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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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Occluding Device Sizing for LAAC in 3D TEE ( AUTO-LAAC), code LCF/TR/CI25/56020040, CaixaImpulse Innovation 2025 , funded by the “la Caixa” Foundation. Scientific Area: Electrical Engineering, Electronic
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Occluding Device Sizing for LAAC in 3D TEE ( AUTO-LAAC), code LCF/TR/CI25/56020040, CaixaImpulse Innovation 2025 , funded by the ‘”la Caixa” Foundation. Scientific Areas: Electrical Engineering, Electronic
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. This aggregate will constitute a proof of concept for new metallic electrodes directly printed within a host material using a technique similar to 3D printing. The first step will be to synthesize the nanowires in
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ideal condition to support 3D cell growth via cell-microgel scaffold formation and additive manufacturing. This highly interdisciplinary position will cover material synthesis, microgel production via
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Fuel Cells (MFCs) by developing 3D-printed titanium electrodes using Laser Powder Bed Fusion (LPBF) technology to achieve trabecular and porous structures optimised for microbial growth. Titanium is
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: 3D model learning, prediction models from imaging and molecular data, model-based simulation coupling, and uncertainty-aware outputs for lab/clinical validation. Work with 3D datasets, time-series
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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