Our studies are aimed at examining how blood flow and pressure is controlled in the various tissues of the body. In particular, we hope to improve our understanding of how blood flow is matched to local metabolic requirements and how a constancy of conditions can be maintained despite changes in overall blood pressure. This ability to control local blood flow occurs through the ability of very small arteries to rapidly adjust their diameters through vasoconstriction or vasodilatation. The vessel ....Our studies are aimed at examining how blood flow and pressure is controlled in the various tissues of the body. In particular, we hope to improve our understanding of how blood flow is matched to local metabolic requirements and how a constancy of conditions can be maintained despite changes in overall blood pressure. This ability to control local blood flow occurs through the ability of very small arteries to rapidly adjust their diameters through vasoconstriction or vasodilatation. The vessels can thus act as valves regulating the transfer of blood flow and pressure to smaller vessels downstream. One particular response that small arteries exhibit is the ability to constrict when pressure within the vessels increases. The increase in pressure appears to stretch the vessel wall which in turn initiates a series of mechanical and biochemical steps that ultimately lead to contraction of muscle cells within the vessel wall. By contracting, the vessels limit the increase in downstream flow and pressure that would be expected to occur. The vessels being studied are very small, typically less than 100 micron. They are studied under isolated and controlled conditions using microscope and computer-based imaging techniques. While this allows us to directly monitor changes in vessel diameter to various stimuli (e.g. a change in pressure) we have also had to miniaturize biochemical measurements so we can understand the chemistry which underlies these vasoconstrictor responses. Understanding of how these local blood regulatory mechanisms occur is not only relevant to our understanding of the normal situation but is also vital to understanding disease states. For example, this work is very relevant to common cardiovascular disorders such as hypertension. It is hoped that a detailed understanding of the biochemical pathways by which small arteries contract will allow the design and targeting of pharmaceutical approaches for treatment of vascular disease states.Read moreRead less
I am an academic clinician who has a principal interest in all aspects of diabetes, especially treatment and complications, and who is also involved in studies of antimalarial pharmacology.
Conventional And Unconventional T Cells In Interstitial Kidney Disease
Funder
National Health and Medical Research Council
Funding Amount
$480,531.00
Summary
Acute damage to the kidney is a common life-threatening condition. Recent studies have shown that less well-studied types of immune cells contribute to kidney damage. However, how these cells enter and injure the kidney is unknown. In this project we will use a special microscope to look into the blood vessels of the kidney and visualise the cells inside kidney blood vessels in order to uncover their behaviour as they respond to acute inflammatory insult to the kidney.