QUEX PhD Scholarship - Design, optimisation, and fabrication of patient-specific multi-phasic total disc replacements to address age-related degenerative disc disease

Summary

Enrolment status New students
Student type Domestic students, International students
Level of study Higher Degree by Research
Study area Engineering and Computing
HDR funding type Living stipend scholarship, Travel Scholarship
Scholarship value $28,092 per annum tax-free (2020 rate), indexed annually, tuition fees and Overseas Student Health Cover (where applicable). A travel grant of AUD $8,500 per annum, and a training grant of AUD $3,000 are also available over the program.
Opening date 3 February 2020
Closing date 30 April 2020

Description

The University of Queensland and the University of Exeter are seeking exceptional students to join a world-leading, cross-continental research team tackling major challenges facing the world’s population in global sustainability and wellbeing as part of the recently launched QUEX Institute. The joint PhD programme provides a fantastic opportunity for the most talented doctoral students to work closely with world class research groups and benefit from the combined expertise and facilities offered at the two institutions. This prestigious programme provides full tuition fees, stipend, travel funds and Research Training Support Grants to the successful applicants.

Spinal problems affect over 80% of the population, the majority of which are aged, representing a major and growing social and an economic burden on health services world-wide, currently costing more than 200 billion USD a year. These problems are frequently associated with the degeneration of the intervertebral disc (IVD), a condition that is highly penetrant within our ageing population and severely limits their ability to participate and contribute to society. Unfortunately, treatments have limited success. Spinal fusion is the sixth most common operating procedure in the US (488,000 per year), but the most costly (total $12.8 billion per year). This procedure can provide pain relief, but can cause increased stress on adjacent tissues, leading to a degenerative cascade. Total disc replacement (TDR) provides an alternative, but current devices show little to no improvement in clinical outcomes over the fusion procedures they are designed to supersede. We believe this situation arises because no current TDRs replicate the unique biophysical (mechanical) properties of the IVD. We propose in this PhD project to develop a ‘design, optimisation, and fabrication’ pipeline for patient-specific multi-phasic TDRs that can be tailored to the mechanical environment of a particular patient’s spine, and through this mechanical-matching, support the generation of new tissue from a patient’s own stem cells. Our collaboration provides the broad range of expertise to achieve this urgently required outcome.

This project will build on previous work performed at the University of Queensland on the construction of regenerative multi-component, multi-phasic scaffolds using a novel additive biofabrication methodology, and differentiation of human tissue-derived stem cells into IVD cells, with added expertise at the University of Exeter in multi-axis spinal loading, and biomechanical optimisation techniques using finite element modelling. Supported by these previous achievements and expertise, this project will focus on the development of a “design, fabricate, optimise (DFO)” total disc replacement (TDR) pipeline.

The successful applicant will investigate the design and fabrication of a multi-scale total disc replacement, develop a finite element model, complete topological optimisation of the TDR design using level-set or gradient-based methods, and validate optimisation algorithms and outputs against in-vitro test data. The optimised disc design produced from this project will form the basis of a patient-specific, regenerative total disc replacement, which will be assessed in vitro for its ability to support the differentiation of human mesenchymal stems into the appropriate cellular phenotypes present in the IVD under loads mimicking those experienced by the IVD in humans.

Eligibility

To be eligible, you must:

 

Applications are closed.

Before you get started

If this scholarship has rules, download and read them.

How to apply

To be considered for this scholarship, please email the following documents to Professor Justin Cooper-White (j.cooperwhite@uq.edu.au). Please include "QUEX PhD Scholarship" in the subject line of your email. 

  • Cover letter
  • CV
  • Academic transcript/s
  • Evidence for meeting UQ's English language proficiency requirements eg TOEFL, IELTS

Please note the following: Submitting the above documents does not constitute a full application for admission into The University of Queensland's PhD program. If you are selected as the preferred applicant, you will then be invited to submit a full application for admission. You can familiarise yourself with the documents required for this process on the Graduate School's website.

Selection criteria

A bachelor’s degree with first class honours or a coursework master’s degree and an overall GPA (grade point average) equivalent to 5.65 on the 7-point UQ scale, which includes a relevant research component.

Applications are closed.

Contact

Professor Justin Cooper-White
Applications are closed.

Terms and conditions

Read the policy on UQ Research Scholarships.

A domestic part-time student with carer’s responsibilities, a medical condition or a disability, which prevents them from studying full time may be eligible for scholarship consideration, on a case by case basis.

Students must be willing to undertake part of their study at both institutions (a minimum of 1 year at the host). 

In instances where the candidate is awarded a scholarship after commencement there will be no retrospective payments of this scholarship. 

Applications are closed.