The Influence Of Gender And Steroid Hormones On Cerebrovascular NADPH Oxidase During Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$390,974.00
Summary
My research addresses several major questions regarding the regulation of brain blood flow and mechanisms that may contribute to stroke. There is confusion as to whether giving menopausal women hormone replacement worsens the effect of having a stroke. I propose that female hormones may lower blood flow to the brain after menopause and therefore cause more damage to the brain after stroke.
Complementary Medicines Based On Propolis Produced By Honeybees From Australian
Funder
National Health and Medical Research Council
Funding Amount
$285,855.00
Summary
Propolis produced by honeybees is a very complex mixture and its chemical composition varies in relation to its floral source. To produce propolis honey bees collect leaf bud and flowerbud exudates also secretions exuded from wounds in plants. These materials have high antibiotic activity as they have a natural function to protect delicate growing or wounded plant tissue from attack from microorganisms and animals. Honey bees use propolis to sterilize the hive and to protect it against outside i ....Propolis produced by honeybees is a very complex mixture and its chemical composition varies in relation to its floral source. To produce propolis honey bees collect leaf bud and flowerbud exudates also secretions exuded from wounds in plants. These materials have high antibiotic activity as they have a natural function to protect delicate growing or wounded plant tissue from attack from microorganisms and animals. Honey bees use propolis to sterilize the hive and to protect it against outside intruders and infection and to seal cracks in the hive. Consequently, humans have made use of propolis since ancient time for medicinal purposes. Modern research shows that a valuable property of propolis is its immunostimulant activity, now widely used in preventive medicine to boost the immune system. Furthermore, its antioxidant and anti-inflammatory properties are also believed to contribute to its current use in Complementary and Alternative Medicine (CAM). As part of research into the medicinal use of propolis produced in Australia, we identified two novel classes of biologically active constituents in Kangaroo Island (KI) propolis, which are for the first time identified to occur in propolis. Despite KI propolis being currently exported to Japan for use as CAM there is no study to determine its chemical composition or to evaluate its biological activities. Therefore we aim to research the KI propolis and evaluate its medicinal properties for use as CAM. Propolis from specific regions with defined floral sources and the identified constituents will be evaluated for their antioxidant property and protective activities against cell damaged after exposed to light source equivalent UV radiation of the sunlight with the aim to establish a defined propolis formula for topical use as CAM to prevent UV-induced skin cancers, known as melanoma, which is prevalent in Australia. This research will add value to a beekeeping product currently exported from KI and provide a health benefit.Read moreRead less
Antioxidant Enzymes Counter Reactive Oxygen Species From Steroidogenic Cytochrome P450 Enzymes In The Ovary To Limit Aneuploidy Of Embryos
Funder
National Health and Medical Research Council
Funding Amount
$536,978.00
Summary
Many birth defects are due to damage sustained by the eggs before ovulation. Aging allows more damage, hence the advice to have babies earlier in life. However, we believe we have identified a source of damage that happens during late development of the follicle in the weeks before ovulation. Proving this will enable us define when an egg is most at risk of damage and to devise strategies to lower the risk.
Investigating New Pathways In Acute Kidney Injury That Are Regulated By CD47
Funder
National Health and Medical Research Council
Funding Amount
$508,848.00
Summary
Acute kidney injury (AKI) is a widespread problem affecting both native and transplanted kidneys. Studies indicate that the incidence has increased more than 200-fold in the last decade, as has mortality. AKI also predisposes to the development of chronic kidney disease. There is no effective therapeutic for treatment or prevention of AKI. This project will investigate new cell signalling pathways regulating AKI with a view to developing these as novel clinical therapies.
Endosomal Reactive Oxygen Species In Tumour Angiogenesis
Funder
National Health and Medical Research Council
Funding Amount
$633,739.00
Summary
Cancer claims more lives worldwide than any other disease affecting millions of people annually. Tumours grow and spread in the body by acquiring their own blood vessels that provide them with nutrients and oxygen. We have identified a new protein called NADPH oxidase that promotes the development of these new blood vessels in tumours. We propose to test new drugs that block NADPH oxidase activity to stop the development of new blood vessels for the potential treatment of cancer
The Role Of Specific Nox Isoforms In Diabetic Renal Disease And Atherosclerosis
Funder
National Health and Medical Research Council
Funding Amount
$460,396.00
Summary
Diabetes is increasing worldwide and in Australia. The majority of patients with diabetes eventually will develop kidney disease and will die of blood vessel complications such as heart attacks and stroke. Oxidative stress (the generation of free oxygen radicals that react quickly with other proteins in the body causing tissue damage) has been suggested to play an important role in kidney and blood vessel disease observed in diabetic patients. This proposal will try to identify and measure speci ....Diabetes is increasing worldwide and in Australia. The majority of patients with diabetes eventually will develop kidney disease and will die of blood vessel complications such as heart attacks and stroke. Oxidative stress (the generation of free oxygen radicals that react quickly with other proteins in the body causing tissue damage) has been suggested to play an important role in kidney and blood vessel disease observed in diabetic patients. This proposal will try to identify and measure specific proteins in the kidney and vessels that are involved in the production of oxidative stress. We aim to define which one of these proteins is the most important. We will assess in detail how these proteins work and which other factors are activated leading to tissue damage. The ultimate goal of these studies is to find new treatment options to decrease the production of harmful molecules in the kidney and blood vessel wall thereby reducing kidney failure, heart attacks, stroke and gangrene in diabetes. In our studies, we will use medications already used in patients to treat high blood pressure in diabetes. In preliminary studies we have shown that these drugs also reduce oxidative stress. Furthermore, we will use novel, more specific treatments that the harmful ptoteins. Through a collaboration with Professor Harald Schmidt and his group from Germany who have recently moved to Monash University in Melbourne we will have access to mice in which specific genes for harmful proteins have been knocked out. These mice when made diabetic will most likely develop less or no kidney and blood vessel damage. Our studies will help to identify the most important oxidative stress producing protein associated with kidney and vessel disease. This knowledge will lead to more effective and more potent treatments for patients with diabetes to prevent, stop or even improve kidney and blood vessel disease thereby reducing disability and death in this high risk group of patients.Read moreRead less
Cellular Metabolism And Signalling In Cardiac Development And Congenital Disease
Funder
National Health and Medical Research Council
Funding Amount
$151,061.00
Summary
This project aims to investigate how the paediatric heart responds to oxidative cellular stresses during cardiac development, surgical stress and congenital heart disease. Pre-surgical interventions aims at improving cardiac function following surgery will be examined, with cellular models being used to determine molecular pathways of cardioprotection, as well as testing agents which may limit cellular damage under surgical stress and disease.