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these change in the context of chromatin or obstacles on the DNA. To do so, you will design and employ novel biophysical instrumentation (e.g. optical tweezers, single-molecule fluorescence, microfluidics, cryo
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researchers with theoretical and practical expertise in acoustofluidics. You will not be working alone. Within our research environment, which is exceptionally strong in acoustic microfluidic systems, we work
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changes in microgravity conditions. d. Ability to perform cell culture and tissue models such as 3D tissue models and microfluidic systems to simulate microgravity. e. Understanding and experience with
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rheological, microfluidic, rheo-SALS/SAS/SANS and allied methods development and implementation. General strategies to reduce the viscosity of highly concentrated suspensions will be explored. This is a one
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of chromatin or obstacles on the DNA. To do so, you will design and employ novel biophysical instrumentation (e.g. optical tweezers, single-molecule fluorescence, microfluidics, cryo-electron microscopy) and
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microfluidic chips, mammalian cell culture and advanced imaging techniques. More information on our work can be found at https://research.aston.ac.uk/en/persons/roslyn-bill ", https://www.youtube.com/watch?v
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focused cryo-Cage development on a molecular level, including protein design, expression, purification and validation of formed cages using microfluidics diffusional sizing, DLS, mass photometry and cryo
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cells and microfluidics to generate mature and functional vascular tissues. This work will be completed as part of our multidisciplinary team studying the interactions between cells and their
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substrates. Collaborate with electrical engineers, microfluidics experts and nanofabrication specialists to develop portable devices for diagnostics and therapeutic drug monitoring. As a formal qualification
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for the parallelized monitoring of metabolites and environmental parameters to assess organoid- and assembloid formation Developing microfluidic chips that enable the multi parameter measurements of key molecular and