The studentship is available for UK, EU and International students, who possess or are about to obtain a first class or BEng (Honours), MEng or MSc degree, or equivalent EU/International qualification, in a relevant physical sciences or engineering discipline.
Eligible Subject: Applied Physics, Mechanical Engineering, BioMedical Engineering, Computational Engineering. Student should have some experience in the use Finite Element computational tools or equivalent ( example ANSYS, ABAQUS)
The research challenge is to design these devices for continuous use for longer than normal engineered life times in a fatigue prone environment of 10-20 years when the stress state is generally unknown. Devices essentially are constructed from a polyester tube, structurally supported by nitinol wire, either wound into a ring bundle or in a Z- profiled ring which is then inserted into the diseased arteries to strengthen the artery and improve flow patency. Furthermore, device failures may also arise when the device becomes occluded due to thrombosis accumulation or migration due to haemodynamic forces or vessel wall pulsation. While current developments in medical image scanning technologies have led to a better appreciation of such issues it is generally accepted that improved design can only result from advances in computational modelling technologies, ie simulation tools that can model full device- artery interaction and provide details of the stress state and local blood flow conditions, thus connecting device state to artery geometrical configurations.
The principal objectives of the project are three fold:
(i) To extend the current structural analysis techniques to model full device conditions in patient specific geometries for both Ring and Z-stent Terumo Aortic graft devices.
(ii) To assess the accuracy of the model by comparison to experimentally derived validation data.
(ii) investigate the use of the full device model using scans of human anatomy for a range of complex conditions.
The student will join a diverse international community of researchers, numbering over 70 academics, post docs and PhD students working with an established wide range of knowledge in modelling, numerical methods, experimental techniques and practical applications in similar and related fields. The department runs international visitor and internal student focussed seminar programmes, including researcher social events. The student will work within a recently revised and modernised open plan office environment which is co-located with academic staff offices. IT equipment will be provided and access to funding for conference attendance is available
The project will be supervised jointly by Dr William Dempster and Professor David Nash, both of the Department of Mechanical and Aerospace Engineering with the principal supervisor being Dr Dempster
Funding is provided by Scottish Research Partnership in Engineering and Termo Aortic. Funding is available for 4 years for full tuition fees (Home and EU applicants), along with a standard stipend (currently £15,009 for academic year 2019/20), and support with travel costs for the duration of the project. International students will be considered, but must provide evidence of sponsorship/funding, which will cover the difference between the Home/EU and International tuition fees
The project will be supervised jointly by Dr William Dempster and Professor David Nash, both of the Department of Mechanical and Aerospace Engineering with the principal supervisor being Dr Dempster. Both Dr Dempster and Prof Nash have a long standing relationship with Terumo Aortic in this area and succesfully supervised numerous PhD students
How to apply
Forward CV, together with cover letter, justifying interest to Dr W Dempster