This post will contribute to a multidisciplinary team using real anatomical data to replicate micro vessel structures in materials that are both mechanically and acoustically similar to tissue. The researcher will be expected to:
- Test, develop and optimise 3D printing protocols to produce vessel-like structures using hydrogel materials
- Incorporate the vessel-like structures they print within fluid flow systems to mimic real-life flow conditions in micro vessels
- Work with acoustic engineers to assess hydrogel acoustic properties and incorporate acoustic excitation of the fluid contained within the micro vessels
- Work with cell biologists to incorporate additive cell culture within the micro vessel mimics for future experimental investigation
For informal enquiries, please contact Dr Helen Mulvana (helen.mulvana@strath.ac.uk)
For further information see https://www.jobs.ac.uk/job/CAJ917/research-associate-303111
Closing date: 1st July 2020
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This post will contribute to a multidisciplinary team using real anatomical data to replicate micro vessel structures in materials that are both mechanically and acoustically similar to tissue. The researcher will be expected to:
- Test, develop and optimise 3D printing protocols to produce vessel-like structures using hydrogel materials
- Incorporate the vessel-like structures they print within fluid flow systems to mimic real-life flow conditions in micro vessels
- Work with acoustic engineers to assess hydrogel acoustic properties and incorporate acoustic excitation of the fluid contained within the micro vessels
- Work with cell biologists to incorporate additive cell culture within the micro vessel mimics for future experimental investigation
For informal enquiries, please contact Dr Helen Mulvana (helen.mulvana@strath.ac.uk)
For further information see https://www.jobs.ac.uk/job/CAJ917/research-associate-303111
Closing date: 1st July 2020