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. Lyngby, Denmark Be the First to Apply Job Description This multidisciplinary research program focuses on developing ultrafast multiphoton lightsheet microscopy for imaging live brain activity in vivo
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processing techniques and aims to develop new methods. Background Ultrasound is widely used at hospitals for medical imaging and allows both 2D (well-known from fetal scans) and 3D images to be created, which
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. The project includes the study of human and murine cellular models of neurodevelopmental delay and epilepsy using live cell imaging of neuronal activity. The purpose is to develop an imaging modality that can
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/. If you are applying from abroad, you may find useful information on working in Denmark and at DTU at DTU – Moving to Denmark . Application procedure Your complete online application must be submitted
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-phase extraction of target compounds in a complex sample matrix at various stages, including proof-of-concept, prototype design, optimization, and validation. Utilizing microfluidics in various diagnostic
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versatile fabrication techniques and equipment are used. CFU are experts in synthetic aperture ultrasound imaging and has the SARUS experimental ultrasound scanner, which can acquire and process data from
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well as high-resolution transmission electron microscopy. The work will include: developing pioneering methods for nanoscale imaging of enzymes immobilized at “soft matter” and inorganic surfaces to determine
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paradigm. You will develop new insight into audio and visual processing in the brain, as how to support and shape these processes through technology, under the general umbrella of ‘perceptual engineering
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establish a microfluidics platform for single cell culture and imaging. The project builds upon our current work in the project MIGRAGEN, recently published in Science Advances: www.science.org/doi/10.1126
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Postdoctoral Research Associate in the Ochs Group at the Biotech Research & Innovation Centre (BRIC)
technology for single molecule imaging in intact cell and tissue samples, with the ambition that our findings may contribute to the development of new clinical treatment strategies. The research in the Ochs