A Fully Implantable Self Powered Extra Aortic Counterpulsation Device? For Translational Development In Hypertensive Heart Failure
Funder
National Health and Medical Research Council
Funding Amount
$901,586.00
Summary
The development of a low cost self-powered cardiac aortic assist device to improve blood flow to the heart and rest of the body. The device is placed on the external surface of the large blood vessel (aorta) leaving the heart and provides gentle counterpulsation to improve blood flow. This aortic cardiac assist device is a therapeutic treatment for early stage heart failure.
The Neonav ECG Tip Location System: Better & Safer Care For Paediatric Intensive Care Patients
Funder
National Health and Medical Research Council
Funding Amount
$879,010.00
Summary
Babies and children can be critically ill. When they need intensive care, thin, flexible tubes (catheters) are placed in their blood vessels to deliver fluids and medications. Despite best efforts, catheters may not reach or move from the correct location inside the patient and the procedures may need to be repeated. Our solution is an innovative medical device that tracks where the catheter is during and after the procedure; this makes care safer and less stressful for the babies and children.
Development Of Endovascular Stents With Proactive Biocompatibility
Funder
National Health and Medical Research Council
Funding Amount
$428,470.00
Summary
Metallic cardiovascular implants, such as stents, used in the treatment of heart disease are not compatible with blood. They cause inflammation at the site of implantation and increase the risk of blood clots forming. We have developed a unique method of binding bioactive protein layers to the surface of metal alloys, and shown a significant improvement in their compatibility. Stents coated using our technology stand to dramatically improve the treatment of cardiovascular disease.
Biocompatible Synthetic Conduits To Treat Vascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$421,818.00
Summary
Clinically available synthetic conduits used in vascular repair and bypass are fundamentally incompatible with the vasculature. They cause inflammation at the site of implantation and increase the risk of blood clots forming. We have developed a unique method of binding bioactive protein layers to the surface of all polymeric materials and have shown a significant improvement in their compatibility. Grafts coated using our technology stand to dramatically improve the treatment of vascular diseas ....Clinically available synthetic conduits used in vascular repair and bypass are fundamentally incompatible with the vasculature. They cause inflammation at the site of implantation and increase the risk of blood clots forming. We have developed a unique method of binding bioactive protein layers to the surface of all polymeric materials and have shown a significant improvement in their compatibility. Grafts coated using our technology stand to dramatically improve the treatment of vascular disease.Read moreRead less
A portable device that can measure glycosylated haemoglobin (HbA1c) in the home will be developed. HbA1c is an important biomarker of the average blood glucose levels over the preceding three months and hence guides a diabetic regarding their blood glucose treatment regime. A 1% decrease in HbA1c levels is associated with a dramatic decrease in chronic health complications from diabetes. The HbA1c meter that will be developed will be able to operate with existing glucose meter technologies.
Development Of An Effective Therapy For Cheyne-Stokes Breathing In Heart Failure.
Funder
National Health and Medical Research Council
Funding Amount
$604,030.00
Summary
During sleep, patients with heart failure often exhibit a cyclic pattern of breathing in which a period of regular breathing alternates with a period when breathing ceases. This breathing pattern is associated with increased mortality and reduced quality of life but to date no effective treatment for it exists. We have developed a method to calculate an exact level of carbon dioxide to stabilise breathing in each individual, offering the prospect of a better night’s sleep and a longer life.