Improving Kidney Transplant Outcomes Using Normothermic Machine Perfusion
Funder
National Health and Medical Research Council
Funding Amount
$778,232.00
Summary
Kidneys donated for transplantation are at risk of damage that prevent the organ from working and reduce its lifespan. Normothermic machine perfusion is a device that can circulate oxygenated blood at normal body temperature through a donor kidney prior to transplantation. In doing so it is able to resuscitate the kidney and prevent injury. We will determine how machine perfusion achieves this remarkable effect and investigate new treatments for kidney injury.
Facial paralysis results in loss of the ability to blink, which is the primary means of protecting and lubricating the eye. The eye becomes dry and ulcerated and eventually vision loss ensues. No therapy exists that can reliably restore blink and hence treatment is mostly palliative today. BLINC is an implantable device that artificially restores eye closure. It is wirelessly powered and readily implantable. BLINC has achieved eye closure similar to natural blinking in human cadaveric models.
A Suture-less Cannula For Rapid, Off-bypass Implantation Of Left Ventricular Assist Devices
Funder
National Health and Medical Research Council
Funding Amount
$816,491.00
Summary
Heart transplantation is the ideal treatment for 300,000 Australians living with chronic heart failure. The lack of donor hearts necessitates the use of implantable mechanical hearts; however, bleeding and blood clots are common due to outdated surgical tools, poor body-device integration and unnatural device blood flow. This project will address these limitations through the development of a rapid and safe implantation tool that integrates with the body and produces natural blood flow dynamics.
Improving Cardiac Valve Implant Outcomes With Advanced Computer Simulation
Funder
National Health and Medical Research Council
Funding Amount
$593,367.00
Summary
This project focuses on improving heart valve procedures, specifically focusing on new transcatheter techniques of heart valve implantation. The research uses advanced imaging and computer simulation techniques to predict the outcome and improve minimally invasive heart procedures.
Predicting Fracture Outcomes From Clinical Registry Data Using Artificial Intelligence Supplemented Models For Evidence-informed Treatment (PRAISE) Study
Funder
National Health and Medical Research Council
Funding Amount
$636,217.00
Summary
This project will establish the role of artificial intelligence (AI) techniques to improve the prediction of clinical and longer-term patient reported outcomes following wrist fracture. Prediction models based on existing, routinely collected registry data with will be compared with models based on registry data enhanced by AI analysis of X-ray images, radiology reports and surgical reports. The AI analysis will reason on both image and text data, better replicating how humans learn.
Advancing The Spatial Analysis Of Cells In Tissues To Profile The Tumour Microenvironment
Funder
National Health and Medical Research Council
Funding Amount
$187,918.00
Summary
Tumours are composed of a mix of different cells, including cancer cells, immune cells and other cells supporting tumour growth. These cells are not organised randomly, but rather are distributed in specific patterns. Here we will develop computational methods to detect these patterns and determine what statistical tests should be used to compare samples. This project will give us the tools to investigate how the location of cells in tissues relates to treatment response and survival.
Biomechanics Meets Phenomics: Towards Understanding And Predicting Abdominal Aortic Aneurysm (AAA) Disease Progression
Funder
National Health and Medical Research Council
Funding Amount
$1,324,897.00
Summary
The criterion used to decide whether to operate on an abdominal aortic aneurysm (AAA), based on the maximum diameter, does not take into consideration the rupture risk for a given patient. By combining imaging, computational biomechanics and metabolic phenotyping, we will assess the structural integrity of an AAA and local structural changes of systemic response. These will allow improved differentiation of rupture risk, leading to better outcomes for patients and savings for the health system.
Exploiting Messenger RNA Export As A Novel Therapeutic Strategy To Treat Cancer
Funder
National Health and Medical Research Council
Funding Amount
$948,098.00
Summary
Novel therapies for cancers represent an area of unmet clinical need. We have identified a new biological pathway implicated in cancer, namely selective mRNA export. Compounds inhibiting other steps of the gene expression pathway are promising therapeutic candidates for cancer, yet mRNA export inhibitors do not exist. We propose to develop first-in-class inhibitors of mRNA export that selectively target transcriptionally addicted cancers with dysregulated RNA processing.
Pathways That Regulate Nuclear Export Of Circular RNA
Funder
National Health and Medical Research Council
Funding Amount
$933,327.00
Summary
An emerging and unusual class of RNA molecules, circular RNAs (circRNAs), is widespread and plays important roles in cancer initiation and progression. However, the pathways responsible for nuclear export of circRNAs are unknown. We propose here to systematically determine how circRNAs are exported from the nucleus and characterise the effect of modulating circRNA export pathways in cancer. This will enable us to determine whether circRNAs can function as a biomarker of patient response.