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
Pain associated with bone cancer, fractures, osteoporosis, osteoarthritis, osteomyelitis (and other bone infections) often presents the clinician with a difficult problem of treatment as the pain can be debilitating and intractable. Most current treatments for bone pain are based on the assumption that the neural mechanisms underlying pain from different sources, whether it be visceral, cutaneous, muscular or bony, are the same, and can therefore be targeted with similar therapies. However, litt ....Pain associated with bone cancer, fractures, osteoporosis, osteoarthritis, osteomyelitis (and other bone infections) often presents the clinician with a difficult problem of treatment as the pain can be debilitating and intractable. Most current treatments for bone pain are based on the assumption that the neural mechanisms underlying pain from different sources, whether it be visceral, cutaneous, muscular or bony, are the same, and can therefore be targeted with similar therapies. However, little is known of the response properties, structure and organization of receptors and neurones responding to, and relaying information about painful stimuli, from bone to the brain. The objectives of this project are to reveal the fundamental neural mechanisms that account for the perception of bone pain. The project will test a series of specific hypotheses in order to explain why bone pain is often poorly controlled by standard pharmacological or surgical approaches. It is expected that this study will reveal the neural mechanisms responsible for relaying sensory information, in particular, that regarding painful stimuli, from bone to the brain. It will lead to a better understanding of the mechanisms of bone pain and form the template for future studies of its treatment.Read moreRead less
Unified framework of intestinal motility. The project aims to establish how a few fundamental mechanisms determine the large repertoire of intestinal motor patterns responsible for moving nutrients along the digestive tract. The project will combine experimental and theoretical data, with biomechanical and electrophysiological models to create a new understanding of this essential function of the body.