Innovations In Cancer Imaging And Targeted Radiotherapy To Improve Human Health
Funder
National Health and Medical Research Council
Funding Amount
$926,980.00
Summary
Through a process of discovery, development and investigation we will create medical devices and methods to improve cancer imaging and targeted radiotherapy. Successful completion of this program will directly impact on the treatment and lives of Australian cancer patients in the foreseeable future.This program will substantially build research capacity and productivity within Australia, raise Australia’s profile in cancer research and foster international collaboration.
Development Of A Non-invasive Magnetic Resonance Based Cartilage Damage Assessment Technique
Funder
National Health and Medical Research Council
Funding Amount
$556,131.00
Summary
This project will develop automated methods for the extraction of 3D maps of cartilage, bone and other anatomy from high field Magnetic Resonance Images of joints in the body.
MR Hip Intervention And Planning System To Enhance Clinical And Surgical Outcomes
Funder
National Health and Medical Research Council
Funding Amount
$668,069.00
Summary
Degenerative hip disorders and osteoarthritis are a major cause of chronic pain and disability. This project will develop a software tool that allows clinicians to assess, monitor and plan patient treatment using magnetic resonance imaging. It will be the first tool that models joint motion using assessments of bone, cartilage and labral tissue. This will help guide treatment selection and improve outcomes from hip surgeries performed on over 20,000 Australians each year.
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.
Our overall objective is to significantly improve the efficacy and efficiency of image-guided neurosurgery for brain tumours by including realistic computation of brain deformations, based on a biomechanical model, in a system to improve intra-operative visualisation, navigation and monitoring. The system will create an augmented reality visualisation of the intra-operative configuration of the patient’s brain merged with high resolution pre-operative imaging data.
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.