How Does Activated Protein C Create Intact, Non-leaky, Stable Blood Vessels?
Funder
National Health and Medical Research Council
Funding Amount
$564,644.00
Summary
Vascular dysfunction is a common feature of many diseases, including sepsis, diabetes, atherosclerosis, tumours and asthma. These vessels have compromised structural and functional integrity, leading to leakage of blood components and causing inflammation in tissues. Based on our recent findings, this project aims to discover how activated protein C creates normal, healthy non-leaky blood vessels and prevents vascular dysfunction in disease.
Targeting Neurovascular Communication As A Novel Way Of Reducing Vision Loss In Diabetes
Funder
National Health and Medical Research Council
Funding Amount
$986,663.00
Summary
Diabetes is a leading cause of blindness. Here, we evaluate whether diabetes causes changes in the way neurons signal to blood vessels, and whether blocking some of the signals from neurons reduces blood vessel abormalities. Overall, this information is critical to our understanding of the early changes that occur during diabetes and whether novel treatments used early in diabetes can prevent long term changes and vision loss.
Therapeutic Approaches To Circumvent NO• Resistance In The Type 2 Diabetic Heart And Vasculature
Funder
National Health and Medical Research Council
Funding Amount
$563,337.00
Summary
Type 2 diabetes (T2D) is Australia’s fastest growing chronic disease, affecting almost 2 million Australians (who face poor cardiovascular health outcomes). We have discovered an exciting new avenue that may potentially more effectively counteract heart and blood vessel disorders in T2D patients in an acute cardiovascular emergency, of substantial clinical importance.
Are Novel Nitric Oxide Mimetics Protective In Vascular Disease?
Funder
National Health and Medical Research Council
Funding Amount
$634,044.00
Summary
Nitric oxide (NO) is a biologically active gas which controls blood flow and blood pressure. New drugs which mimic the effects of NO show promise in the treatment of cardiovascular disease. This study investigates the ability of NO mimetics to protect blood vessels in disease, by limiting the production of toxic molecules, improving blood flow and preventing blood clot formation. The information gained may lead to the development of new therapies for blood vessel diseases such as stroke.
A Novel Pathway For The Regulation Of Vascular Tone
Funder
National Health and Medical Research Council
Funding Amount
$596,550.00
Summary
The regulation of blood pressure is complex involving the nervous system, kidneys and local pathways that generate blood vessel relaxing and constricting factors. We recently discovered a novel local pathway that becomes induced during inflammation and generates a relaxing substance from the amino acid tryptophan. The present project will identify the active substance and characterize how it causes blood vessel relaxation and thus contributes to the regulation of blood pressure.
Role Of Epigenetic Mechanisms In Diabetic Vascular Complications
Funder
National Health and Medical Research Council
Funding Amount
$438,520.00
Summary
Diabetic complications including heart attacks, strokes, kidney disease and blindness appear to be related to the high glucose (sugar) level but how glucose itself induces end-organ injury remains to be fully determined. In this proposal it is suggested that the long-term damaging effects of glucose relate to its ability to damage the regulation of genes by directly affecting DNA and its covering known as histones. Specifically glucose, possibly by altering certain biochemical pathways called ox ....Diabetic complications including heart attacks, strokes, kidney disease and blindness appear to be related to the high glucose (sugar) level but how glucose itself induces end-organ injury remains to be fully determined. In this proposal it is suggested that the long-term damaging effects of glucose relate to its ability to damage the regulation of genes by directly affecting DNA and its covering known as histones. Specifically glucose, possibly by altering certain biochemical pathways called oxidation pathways, interferes with enzymes which affect the structure of DNA and related molecules resulting in altered expression of many proteins. One of these proteins known as NF kappa B is activated in diabetes, probably by mechanisms involving regulation of these enzymes which play a central role in modifying gene structure. By clarifying the exact mechanisms at a molecular level that mediate the effect of glucose on genes and proteins it will be possible to target these molecules and develop new treatments to prevent, retard or reverse the blood vessel complications that are so common in diabetes.Read moreRead less
Feasibility, Safety, Adherence, And Efficacy For High Intensity Interval Training In A Hospital-Initiated Rehabilitation Program For Heart Disease
Funder
National Health and Medical Research Council
Funding Amount
$75,779.00
Summary
This project aims to investigate if high intensity interval training can be successfully integrated into a hospital-based cardiac rehabilitation program as a practical and safe alternative to the usual care exercise protocol (moderate intensity continuous training). We expect high intensity interval training will be a safe and practical option for appropriate patients, and will offer greater improvements in fitness, exercise adherence, cardiovascular risk factors, and intra-abdominal fat.