Optimizing The Management Of Osteoarthritis Through Research And Innovation
Funder
National Health and Medical Research Council
Funding Amount
$2,889,164.00
Summary
I will test new treatments aimed at slowing disease progression and reducing pain in osteoarthritis (OA) by targeting specific disease pathways (metabolic factors and inflammation). I will undertake work examining the causes of hip OA where little is known. All required methodologies and resources to undertake this work are available and the trials underpinned by strong scientific rationale. This research program has high potential for translation and for reducing the burden and cost of OA.
Determinants And Impact Of Patient-Centred Health Outcomes In Psoriatic Arthritis
Funder
National Health and Medical Research Council
Funding Amount
$84,069.00
Summary
Psoriatic arthritis is a chronic joint disease which is linked with the skin condition called psoriasis. People who have psoriatic arthritis can develop deformities in their joints and suffer from decreased quality of life. Psoriatic arthritis can present in a wide range of ways, but the reasons for this are not understood. This research aims to explain some of this variation and to predict which patients will develop more severe disease so treatment can be targeted to improve their outcome.
Airway Inflammometry For Asthma And COPD: Practitioner Fellowship Peter G Gibson
Funder
National Health and Medical Research Council
Funding Amount
$568,892.00
Summary
Asthma and chronic obstructive pulmonary disease will receive the benefits of personalized medicine with this Fellowship funding. Dr Gibson, an international leader in this field, has identified key biomarkers that will allow treatments to be rationalized based on the underlying disease mechanisms. This research will translate the benefits on modern technology and apply these to individualized care for people with asthma and COPD, who can expect fewer lung attacks and better quality of life.
Gene Expression Biomarkers Predict Severe Asthma Inflammatory Phenotype, Activation Mechanisms And Treatment Response
Funder
National Health and Medical Research Council
Funding Amount
$465,627.00
Summary
Asthma is now recognised to be made up of several disease variants or phenotypes, which are likely to have different underlying causes and mechanisms. We lack understanding of how to identify phenotypes of asthma and how they work, and this is delaying research that will lead to improvements in treatments and patient care. This is particularly important in people with severe disease. This grant will establish a gene test to identify asthma phenotype, and further understand mechanisms and treatme ....Asthma is now recognised to be made up of several disease variants or phenotypes, which are likely to have different underlying causes and mechanisms. We lack understanding of how to identify phenotypes of asthma and how they work, and this is delaying research that will lead to improvements in treatments and patient care. This is particularly important in people with severe disease. This grant will establish a gene test to identify asthma phenotype, and further understand mechanisms and treatment responses.Read moreRead less
National Clinical Centre Of Research Excellence In Severe Asthma
Funder
National Health and Medical Research Council
Funding Amount
$2,597,952.00
Summary
Severe Asthma remains a large burden for the Australian community. It does not respond to current management approaches. We will develop and implement a targetted therapy approach to severe asthma that will involve assessment of needs of people with severe asthma, community burden form severe asthma, biomarkers and linked treatment strategies, as well as knowledge transfer tools and training of the health and medical workforce.
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.