Forebrain Neuroadaptations To Chronic Morphine Treatment
Funder
National Health and Medical Research Council
Funding Amount
$435,956.00
Summary
Drug addiction is caused by long term changes in brain areas that normally produce the drives that sustain normal behaviours such as eating, drinking and sex. Addictive drugs effectively hijack these brain areas so that behaviours relating to drug taking become associated with feeling good. In some individuals, over time the pattern of drug taking becomes compulsive and no longer can be controlled. This transition is now known to be due to drugs causing physical changes to certain groups of nerv ....Drug addiction is caused by long term changes in brain areas that normally produce the drives that sustain normal behaviours such as eating, drinking and sex. Addictive drugs effectively hijack these brain areas so that behaviours relating to drug taking become associated with feeling good. In some individuals, over time the pattern of drug taking becomes compulsive and no longer can be controlled. This transition is now known to be due to drugs causing physical changes to certain groups of nerve cells in the brain. The affected nerve cells are responsible for causing new behaviours that appear once addiction is established. Addiction is not exclusive to humans. Animals will self-inject the same addictive drugs that humans use, and show many other kinds of addictive behaviours that parallel aspects of human addiction. Studying the effects of addictive drugs on rats and other animals has been very important in working out where and how drugs work. We now have a very good idea of which parts of the brain are affected by drugs, and it turns out that most addictive drugs act in the same places. We also now know for all of the major drugs, exactly which parts of nerve cells they affect. However, this turns out to be only the first step as the nerve cells that directly respond to drugs can affect other whole networks of nerve cells. This study is going to look at how morphine, a drug that is related to heroin, affects nerve cells in a part of the brain that helps cause addiction. It is going to work out which of the many pathways in this brain region are affected by morphine treatments that cause addiction in rats. It will then see what is happening to single nerve cells in the affected pathways. If we can understand more about these processes it may become possible to come up with new ways to treat addiction. We will also understand much more about the production of powerful emotional and behavioural drives so many of us find hard to control.Read moreRead less
Mechanisms Of Central Nervous System Disease Induced By Dysregulated Interferon Signalling
Funder
National Health and Medical Research Council
Funding Amount
$618,165.00
Summary
Interferons are proteins that on one hand have been found to protect cells against infectious agents such as viruses but on the other can cause injury and disease in the brain. In this project the way in which interferons affect the brain to bring about these outcomes will be studied. The results of this work will advance our understanding of how interferons function and may lead to better approaches for combating immune and infectious diseases of the nervous system.
We will use genetically engineered mice to study brain circuitry in an effort to understand the anatomical basis of Huntington's disease and a number of other more common degenerative brain diseases similar to Parkinson's disease. We will look at the brain in detail to decipher how the injured brain repais itself by making new connections and by producing new cells. We will also study supporting cells in the brain to determine if they play a beneficial role in this injury repair process.
Role Of The Hypothalamus, Oxidative Stress And Angiotensin In Chronic Stress
Funder
National Health and Medical Research Council
Funding Amount
$535,333.00
Summary
Stress can trigger life threatening cardiovascular events and its impact is much greater when blood pressure is raised. We seek to determine which chemical type of brain neuron and which region is responsible for amplifying the responses to repeated stress in an animal model that closely resembles the human form of the disease. We will focus specifically on the hypothalamus which controls the sympathetic nervous system.
Elucidation Of The Transcriptional Control Of CNS Myelination And Remyelination
Funder
National Health and Medical Research Council
Funding Amount
$570,764.00
Summary
Oligodendrocytes are the cell type in the central nervous system that produce myelin, the insulating layer around nerve cells. Loss of oligodendrocytes and myelin are key features of multiple sclerosis. This project aims to characterize how a recently identified gene (Myelin Gene Regulatory Factor) functions to promote myelination and to assess the role of the gene in myelin maintenance and repair in the adult central nervous system.
Encephalitis is a common cause of neurological disability in young adults and adolescents. We have identified a subgroup of encephalitis which is due to the patient's own immune system attacking the brain. Our study will identify the earliest immune responses against the brain in children with encephalitis. Identifying these early immune responses in people with encephalitis will allow early and directed treatments to prevent disability and death in the future.
Lipocalin 2 In Host Defence Of The Central Nervous System
Funder
National Health and Medical Research Council
Funding Amount
$575,014.00
Summary
Lipocalin 2 is a protein that is involved in protection of the host organism against bacterial infections. We have found that high levels of lipocalin 2 are produced by a variety of cells in the brain in response to not only bacterial products but also to infection with West Nile virus (WNV). WNV is a dangerous virus known to cause lethal encephalitis. This project will determine the role of lipocalin 2 in the defence of the host against WNV encephalitis.
