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. This project aims to overcome that limitation by extending our high-throughput metabolic fingerprinting platform into 3D cancer models such as spheroids and organoids. By combining untargeted metabolomics, high
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anthropogenic impact on past biodiversity and its transformations, and refine the recognition of extinct animal varieties or those with particular adaptations by combining methods borrowed from archaeozoology, 3D
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-in-3d-stem-cell-derived-human-organ-models/t11589 Where to apply Website https://www.ceitec.eu/protein-in-cell-nmr-spectroscopy-in-3d-stem-cell-derived-… Requirements LanguagesENGLISHLevelGood
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complexity of in vivo patient tumors. This project aims to overcome that limitation by extending our high-throughput metabolic fingerprinting platform into 3D cancer models such as spheroids and organoids. By
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George Emil Palade University of Medicine, Pharmacy, Science, and Technology of Târgu Mureș | Romania | 13 days ago
on the development and validation of biomaterials and smart medical devices using animal models and advanced 3D technologies Topics: Advanced biomaterials for tissue repair and regeneration Preclinical animal models
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? Not funded by a EU programme Is the Job related to staff position within a Research Infrastructure? No Offer Description “Development of an AI-driven generative 3D modeling framework". The main
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We are seeking a motivated early-career researcher to contribute to the development of advanced beam-steering antenna solutions at Ka-band (27–30 GHz) using 3D-printing technology at the Antenna and
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of the 3D-printed clips; Analysis of the results Where to apply Website https://pica.cineca.it/unipd/ Requirements Additional Information Eligibility criteria Eligible destination country/ies for fellows
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Posting Details Student Title Classification Information Quick Link https://chapman.peopleadmin.com/postings/38848 Job Number SE169024 Position Information Department or Unit Name Grand Challenges