemical and genetic disease models, multi-cultures and organ-on-a-chip devices. • Investigate the biodistribution as
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cells (hPSCs) using 2D and 3D culture systems, including cerebral organoids. Developing and characterizing patient-derived and mouse-derived models of tauopathies, both in vitro and in vivo, to uncover
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: • Design and fabrication of a microfluidic device mimicking the tumor microenvironment using 3D printing and bioprinting • Characterization of the blood and lymph barriers on chip • Establishment of chemical
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well as electrical flow. Prototyping of the identified structures via stereolithographic, 3D printing and textile techniques like tufting, machine-based embroidery techniques or non-interlaced 3D pre-forming
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, machine/deep learning (Pandas, SHAP , TensorFlow, etc.) and specific to image analysis, statistics, simulation, cloud environments (Kubernetes type, Docker-compose, virtualization, etc.), 3D environments
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, microfabrication, 3D-printing, finite element analysis, atomic force microscopy (AFM), microfluidics, optical microscopy, electron (cryo) microscopy, image analyis, statistical data analyis, and biophysics. You are
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To unlock the potential of targeted femtoliter volume control for efficient imaging of biological objects at molecular resolution. Job description Femto-Cryo project is a Topconsortium voor Kennis
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Biology research unit’ at BMB and the ‘Danish National Mass Spectrometry Platform for Proteomics and Biomolecular Imaging’ (PLATO), which provides a highly international, collaborative, ambitious and