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Advanced 3D Human-Relevant Models for Testing a 4D Injectable Hydrogel in Chronic Wound Regeneration
and validation of advanced 3D human-relevant models of chronic wounds to investigate and optimize the performance of an innovative 4D injectable hydrogel designed to promote tissue regeneration and
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world models that integrate object-centric 3D representations (Gaussian Splatting) with physics simulators (Drake) to create efficient, physically grounded digital twins of real environments; developing
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. To overcome these limitations, the TUNIC project will utilize a “phenotype-first” approach. This involves: Creating a 3D “tumor-on-a-chip” (ToC) model: This model will incorporate primary human cells, including
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targets. Her lab combines genetically engineered mouse models, patient-derived organoids, and advanced genomic tools to investigate how Wnt signalling and cell state plasticity contribute to homeostasis and
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at the finest scale to create impact on a global scale. For more information on the Weiss laboratory: https://www.lsi.umich.edu/science/our-labs/weiss-lab Job Summary Please note: This position is term-limited
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to join the interdisciplinary SNSF-funded research project "Digital Originals in 3D" (D2M). This innovative project is a collaboration between the University of Basel, the Bern University of the Arts, and
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the team of the NAMIC Project for 3DP Ship Hull Design. The Research Engineer will play a critical role in the development, validation, and optimization of 3D-printed Ship Hull and Connector System
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covalent networks, supramolecular materials, light-responsive systems, and 3D-printable bioinks to create controlled culture environments for organoids and other advanced 3D in vitro models. These in vitro
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solar tornadoes. The main objective of this project is to provide 3D directional energy flux maps of the solar atmosphere. It will be achieved by tracking the intricate interplay between plasma flows and
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for cooperative autonomous driving; Design large vision-language models for autonomous driving; Design generative diffusion & 3D/4D scene synthesis models to enable multiple agents to jointly reconstruct a scene