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Assessing a model of the physiological changes at arousal from sleep. Arousals from sleep are common in the elderly and have adverse consequences. This project will investigate a model of the changes in bodily processes (muscle, brain and cardiovascular activation) that occur when humans awaken from sleep.
Defining targets and generating tools/therapeutic agents for prevention, diagnosis and therapy of atherothrombosis. Atherosclerosis and its complications such as myocardial infarction and stroke are a major cause of death and disability in Australia and worldwide. The proposed research program investigates new therapeutic targets and concepts (e.g. targeting of stem cells) to treat atherosclerosis and aims to develop new therapeutic agents using modern biotechnological methods. The project furth ....Defining targets and generating tools/therapeutic agents for prevention, diagnosis and therapy of atherothrombosis. Atherosclerosis and its complications such as myocardial infarction and stroke are a major cause of death and disability in Australia and worldwide. The proposed research program investigates new therapeutic targets and concepts (e.g. targeting of stem cells) to treat atherosclerosis and aims to develop new therapeutic agents using modern biotechnological methods. The project further aims to develop nanoparticle-based diagnostic tools to identify and preventatively treat atherosclerotic plaques that are prone to cause myocardial infarction. The expected outcome will provide direct benefit to patients and create new economic opportunities in Australian bio-/nanotechnology.Read moreRead less
Targeting genes elevated in the athlete's heart to improve function of the failing heart. Cardiovascular disease affects about 3.7 million Australians and heart failure ranks as one of the major killers, representing a huge burden on our health care system and economy. This situation is likely to get worse with an increasing ageing population. Current therapeutics for heart failure patients largely delay disease progression but generally fail in significantly improving heart function and quality ....Targeting genes elevated in the athlete's heart to improve function of the failing heart. Cardiovascular disease affects about 3.7 million Australians and heart failure ranks as one of the major killers, representing a huge burden on our health care system and economy. This situation is likely to get worse with an increasing ageing population. Current therapeutics for heart failure patients largely delay disease progression but generally fail in significantly improving heart function and quality of life. The proposal has focused on targeting the protective effects of 'good' heart growth by identifying genes elevated in the heart in response to exercise. Targeting genes elevated in the athlete's heart to improve function of the failing heart represents a new strategy for the treatment of heart failure.Read moreRead less
Examining novel cell signalling in the regulation of platelet structure and function. Pharmaceutical inhibition of platelet function is the primary therapy for prevention of arterial thrombosis – the most common cause of death and disability in Australia. However, current therapies have limited efficacy. Defining platelet activation mechanisms in order to rationalise more effective antithrombotic approaches is the major focus of this research. This project describes the first studies to examine ....Examining novel cell signalling in the regulation of platelet structure and function. Pharmaceutical inhibition of platelet function is the primary therapy for prevention of arterial thrombosis – the most common cause of death and disability in Australia. However, current therapies have limited efficacy. Defining platelet activation mechanisms in order to rationalise more effective antithrombotic approaches is the major focus of this research. This project describes the first studies to examine the importance of a family of intracellular signalling enzymes, the Class II phosphoinositide 3-kinases, in platelet function. These studies will define the contribution of these enzymes to platelet production and function and will establish whether their inhibition is an attractive strategy for the prevention of arterial thrombosis.Read moreRead less
Improved identification of patients 'at risk' of depression, and optimal targeting of rehabilitation post-stroke through novel brain imaging and biomarkers. Use of novel brain imaging and biomarkers for identification of stroke survivors at risk of depression and recurrent stroke will permit early access to preventative and effective treatments for depression and improve capacity to benefit from rehabilitation. Development of predictive models to guide selection of most optimal rehabilitation st ....Improved identification of patients 'at risk' of depression, and optimal targeting of rehabilitation post-stroke through novel brain imaging and biomarkers. Use of novel brain imaging and biomarkers for identification of stroke survivors at risk of depression and recurrent stroke will permit early access to preventative and effective treatments for depression and improve capacity to benefit from rehabilitation. Development of predictive models to guide selection of most optimal rehabilitation strategies based on viable brain will maximise the capacity for persons with stroke to reach their full potential for recovery and ensure rehabilitation is more targeted and cost efficient. Improved capacity to benefit from treatment will have ongoing benefits for activity participation and productive living in Australians who experience stroke.Read moreRead less
Determining the molecular regulation of blood vessel development and angiogenesis. Abnormal blood vessel growth is associated with diseases including cancer, macular degeneration, diabetic retinopathy and chronic inflammation. This project focuses on understanding normal blood vessel growth in order to gather clues to help discover ways of preventing abnormal blood vessel growth during disease.
Novel mechanisms controlling signaling by adenosine monophosphate-activated protein kinase, central regulator of energy homeostasis. Sedentary lifestyles and consumption of high energy foods have led to dramatic increases in the incidence of obesity-related metabolic diseases such as type 2 diabetes and cardiovascular disease, placing enormous financial and medical burden on the Australian economy. An attractive drug target to treat these diseases is AMP-activated protein kinase (AMPK), which fu ....Novel mechanisms controlling signaling by adenosine monophosphate-activated protein kinase, central regulator of energy homeostasis. Sedentary lifestyles and consumption of high energy foods have led to dramatic increases in the incidence of obesity-related metabolic diseases such as type 2 diabetes and cardiovascular disease, placing enormous financial and medical burden on the Australian economy. An attractive drug target to treat these diseases is AMP-activated protein kinase (AMPK), which functions as both a cellular fuel gauge and co-ordinator of whole-body metabolism. Building on recent breakthroughs made at St. Vincent's Institute, this project will produce innovative research into novel mechanisms that control AMPK. These discoveries will greatly increase our understanding of AMPK regulation by cellular processes, and aid the design of more effective AMPK drugs.Read moreRead less
Using mouse genetics to understand skin development and cell biology. During embryonic development the skin forms a protective barrier which permits life outside the womb and provides a window into the biology of cells. This project aims to use the skin to identify and characterise genes necessary for embryonic development and maintenance, the development of diseases and to explore their broader roles in other organs.
Controlling apoptotic cell death in health and disease. Regulating how and when cells die is crucial for the development and maintenance of a healthy body and mind. This project will investigate the proteins that are responsible for controlling cell death with the view to identifying novel ways to target these proteins for the treatment of disorders such as cancer, neurodegenerative disease and autoimmunity.
New models of mitochondrial fatty acid oxidation disorders. Mitochondrial disease can affect both children and adults and is often fatal. This project will study mitochondrial function in cell types of the heart and brain to better understand how they generate energy in these tissues. This will provide new insights into mitochondrial metabolism and how defects in this process cause mitochondrial disease.