Development Of A Chronically Implantable, Miniaturised Device For Monitoring Ventricular Function, To Assist Tracking An
Funder
National Health and Medical Research Council
Funding Amount
$335,000.00
Summary
Heart failure (HF) is increasing - with ~5million sufferers (1-3rd in New York Heart Association Class III-IV i.e. severe cases) in the US alone, and ~12-15 million worldwide. Its management consumes health resources and strains sufferers, families and institutions. The proposed monitoring-management device, chronically implanted by minimally invasive surgery, will track the heart’s pumping pattern. It will allow informed decisions to optimise therapy, thereby improving Quality of Life (QOL), de ....Heart failure (HF) is increasing - with ~5million sufferers (1-3rd in New York Heart Association Class III-IV i.e. severe cases) in the US alone, and ~12-15 million worldwide. Its management consumes health resources and strains sufferers, families and institutions. The proposed monitoring-management device, chronically implanted by minimally invasive surgery, will track the heart’s pumping pattern. It will allow informed decisions to optimise therapy, thereby improving Quality of Life (QOL), decreasing hospitalisations and decreasing healthcare costs. We aim to develop a small, chronically and easily implantable device to track changes in heart function in HF patients.Read moreRead less
Exercise As Medicine For Heart Failure: A Novel Intervention To Improve Outcomes
Funder
National Health and Medical Research Council
Funding Amount
$665,585.00
Summary
Heart failure (HF) is a common, debilitating and expensive disease; prognosis remains poorer than for the most cancers. 30,000 Australians are diagnosed every year and 300,000 live with the HF, at an annual cost of ~$1Billion. Exercise training is effective therapy in HF, because it reverses many of the problems that contribute to the reduced lifespan and impaired quality of life of patients with HF. We will test an exciting new type of exercise that promising greater benefit, at lower risk.
Function Of The S100A1 Ca2+-binding Protein Under Physiological And Pathological Conditions
Funder
National Health and Medical Research Council
Funding Amount
$452,545.00
Summary
The S100A1 protein is one of the most abundant proteins in human heart muscle cells. It binds calcium ions and may play a role in the regulation of heart function. S100A1 levels are reduced in human heart failure, but it is unclear whether this reduction contributes to worsening of the disease. To study this, we have generated a genetically modified mouse strain that cannot make the S100A1 protein. We will use these mice to study how important the protein is for heart function under normal condi ....The S100A1 protein is one of the most abundant proteins in human heart muscle cells. It binds calcium ions and may play a role in the regulation of heart function. S100A1 levels are reduced in human heart failure, but it is unclear whether this reduction contributes to worsening of the disease. To study this, we have generated a genetically modified mouse strain that cannot make the S100A1 protein. We will use these mice to study how important the protein is for heart function under normal conditions, and how it contributes to the development of heart failure. Preliminary data indicate that adult mice with reduced S100A1 protein levels develop a form of heart disease that significantly reduces the efficiency of the pump function of the heart.Read moreRead less
Low Cost High Precision Radiotherapy: A Synergistic Framework For Tumour Tracking During Treatment
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
Advances in technology have enabled radiotherapy to become more sophisticated and more efficient at treating cancer. Yet, despite its sophistication, today radiotherapy suffers from a major problem: whilst we routinely image patients prior to treatment, no anatomical information is available during treatment. This project aims to solve this problem by making use of a number of sensors that are already available in a radiotherapy to track the tumours positions during treatment, when it counts.
Real-time In-vivo Imaging During Lung Cancer Radiotherapy
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
Lung tumours move in clinically significant and unpredicable ways. Current radiotherapy is limited by the lack of real-time imaging to monitor tumour motion. The aim of this project is to develop and clinically implement Real-time In-vivo Imaging to enable motion-adaptive radiotherapy and thereby improve treatment outcomes. Real-time In-vivo Imaging is a software technology that will be applicalbe to 90% of modern radiotherapy systems globally and will enable wide access to advanced cancer care.