The Role Of Tissue Hypoxia In The Evolution Of Kidney Disease
Funder
National Health and Medical Research Council
Funding Amount
$509,391.00
Summary
We will determine how low oxygen levels in the kidney lead to kidney disease. We can now measure the levels of oxygen in kidney tissue in rats 24 hours a day, 7 days a week, in a completely non-invasive way. We will study two common kinds of kidney disease. One, acute kidney injury, can result from administration of contrast agents used in x-ray diagnostic procedures. The other, chronic kidney disease, is common in patients with diabetes or high blood pressure.
Towards Prevention Of Acute Kidney Injury After Cardiac Surgery
Funder
National Health and Medical Research Council
Funding Amount
$771,918.00
Summary
Open heart surgery saves thousands of lives each year in Australia, but often injures the kidney. Kidney oxygen deficiency is a major cause of kidney injury. We propose a new way to manage kidney oxygen levels during heart surgery, by measuring the level of oxygen in the urine in the bladder. We will determine whether low levels of oxygen in the urine during surgery predict later development of acute kidney injury, and whether patient management can be changed to optimize kidney oxygen levels.
This project examines the types of computations used by brain cells to combine two types of sensory information, in a way that allow us to reach better decisions in everyday life. To address this general problem, we will perform experiments that explore the combination of signals from vision and hearing. The ability to combine sensory information is vital to our mental health, and this process is compromised in a range of psychological, psychiatric and neurological disorders.
I am a physiologist working to understand how disturbances during pregnancy can alter fetal development and increase the risk of developing adult onset diseases such as cardiovascular disease, renal disease and diabetes. In particular I am interested in how alterations in kidney development may play a crucial role in disease development.
Study Of The Functional Consequences Of Angiotensin II Induced Increases In Renal Innervation
Funder
National Health and Medical Research Council
Funding Amount
$393,750.00
Summary
Hypertension (high blood pressure) is a major public health problem in Australia, being a key risk factor for cardiovascular diseases such as heart attack and stroke. More ominously, recent WHO reports show that cardiovascular disease is the major health burden facing developing countries, particularly in our region. Although some of the burden of cardiovascular diseases may be reduced by effective public health measures (e.g., to reduce saturated fat intake), hypertension remains largely imperv ....Hypertension (high blood pressure) is a major public health problem in Australia, being a key risk factor for cardiovascular diseases such as heart attack and stroke. More ominously, recent WHO reports show that cardiovascular disease is the major health burden facing developing countries, particularly in our region. Although some of the burden of cardiovascular diseases may be reduced by effective public health measures (e.g., to reduce saturated fat intake), hypertension remains largely impervious to preventative public health measures. While treatment of established high blood pressure can reduce the incidence of cardiovascular disease, preventing the development of hypertension in the first place is not possible at this time. A major impediment to the development of effective public health measure is our lack of knowledge of the pathological mechanisms involved, despite over 100 years of active research effort. The experiments planned in this study will probe below the surface of two important facts known about hypertension but not previously brought together - that the kidney's blood vessels and nerves are remodeled in hypertension, and that the kidney's control of the level of blood pressure must be changed in order for high blood pressure to develop in the first place. We hope that pursuit of this experimental line of enquiry will provide new clues on where to look for initiating factors in human hypertension.Read moreRead less
Identification Of Heterogeneity In Vasodilator Function In Human And Rat Resistance Vessels: Potential Drug Targets?
Funder
National Health and Medical Research Council
Funding Amount
$595,330.00
Summary
The balance between the ways that blood vessels decrease in size (constrict) and increase in size (dilate) determine how blood vessels normally function. There are many differences in the ways that blood vessels control this balance in different parts of the body. Such differences are altered in vascular diseases, such as hypertension and diabetes, which are prevalent in obesity, such that constriction generally outweighs dilation. However, what these differences are and how they occur are not w ....The balance between the ways that blood vessels decrease in size (constrict) and increase in size (dilate) determine how blood vessels normally function. There are many differences in the ways that blood vessels control this balance in different parts of the body. Such differences are altered in vascular diseases, such as hypertension and diabetes, which are prevalent in obesity, such that constriction generally outweighs dilation. However, what these differences are and how they occur are not well understood. While current drugs for treating vascular disease either reduce vessel constriction or increase dilation, they are not specific for individual arteries; a situation that would allow us to control vascular diseases in a very specific manner. Recently, we have described differences between the ways that individual vessels are controlled. These changes relate to differences in the way that different vessels dilate. AIMS - To further understand normal blood vessel function and the changes that occur in blood vessels in cardiovascular disease, with a focus on the ways that blood vessels dilate in normal states and in obesity-related diseases, such as in hypertension and diabetes. - The eventual aim is to identify the specific ways that arteries function, so that artery-specific drug targets can be identified to treat disease-related changes in cardiovascular disease in a very specific manner. EXPECTED OUTCOMES This project will contribute to understanding blood vessel function in health and disease. The expected eventual outcome is the identification of the mechanisms that underlie the function of different arteries in different parts of the body, so that specific individual vessel function can be targeted to treat vascular disease. Additionally, this work will also verify the relevance of the diet-induced obesity animal model, in terms of the characteristics and causes of human obesity and related cardiovascular disease.Read moreRead less
A lack of oxygen in the kidney (hypoxia) is a primary cause of kidney disease, but the mechanisms are not clear. To determine the processes involved, we will take a new approach; combining a mathematical model with studies of kidney oxygen regulation in both normal and diseased kidneys. We will determine the causes of hypoxia in kidney disease, and find out if preventing hypoxia has the potential to be a treatment for kidney disease.
Sympathetic Nervous System Contribution To Hypertension : CNS Pathways, Neurotransmitters And Neuroeffector Mechanisms
Funder
National Health and Medical Research Council
Funding Amount
$450,750.00
Summary
High blood pressure (hypertension) is a major public health problem in Western society with approximately 20% of adults affected. If left untreated, serious damage to organs can occur and the risk of sudden cardiac death or stroke is greatly increased. While many factors contribute to the development of hypertension such as lifestyle, genes, diet, weight and exercise levels, a common feature in the early stages is an overactive nervous system in the kidney and in the heart which is most likely d ....High blood pressure (hypertension) is a major public health problem in Western society with approximately 20% of adults affected. If left untreated, serious damage to organs can occur and the risk of sudden cardiac death or stroke is greatly increased. While many factors contribute to the development of hypertension such as lifestyle, genes, diet, weight and exercise levels, a common feature in the early stages is an overactive nervous system in the kidney and in the heart which is most likely due to altered signals from the brain. We need to understand why this occurs. One possibility is that renin (a chemical released from the kidney) that is known to control body fluid, also acts in the brain to increase nerve activity to the kidney and heart and in this way contributes to high blood pressure. It does this indirectly by producing another hormone called angiotensin. Our research has shown that in conditions where the kidney releases excess of the hormone renin, which may occur if the blood supply to the kidney is reduced, a change occurs in the way in which the nervous system affects blood pressure. The nervous system is activated to increase the release of renin from the kidney. The effect of this is to make blood pressure increase further in what can become a vicious circle. At present it is not understood why and how this change occurrs. The major thrust of this project is to determine the mechanims by which the renal hormones signal the central nervous system to change the nature of the nervous activity back to the kidney. We want to know what parts of the brain are involved, how the nature of the activity in the nerves changes and also how the nervous control of the kidney changes (i.e. how the kidney changes its responsivness to the nerve activity). Because similar processes probably occur in nearly all forms of high blood pressure, our results will greatly improve our understanding of how this dangerous condition develops.Read moreRead less