The Role Of SPARC In Regeneration And Neurogenesis In The Central Nervous System.
Funder
National Health and Medical Research Council
Funding Amount
$324,870.00
Summary
Stroke is a leading cause of disability in the elderly. Although the brain has built-in mechanisms for repairing itself, these processes are slow and incomplete. We are investigating how these natural repair mechanisms work and how to stimulate them to improve recovery. Our initial results suggest that a protein called SPARC, which is involved in wound healing outside the nervous system, may be able to recruit new nerve cells and blood vessels to damaged brain tissue.
Blood-Spinal Cord Barrier Structure And Function In Syringomyelia
Funder
National Health and Medical Research Council
Funding Amount
$82,630.00
Summary
Syringomyelia is a disorder in which a fluid-filled cyst forms within the spinal cord. These cysts expand over time resulting in paralysis or even death. Syringomyelia occurs in association with spinal cord injury and a number of congenital conditions. In this project we aim to investigate the underlying cause of cyst formation, which is currently unknown. It is hoped that these studies will improve our understanding of cyst formation and facilitate development of better treatment strategies.
Inhibition Of Fear Memories By Extinction: Neural Substrates.
Funder
National Health and Medical Research Council
Funding Amount
$234,250.00
Summary
Anxiety disorders [e.g., Post Traumatic Stress Disorder (PTSD)] are the most prevalent type of psychopathology in the industrialised world. They are associated with characteristic behavioural (e.g., heightened startle) and autonomic (e.g., cardiovascular) reactions. These disorders are often characterised as an inability to regulate the emotion of fear. Significant progress has been made in understanding the neural and cellular processes involved in the establishment of fear memories, but relati ....Anxiety disorders [e.g., Post Traumatic Stress Disorder (PTSD)] are the most prevalent type of psychopathology in the industrialised world. They are associated with characteristic behavioural (e.g., heightened startle) and autonomic (e.g., cardiovascular) reactions. These disorders are often characterised as an inability to regulate the emotion of fear. Significant progress has been made in understanding the neural and cellular processes involved in the establishment of fear memories, but relatively little is known about the mechanisms by which fear memories can be inhibited or suppressed. Understanding this latter process is a key to the development of effective treatments for anxiety disorders such as PTSD where the patient suffers from persistent, intrusive, unwanted trauma memories. A common experimental procedure for reducing learned fear is to repeatedly expose the subject to a fear-eliciting stimulus but without any aversive outcome. This procedure leads to a progressive loss, or extinction, of the fear reactions elicited by the stimulus. Historically, the extinction of fear was thought to be due to an erasure of the fear memory. However, recent evidence shows that extinction inhibits, rather than erases, the fear memory. Because the fear memories remain intact, some structure(s) in the brain must inhibit activity in the fear pathway. This project uses extinction of conditioned fear reactions in rat subjects to determine the structure(s) in the brain that inhibit fear memories and their behavioural and cardiovascular expression. It brings together the expertise of four well-established researchers and uses a combination of behavioural, physiological, immunohistochemical, tract tracing, and lesion approaches to achieve this aim. The proposed experiments will reveal the structure(s) in the brain that control the inhibition of fear, as well as the site(s) of this inhibition in the fear pathwayRead moreRead less
PURINERGIC TRANSMISSION AND CENTRAL AUTONOMIC REGULATION
Funder
National Health and Medical Research Council
Funding Amount
$157,848.00
Summary
The brain regulates bodily functions in a complex manner. One such example is the regulation of blood pressure and heart rate. This is achieved by an interconnected network of brain nuclei that sense information from the major blood vessels and integrate appropriate responses to maintain the status quo. Chemicals called neurotransmitters convey the nervous messages, and one such example is purines, which include ATP and adenosine. Both ATP and adenosine can act in a number of brain regions to mo ....The brain regulates bodily functions in a complex manner. One such example is the regulation of blood pressure and heart rate. This is achieved by an interconnected network of brain nuclei that sense information from the major blood vessels and integrate appropriate responses to maintain the status quo. Chemicals called neurotransmitters convey the nervous messages, and one such example is purines, which include ATP and adenosine. Both ATP and adenosine can act in a number of brain regions to modulate blood pressure and heart rate. This project is designed to characterise the mechanism by which purines act within specific brain nuclei to regulate the cardiovascular system. Considering the large economic burden on the healthcare system caused by cardiovascular disease, this research is vital to increase our understanding of how diseases such as hypertension may be caused, and therefore provide improved therapeutic strategies.Read moreRead less
Experience-dependent Maturation And Plasticity Of The Cerebral Cortex Mediating Schizophrenia-like Endophenotypes
Funder
National Health and Medical Research Council
Funding Amount
$384,199.00
Summary
We will use genetic mouse models of schizophrenia to understand how specific abnormal behaviours are caused, focusing on cells and molecules within the brain. We will investigate how the gene mutations disrupts communication between, and production of, brain cells (neurons), and the role of mental and physical activity. The results of this project will not only have implications for understanding schizophrenia, but also for other brain disorders involving cognitive problems, such as dementia.
