Blood pressure control by neural activation: underlying mechanisms of electric field stimulation and photostimulation of genetically targeted neurones. This project aims to understand how nerve stimulation can be used to treat drug-resistant high blood pressure. The project will lead to new benchmarks for interfacing novel technology with the nervous system and to development and enhancement of commercial devices similar to a cardiac pacemaker for patients with limited treatment options and poor ....Blood pressure control by neural activation: underlying mechanisms of electric field stimulation and photostimulation of genetically targeted neurones. This project aims to understand how nerve stimulation can be used to treat drug-resistant high blood pressure. The project will lead to new benchmarks for interfacing novel technology with the nervous system and to development and enhancement of commercial devices similar to a cardiac pacemaker for patients with limited treatment options and poor prognosis.Read moreRead less
Highly multiplexed rapid-analysis microarrays for early disease diagnosis. Molecular diagnostics are revolutionising the treatment of disease in hospitals by providing rapid and accurate identification of pathogens; saving costs, time and lives. This project will accelerate this revolution by combining new array technology from the University of Sydney with a proven multiplex method from the Sydney based company, AusDiagnostics.
Electrochemical biosensors for detection of cardiac disease markers in blood. Cardiovascular diseases leading to heart failure have a prevalence of over 16 per cent in Australia. The social, economic and health burden is higher than for any other disease group. Hence, it is critically important to develop fit-for-purpose sensors of known cardiac biomarkers, which alert patients and clinicians of the risk of imminent heart failure.
Hybrid radiofrequency/optical catheter for effective atrial fibrillation ablation. This research project aims to advance engineering knowledge by applying an innovative, fibre-optics-based discrete optical coherence tomography to technology used for atrial fibrillation catheter ablation. RadioFrequency catheter-based ablation is far superior to cardiac drug therapy for atrial fibrillation patients. RadioFrequency catheters are not equipped with real-time lesion formation monitoring means, which ....Hybrid radiofrequency/optical catheter for effective atrial fibrillation ablation. This research project aims to advance engineering knowledge by applying an innovative, fibre-optics-based discrete optical coherence tomography to technology used for atrial fibrillation catheter ablation. RadioFrequency catheter-based ablation is far superior to cardiac drug therapy for atrial fibrillation patients. RadioFrequency catheters are not equipped with real-time lesion formation monitoring means, which enable the assessment of continuity-transmurality and prevent extra-cardiac complications, such as steam pops. Optical Coherece Tomography enables non-invasive, microscopic lesion formation assessment in real time during atrial fibrillation ablation procedures. The expected outcomes of this project are to develop a new hybrid fibre-optic/RadioFrequency catheter system and user-friendly driving software that will enable cardiac electrophysiologists to perform three key tasks not previously available.Read moreRead less
Haemodynamic investigation of flow diverter stents for the treatment of intracranial aneurysms. This project will explore the engineering of a flow diverter, an endovascular device for the treatment of brain aneurysms. The project will determine the optimal design of new types of flow diverters, which in turn could improve the effectiveness of treatments, thus reducing the associated costs of cerebral haemorrhage and stroke.
Technology optimisation of integrated circuits with applications to wireless communication systems in medicine. This project will define and verify methods to help engineers pick the best technology for designing critical wireless monitoring systems used for medical devices. This project will also verify these methods by developing a wireless, implantable blood pressure monitor with real-time video.
Laser powered miniature bionic devices. Laser powered miniature bionic devices. This project aims to develop a laser-based system to wirelessly power and control implantable medical micro-devices. Very-large-scale integration technology has miniaturised microelectronic medical implants, but energy systems have not shrunk; the wireless power/data interface is most of the implant’s volume. This project intends to develop an optical power/data interface to achieve high power density transfer to a m ....Laser powered miniature bionic devices. Laser powered miniature bionic devices. This project aims to develop a laser-based system to wirelessly power and control implantable medical micro-devices. Very-large-scale integration technology has miniaturised microelectronic medical implants, but energy systems have not shrunk; the wireless power/data interface is most of the implant’s volume. This project intends to develop an optical power/data interface to achieve high power density transfer to a miniaturised retinal implant housed entirely within a single self-contained transparent diamond capsule without any external lead wires. This safe and robust power/data delivery will exploit the outstanding transparency, biocompatibility and biostability of diamond encapsulation, thus enhancing the international competitiveness of the Australian medical device sector.Read moreRead less