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Field
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Our main goal is to unlock ultrasound imaging inside organs that are still inaccessible to existing clinical ultrasound scanners, in particular bones and the adult human brain. Our ambition is to
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biomedical research. Ultrasound Localization Microscopy (ULM) is a breakthrough imaging modality that enables scientists to visualize the microvasculature of living organisms with a 10 microns precision
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Challenge: Developing high-speed 3D ultrasound localization microscopy (ULM) Change: State-of-the-art artificial intelligence (AI) techniques to improve ULM Impact: Enable visualizing 3D
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, studies, etc.) in the France for more than 12 months in the 36 months preceding the recruitment start date. High-power ultrasound has long been known to disrupt particulate aggregates with applications
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mechanical environment by optimising its structure, a process known as bone remodelling. Ultrasound stimulation of bone regeneration (UStim) was discovered in the 1950s and has been widely studied ever since
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-resolution spectroscopic techniques (NMR, muon spin relaxation, inelastic neutron scattering) and bulk thermodynamic measurements (ultrasound, specific heat) at very low temperature; pursuing our recent
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ultrasonics is one of these techniques and it does this by linking the elasticity of individual crystals and measured ultrasound wave speeds. However due to this being an ill-defined problem, a computationally
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measured ultrasound wave speeds. However due to this being an ill-defined problem, a computationally intense search is performed to find a correct solution of what is measured. By combining state-of-the-art
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ultrasound devices”. This project is an interdisciplinary collaboration with the University of Vienna, the Medical University of Vienna, and General Electrics (GE) HealthCare. For further information
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academic work to industrial practice. An additional academic secondment in CNRS/ENS de Lyon (France) offers the opportunity to explore how ultrasound can alter/control these filled gels. The Ph.D. project