Brain Angiotensin: Generation, Localisation And Physiological Function
Funder
National Health and Medical Research Council
Funding Amount
$209,250.00
Summary
The renin angiotensin system is one of the major homonal systems of the body that regulate the cardiovascular system and bodily salt and water balance. Drugs that inhibit the function of this system by reducing the blood level of the hormone angiotensin II or blocking the receptors at which it acts are in the forefront of treatment of high blood pressure and heart failure. It has been proposed that a separate brain renin angiotensin system exists that is not influenced by angiotensin II in the b ....The renin angiotensin system is one of the major homonal systems of the body that regulate the cardiovascular system and bodily salt and water balance. Drugs that inhibit the function of this system by reducing the blood level of the hormone angiotensin II or blocking the receptors at which it acts are in the forefront of treatment of high blood pressure and heart failure. It has been proposed that a separate brain renin angiotensin system exists that is not influenced by angiotensin II in the blood stream because of the blood-brain barrier. Strains of mice in which the genes that code for two components of this system - angiotensin converting enzyme (the enzyme responsible for generating angiotensin II) and angiotensinogen (the protein which gives rise to angiotensin II) provide excellent tools to elucidate this system in the brain. By studying these mice we will be able to determine whether angiotensin converting enzyme is necessary in the brain for foreming angiotensin II, and we will be able to determine the sites in the brain where authentic angiotensin peptides exist. We will also determine whether angiotensin II transmits information between neurons in the brain that play a role in control of the cardiovascular system and body fluid balance.Read moreRead less
Functional Mapping Of Autonomic Control Circuits In The Human Brain
Funder
National Health and Medical Research Council
Funding Amount
$291,451.00
Summary
Nerves called sympathetic nerves stimulate the heart and raise blood pressure. The brain drives them when we are excited or frightened. It also over-drives them in cardiovascular diseases, and this makes matters worse. This project will use MRI brain scanning to investigate, for the first time, how the cerebral cortex and brain stem act together to control sympathetic nerves. Understanding how this system works normally will help tell us how it may malfunction, and what we can do to correct it.
Forebrain Control Of Cardiovascular Function: Integrative And Cellular Mechanisms
Funder
National Health and Medical Research Council
Funding Amount
$834,233.00
Summary
Blood pressure is controlled to a large extent by nerves, known as sympathetic nerves, that supply the heart and blood vessels. Measurements in humans have shown that the activity of sympathetic nerves is increased in a number of cardiovascular diseases, including heart failure and in many cases of high blood pressure. This has the effect of constricting blood vessels and increasing heart rate, which places an additional load on the heart which can cause damage to the heart. It is not known what ....Blood pressure is controlled to a large extent by nerves, known as sympathetic nerves, that supply the heart and blood vessels. Measurements in humans have shown that the activity of sympathetic nerves is increased in a number of cardiovascular diseases, including heart failure and in many cases of high blood pressure. This has the effect of constricting blood vessels and increasing heart rate, which places an additional load on the heart which can cause damage to the heart. It is not known what causes this increased sympathetic activity, but one possibility is that it is due to the action of a circulating hormone called angiotensin, which acts on the brain, activating central nerve pathways which ultimately increase sympathetic activity. In this project we aim to test this hypothesis and thus help to unravel the mechanisms involved in the long term control of sympathetic activity and blood pressure.Read moreRead less