THE AUTONOMIC, SOMATIC AND CENTRAL NEURAL RESPONSES TO DEEP AND SUPERFICIAL PAIN IN HUMAN SUBJECTS
Funder
National Health and Medical Research Council
Funding Amount
$375,750.00
Summary
Pain is a subjective experience, the intensity of which can be readily influenced by personal experience. Despite this, pain originating from a particular part of the body will usually be described by all individuals as having similar character. For example, pain arising from the skin is commonly described as being sharp or burning and is usually easy to localise, whereas pain arising from muscle is commonly dull, throbbing and diffuse. In addition to producing sensory changes, pain also evokes ....Pain is a subjective experience, the intensity of which can be readily influenced by personal experience. Despite this, pain originating from a particular part of the body will usually be described by all individuals as having similar character. For example, pain arising from the skin is commonly described as being sharp or burning and is usually easy to localise, whereas pain arising from muscle is commonly dull, throbbing and diffuse. In addition to producing sensory changes, pain also evokes changes in blood pressure, heart rate and motor activity (often in an attempt to remove the source of the pain). The proposed research aims to characterise the cardiovascular and motor patterns associated with pain originating in skin and in muscle and to examine the brain regions that produce these changes. More specifically, microelectrodes will be used to investigate changes in peripheral nerve activity during transient painful skin and muscle events in awake human subjects. In a separate investigation functional magnetic resonance imaging will be used to determine brain sites that are activated by skin or muscle pain.Read moreRead less
Anatomical Substrates For Primate Executive Cortical Function
Funder
National Health and Medical Research Council
Funding Amount
$362,820.00
Summary
When studying the brain, many have been tempted to look for similarities in organization of cells and circuitry in different regions involved in various processes. While, at a first approximation, this may be a reasonable approach to understand how the brain works, it also ignores what makes the brain so complex: the diversity in its structure. In the late 19th, and early 20th, centuries, pioneering anatomists seized on the diversity in structure of the human brain. The study of cortical circuit ....When studying the brain, many have been tempted to look for similarities in organization of cells and circuitry in different regions involved in various processes. While, at a first approximation, this may be a reasonable approach to understand how the brain works, it also ignores what makes the brain so complex: the diversity in its structure. In the late 19th, and early 20th, centuries, pioneering anatomists seized on the diversity in structure of the human brain. The study of cortical circuitry that underlies the diversity in cortical processing reached a zenith and there was a renaissance in understanding of brain function. These researchers were, however, limited by techniques available to them at the time. With the advent of new methodologies which allowed scientists to explore individual connections between cells (synapses), to probe structure and transmission across synapses, and to record from live neurones, new and exciting discoveries were made. However, these methodologies are highly time consuming and studies became necessarily more focussed. As a result, there was a tendency in the later half of the 20th century to extrapolate findings from one cortical area to cortex in general. Even more precarious, anatomical and functional findings in highly specialized sensory cortex of one species were projected to other distantly related species. Such thinking lead to a dark age in neuroscience. It became widely accepted that there exists a canonical circuit. Consequently, differences in function between different cortical areas were attributed solely to the source of their projections. The central thesis of this project is to study aspects of cell structure and cortical circuitry in the prefrontal lobe. We hope that the project will provide another step in the pathway that leads to understanding the mind.Read moreRead less
Nerve pathways exist that carry information from the highest parts of the brain to the peripheral hearing organ, the inner ear. These descending control pathways have the potential to affect the hearing process in a number of ways; protecting from loud sounds, improving the detection of signals in noisy backgrounds, selecting stimuli of interest and regulating a variety of aspects of inner ear function. Abnormal function of these pathways can affect hearing sensitivity and may be important in ph ....Nerve pathways exist that carry information from the highest parts of the brain to the peripheral hearing organ, the inner ear. These descending control pathways have the potential to affect the hearing process in a number of ways; protecting from loud sounds, improving the detection of signals in noisy backgrounds, selecting stimuli of interest and regulating a variety of aspects of inner ear function. Abnormal function of these pathways can affect hearing sensitivity and may be important in phenomena such as tinnitus and other disorders of hearing. This project will investigate the subtle effects that selective activation of these pathways has on inner ear function and will attempt to unravel the different influences that subcomponents of the pathways have on the different aspects of hearing.Read moreRead less