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Vacancies Post-Doctoral Position: Development of a robotic system for training 3D skeletal muscle tissues engineered in vitro Key takeaways Job Description The Neuro-Mechanical Modeling and
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to the immune system 80% 3D fabrication of immune-related tissue 20% reading literature, writing papers, grants Required Qualifications: PhD in biological science or biomedical engineering, or other field with
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and tools for spatial omics data analysis, establishing next-generation molecular pathology pipelines that will be broadly applicable across tissues and species. Profile Essential PhD in Bioinformatics
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synthetic implants that are transformed into living tissues by the body itself? Are you eager to contribute to better and sustainable healthcare through innovative tissue engineering approaches? Are you
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cross-disciplinary team of scientists, including pharmacologist, biomedical engineer and mathematical modeller under a Wellcome Trust funded research programme. You should have a PhD degree in stem cell
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cross-disciplinary team of scientists, including pharmacologist, biomedical engineer and mathematical modeller under a Wellcome Trust funded research programme. You should have a PhD degree in stem cell
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will support the mission of the university through their work. Qualifications: PhD in mechanical engineering, chemical engineering, materials science, electrical engineering, chemistry, or related
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are used. The research is applied on direct problems in orthopaedics to develop better methods to understand and improve repair of musculoskeletal tissues. The group encompasses about 12-15 scientists (PhD
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work in close connection with a PhD student (hired at the AMBER group at the UT, focusing on the microfluidic and engineering aspects of the project), a Postdoc (hired at Radboudumc, devoted
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or COPD. We utilize single cell transcriptomics, genetically engineered mouse models and 3D organotypic cultures to characterize cellular/microenvironmental processes that underly lung tissue construction