Understanding The Origins Of Neurogenic Hypertension
Funder
National Health and Medical Research Council
Funding Amount
$668,914.00
Summary
Brain cells that control the cardiovascular system are thought to have stopped dividing by adulthood. We recently discovered that this is not the case. Our initial findings suggest that these nascent cells might be important for maintaining normal blood pressure. This work will allow us to elucidate the function of these nascent cells and how they integrate into the circuit that controls the cardiovascular system. Our findings will be fundamental for understanding diseases such as hypertension.
The Brain As A Therapeutic Target For Heart Failure
Funder
National Health and Medical Research Council
Funding Amount
$923,432.00
Summary
In heart failure there is a large increase in sympathetic nerve activity to the heart that leads to damage to the heart and sudden death. We have shown that lesion of the area postrema, a brain nucleus that senses hormones in the blood, reduces nerve activity to the heart and, importantly, improves cardiac function. We aim to translate these findings into a treatment that can be used clinically, which our findings compellingly indicate should improve cardiac function in heart failure
Targeting The Sympathetic Nervous System To Reduce The Burden Of Fatty Liver Disease
Funder
National Health and Medical Research Council
Funding Amount
$728,152.00
Summary
The metabolic syndrome is characterised by abdominal obesity, high blood pressure and an increased risk of diabetes development. It is clear from our own observations that the sympathetic nervous system (SNS) is important in the generation of obesity-related illness and, through its stimulation of the liver, plays an important role in the development of obesity-related liver disease. We will target the SNS in order to reduce the burden of obesity-related liver disease.
IDENTIFICATION OF BRAIN NEURONS INVOLVED IN THE CARDIOVASCULAR RESPONSE TO FEAR AND FLIGHT
Funder
National Health and Medical Research Council
Funding Amount
$400,247.00
Summary
The circulatory system of the body acts in concert with the respiratory system to distribute oxygenated blood to the brain and other organs and tissues of the body. Control of blood pressure and heart rate is achieved largely through the actions of the central nervous system on effector organs and tissues such as the heart and blood vessels. This control is exerted through the actions of nerves in the body which affect the rate and force of contraction of the heart and the diameter of blood vess ....The circulatory system of the body acts in concert with the respiratory system to distribute oxygenated blood to the brain and other organs and tissues of the body. Control of blood pressure and heart rate is achieved largely through the actions of the central nervous system on effector organs and tissues such as the heart and blood vessels. This control is exerted through the actions of nerves in the body which affect the rate and force of contraction of the heart and the diameter of blood vessels which restrict the flow of blood to the tissues. These nerves, in turn, are under the control of brain cells or neurons which are located in the brainstem. Blood pressure-controlling neurons, acting upon information they receive from pressure sensors in the major blood vessels in the chest cavity, can alter their activity so that blood pressure is maintained within normal limits. Our laboratory has been examining the properties of these blood pressure-controlling neurons by recording their minute electrical discharges and by studying other brain regions which are able to influence them. In this study, we will use newly-developed procedures which will allow us to identify the precise locations of these neurons in the brain, to study which neurotransmitters (chemicals released by neurons which are used to communicate with other neurons) they use, as well as to identify other regions of the brain they connect with and influence. The major significance of this work will be that new brain circuits which transmit information about the status of the cardiovascular system to other areas of the brain will be identified. Our understanding of, and the development of new treatments for, cardiovascular diseases such as high blood pressure and heart failure are critically dependent on advancing our understanding of the nervous system.Read moreRead less