Improving The Functional Outcomes Of Lower Limb Orthopaedic Surgery
Funder
National Health and Medical Research Council
Funding Amount
$425,048.00
Summary
While orthopaedic surgery usually achieves pain relief and improves function somewhat, it can often leave a patient unable to perform certain activities. And these abnormal movement patterns are likely to cause further problems. This project will objectively measure post-surgical function, in order to improve the surgery and rehabilitation of some of the most complex orthopaedic conditions. The goal is that patients receive the maximum benefit from surgery.
WHY YOUNG PEOPLE DEVELOP OLD KNEES: PREDICTORS OF EARLY JOINT CHANGES FOLLOWING KNEE LIGAMENT RECONSTRUCTION
Funder
National Health and Medical Research Council
Funding Amount
$415,218.00
Summary
My research investigates how muscles & movement patterns (i.e. biomechanics) contribute to early adverse knee cartilage & bone changes in young individuals at risk of developing premature knee osteoarthritis (OA): a debilitating disease causing pain & diminished quality of life. Biomechanical measures selected can be modified with interventions such as exercise & gait retraining. Ultimately, my research could reduce future risk of knee OA & its resultant personal & societal costs.
The emerging interdisciplinary field, mechanobiology, is focused on understanding how cells sense their surroundings and transfer biomechanical signals to initiate cellular changes. I aim to develop hydrogel platforms with differential stiffness patterns to study cellular mechanotransduction and to generate heart muscle cells. The findings have the potential to greatly improve the clinical outcomes where more than 10 clinical trials failed to show successful regeneration after heart attack.
Patient-specific Modelling Of Cardiovascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$428,065.00
Summary
Cardiovascular disease is undoubtedly the biggest killer in the developed world and accounts for 30% of all deaths in Australia; killing one Australian every twelve minutes. My research group and I, combine medical imaging with biomedical engineering to perform patient-specific modelling. For example, we can predict the likelihood that aneurysm will rupture or the way blood flows through the aorta. My goal is to make these modelling tools accurate and robust enough to be used in the clinic.