Black Out Advisory System - Development Of An Implantable Sub-scalp Seizure Monitor
Funder
National Health and Medical Research Council
Funding Amount
$868,402.00
Summary
Blackouts may result from seizures or heart problems, and incorrect diagnosis exposes patients to risk and limits activities. Diagnosis is difficult because these events are infrequent. Implantable monitors are useful in diagnosing cardiac abnormalities, but prolonged seizure monitoring has not been feasible. This system will use a minimally invasive implant inserted under the scalp enabling distinction of epileptic from non-epileptic causes. The implant also has the capability to improve patien ....Blackouts may result from seizures or heart problems, and incorrect diagnosis exposes patients to risk and limits activities. Diagnosis is difficult because these events are infrequent. Implantable monitors are useful in diagnosing cardiac abnormalities, but prolonged seizure monitoring has not been feasible. This system will use a minimally invasive implant inserted under the scalp enabling distinction of epileptic from non-epileptic causes. The implant also has the capability to improve patient safety through remote monitoring.Read moreRead less
Development Of A High Acuity, Diamond Retinal Prosthesis
Funder
National Health and Medical Research Council
Funding Amount
$1,010,214.00
Summary
Over recent years our team has developed a retinal implant to restore sight to people with certain types of blindness. With 256 independently controllable electrodes this device is among the most sophisticated in the world. We aim to conduct experiments to demonstrate that our device can provide improved better visual acuity than the world leaders with a view to developing a competitive commercial medical technology.
Enhanced Deep Brain Stimulation Electrodes For Improved Efficacy In Parkinson’s Disease Therapy
Funder
National Health and Medical Research Council
Funding Amount
$809,940.00
Summary
We are developing an advanced Deep Brain Stimulation system to improve the treatment for Parkinson’s disease. Current devices benefit only half of the patients, due to imprecision in directing the electrical current to the ideal brain targets. Our system aims to deliver the current more selectively. Our implant will contain more and smaller electrodes. We will also use a state-of-the-art stimulator, implantable on the head, with capabilities far beyond the current technology.
Potent Antibiotics Against Drug-resistant Tuberculosis
Funder
National Health and Medical Research Council
Funding Amount
$531,410.00
Summary
Tuberculosis (TB) is a significant killer and caused 1.7 million deaths in 2009. The disease affects all countries, including Australia, in which the incidence in the indigenous population is 14 times higher than that in the non-indigenous population. We will develop a new anti-TB drug that can replace or enhance the current drugs that are not effective against drug resistant TB.
Superior Surgical Fixation Using A Novel Orthopaedic Expandable Fastener
Funder
National Health and Medical Research Council
Funding Amount
$414,076.00
Summary
Surgeons repair bone fractures using metal plates and screws. Sometimes the screws loosen and the surgery needs to be repeated. Expandable screws are stronger, but more difficult and sometimes impossible to remove. The research team will test a new type of screw that holds the bones together with greater strength (our current work shows 40% stronger) but can be removed easily if necessary. This grant will allow extensive mechanical testing in preparation for a first-in-human clinical trial.
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.
Dengue Fever Vaccine: Towards Low Cost Production And Delivery
Funder
National Health and Medical Research Council
Funding Amount
$612,039.00
Summary
With rising populations and a warming climate mosquito borne viral diseases will become more prevalent and low-cost vaccine production & delivery systems will become increasingly important. Here a microalgae based vaccine production platform will be coupled to proven Nanopatch & low cost oral vaccine delivery. The focus is on a Dengue virus vaccine, as Dengue causes 400 million infections & 100 million symptomatic cases annually.
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
Manufacture And Testing Of Next Generation Orthopaedic Implants Harnessing Periosteum's Regenerative Power
Funder
National Health and Medical Research Council
Funding Amount
$508,314.00
Summary
Tissue defects, e.g. due to trauma or tumor removal, are too large to heal without reconstructive surgery. Complications associated with defect repair may diminish the patient's quality of life and productivity, posing significant medical and psychosocial costs. Here we propose a plan to define technical specifications for next generation, "smart" orthopaedic implants that deliver cells and the signals they need to build new tissue using nature's paradigms.
Dengue virus is the most important mosquito-borne viral disease, with 2/3 of the world's population at risk. There is currently no treatment available for dengue. Our proposal aims to progress a safe and effective new treatment (4-HPR) against Dengue towards the clinic, generating all the required pharmacokinetic and pre-clinical animal data necessary to progress to a future clinical trial in humans. We will also investigate the use of 4-HPR as a dengue preventative.