Central Nervous Pathways For The Sympathetic Control Of Immune Function
Funder
National Health and Medical Research Council
Funding Amount
$300,741.00
Summary
The nervous system regulates immune system function by a special set of nerves that are part of the sympathetic nervous system. This project aims to work out which brain pathways control them.
Effects Of Ischemia/ Reperfusion Injury On Enteric Neurons And Neuroprotective Strategies
Funder
National Health and Medical Research Council
Funding Amount
$566,277.00
Summary
The intestine can suffer restricted blood flow, creating a region of damaged or dead bowel. This leads to severe medical emergencies, complications and even death. Loss of blood flow and damage can be a serious complication for intestinal transplant surgery, which compromises patient survival and recovery. The project brings together transplant surgeons and basic scientists to solve problems caused by intestinal ischemia. A major result will be to improve outcomes for Australian patients
Control Of Sympathetic Nerves That Talk To The Immune System
Funder
National Health and Medical Research Council
Funding Amount
$385,958.00
Summary
The two complex systems of the body, the immune system and the nervous system, communicate with each other. This proposal studies one of the major pathways from brain to immune system - sympathetic immuno-efferent nerves. In stroke, these pathways cause profound immunosuppression, causing susceptibility to infection. Their poorly understood central and peripheral pathways will be defined and mapped by this study.
Neural Circuits Producing Pelvic Vasodilation In Females
Funder
National Health and Medical Research Council
Funding Amount
$472,770.00
Summary
The reproductive organs and genitalia in males and females experience a large increase in blood flow during sexual and reproductive activity. This increased blood flow (vasodilation) is a key component of penile and clitoral erection, and enhances secretion from the lining of the internal reproductive organs. Vasodilation during sexual activity is produced by a special sets of nerves receiving signals from the genitalia and the brain. In fact, Viagra works by enhancing and prolonging the actions ....The reproductive organs and genitalia in males and females experience a large increase in blood flow during sexual and reproductive activity. This increased blood flow (vasodilation) is a key component of penile and clitoral erection, and enhances secretion from the lining of the internal reproductive organs. Vasodilation during sexual activity is produced by a special sets of nerves receiving signals from the genitalia and the brain. In fact, Viagra works by enhancing and prolonging the actions of these nerves. An important part of this neural pathway is a group of nerve cells in the spinal cord that connects the central nervous system with peripheral nerves in the reproductive organs - these are called preganglionic neurons. Recently we discovered that a major pathway from the spinal cord to the pelvic blood vessels in females leaves the spinal cord at a different level (lumbar) from that thought previously (sacral level). Currently there is no information on how these lumbar preganglionic nerves in females are connected to other nerve pathways that are active during sexual activity, and how they integrate signals from both the internal organs and the brain. We will use an array of modern cellular techniques together with direct observation of dilation in isolated uterine arteries to discover how these nerve cells are wired up in circuits in the spinal cord. This information is vital for us to understand the factors producing increased blood flow in normal sexual activity, and how these might be altered in inflammation or in conditions where there could be selective damage to one nerve pathway and not the other, such as after pelvic surgery, spinal cord damage at different levels, or stimulation of the spinal cord for treatment of chronic pain. Our study also will help understand referred pain and sensations of discomfort in abdominal and pelvic organs.Read moreRead less
This project aims to discover the nervous pathways and mechanisms in the brain that control body temperature. We hope to identify the nerve cells in the brain that detect increases in the core temperature of the body and determine the nervous pathways that project from them to increase blood flow to the skin when we become hot. This research may lead to a better understanding of heat exhaustion which is especially dangerous to the elderly.
FUNCTIONAL IDENTIFICATION OF CORTICAL AND SUBCORTICAL SITES RESPONSIBLE FOR NEUROGENIC HYPERTENSION IN HUMANS
Funder
National Health and Medical Research Council
Funding Amount
$514,644.00
Summary
Blood pressure is normally maintained at a relatively constant level through reflexes involving the brainstem, but we have recently shown that higher areas of the brain are also involved in the regulation of blood pressure in humans. Here, we will use the novel methodologies we have developed to study functional and structural changes in the brain in patients with essential and renovascular hypertension.
BRAIN IMAGING OF CARDIOVASCULAR CONTROL DURING MUSCLE PAIN
Funder
National Health and Medical Research Council
Funding Amount
$370,983.00
Summary
One in every five people in Australia suffers chronic pain and a third of these have severe pain associated with severe disability. The incapacitating effects of long-lasting pain are not just psychological, but affect many systems, including the cardiovascular system. We are interested in why pain causes blood pressure to increase in some people but not in others: patients with post-surgical chronic pain have nearly twice the prevalence of clinical hypertension than patients without pain.
Role Of The Medial Amygdala In Developing Neurogenic Hypertension
Funder
National Health and Medical Research Council
Funding Amount
$302,123.00
Summary
We aim to investigate the underlying mechanisms and pathways that regulate the activity of neurons located in the medial amgydala during stress that contribute long term to the development of hypertension. This study is highly relevant to people who inappropriately respond to typical daily stressors and we aim to provide direction for developing specific therapies to interrupt the adverse cardiovascular consequences of chronic stress.
FUNCTIONAL IMAGING OF THE BRAINSTEM AND CORTICAL SITES OF BLOOD PRESSURE CONTROL IN HUMAN SUBJECTS IN HEALTH AND DISEASE
Funder
National Health and Medical Research Council
Funding Amount
$398,498.00
Summary
Disturbances in cardiovascular control underpin many diseases yet little is known about how the brain controls the heart and blood vessels. This project uses brain imaging (fMRI) and concurrent nerve recording in awake human subjects to increase our understanding of how normal blood pressure is maintained and how different disease states influence this control.