Innovative And Multi-disciplinary Treatment Strategies For Secondary Degeneration Following Neurotrauma
Funder
National Health and Medical Research Council
Funding Amount
$455,452.00
Summary
Following injury to the central nervous system the damage spreads into nearby areas, leading to worse outcomes for the patient. The research conducted during this Fellowship will ensure that promising treatment strategies to prevent spreading damage are used in the best way, and will determine the mechanism of action of these treatments.
Cutting Through Complexity: The Promise Of Biomarkers To Discover, Diagnose, And Treat Antibody-associated Demyelination
Funder
National Health and Medical Research Council
Funding Amount
$438,768.00
Summary
Patients with damage to myelin, the sheath around nerve cells in the brain, have “demyelinating disorders” which can result in severe disability including blindness and paralysis. In some patients, their immune system mistakenly targets certain proteins in the brain. This research project will identify new targets in currently undiagnosed patients, increase our understanding of underlying disease processes, and evaluate optimal treatment strategies in these patients to improve their outcomes.
Investigating Mechanisms Of Axonal Pathology Following Oligodendrocyte Apoptosis: Avenues For Neuroprotection In Early MS
Funder
National Health and Medical Research Council
Funding Amount
$678,138.00
Summary
Recent research suggests that Multiple Sclerosis could first be triggered by the death of a type of brain cell called an oligodendrocyte. These cells insulate nerve cells in the brain which help them function normally. We will test the idea that death of oligodendrocytes impairs nerve cell function by causing inflammation and by depriving nerve cells of energy. We will determine whether preventing inflammation and feeding the nerve cells an alternative source of energy can restore normal functio ....Recent research suggests that Multiple Sclerosis could first be triggered by the death of a type of brain cell called an oligodendrocyte. These cells insulate nerve cells in the brain which help them function normally. We will test the idea that death of oligodendrocytes impairs nerve cell function by causing inflammation and by depriving nerve cells of energy. We will determine whether preventing inflammation and feeding the nerve cells an alternative source of energy can restore normal function.Read moreRead less
Using Non-invasive Magnetic Stimulation To Promote Remyelination
Funder
National Health and Medical Research Council
Funding Amount
$664,869.00
Summary
In patients with multiple sclerosis, brain insulation is lost from nerves. This leads to permanent and progressive disability. We have identified a non-invasive method of magnetic stimulation, and have shown that it increases the number of new insulating cells added to the brain. In this study we will determine whether this new treatment can promote insulation repair in a model of multiple sclerosis.
Defining The Basis Of Autoimmune Attacks Against Myelin To Better Target Treatment Of Demyelinating Disorders
Funder
National Health and Medical Research Council
Funding Amount
$913,216.00
Summary
Brain autoimmunity is a common and costly cause of neurological and psychiatric disability in children and adults. Exploring the autoimmune response that targets the brain is essential for accurate diagnosis, prognosis, and treatment. This project grant will identify and study the earliest autoimmune responses against the brain in children and adults. This will allow early and directed treatments that will not only prevent disability, but will also be life-saving.
Novel Strategies To Promote Myelin Repair In The Brain
Funder
National Health and Medical Research Council
Funding Amount
$597,865.00
Summary
Demyelinating diseases of the central nervous system such as multiple sclerosis have a lifelong impact and devastating impact on quality of life. We have identified that a growth factor, brain derived neurotrophic factor (BDNF), plays an important role in promoting myelination during development. We will investigate the potential of translating these findings into effective clinical treatment, by characterising the efficacy of BDNF in promoting CNS remyelination after a demyelinating insult.
Cellular and Neurochemical Basis of Drug Addiction. Addiction to the major drugs of abuse, including heroin, amphetamines, cocaine, nicotine and alcohol damage the lives and cause premature death of more than 20% of Australians. Addiction produces long-term disruption of brain processes that lead to loss of control over urges to consume drugs and persistent cycles of relapse to drug taking. This research will apply new neurochemical approaches to discover mechanisms of disrupted brain function t ....Cellular and Neurochemical Basis of Drug Addiction. Addiction to the major drugs of abuse, including heroin, amphetamines, cocaine, nicotine and alcohol damage the lives and cause premature death of more than 20% of Australians. Addiction produces long-term disruption of brain processes that lead to loss of control over urges to consume drugs and persistent cycles of relapse to drug taking. This research will apply new neurochemical approaches to discover mechanisms of disrupted brain function that occur during development of addiction and relapse that are critical for development of better strategies to treat the disorder. Read moreRead less
Characterisation of monoaminergic transmission in Central Amygdala. This project will identify the distribution and function of dopamine, serotonin and noradrenalin receptors on the various cell types and their inputs, in the medial, lateral and capsular divisions of Central Amygdala (CeA). We will test for tonic endogenous activation of monoaminergic receptors and synaptic release from electrically stimulated fibers terminating in CeA. Using paired recordings and calcium imaging, we will invest ....Characterisation of monoaminergic transmission in Central Amygdala. This project will identify the distribution and function of dopamine, serotonin and noradrenalin receptors on the various cell types and their inputs, in the medial, lateral and capsular divisions of Central Amygdala (CeA). We will test for tonic endogenous activation of monoaminergic receptors and synaptic release from electrically stimulated fibers terminating in CeA. Using paired recordings and calcium imaging, we will investigate intracellular mechanisms underlying monoamine receptor mediated effects. These findings when correlated with published behavioural studies will provide greater understanding of the role of the divisions of CeA and the inputs they receive, in the function of the amygdala.Read moreRead less
Investigating the mechanisms of flavonoid actions on glycine receptors. The research to be conducted in this project will use state-of-the-art electrophysiological and molecular biological approaches to carefully characterise the actions of certain flavonoid compounds on the glycine-receptor channel. These compounds have recently been reported to act as modulators of ligand-gated ion channels, proteins integral to brain function and disease. However, no-one has studied in any detail the mechan ....Investigating the mechanisms of flavonoid actions on glycine receptors. The research to be conducted in this project will use state-of-the-art electrophysiological and molecular biological approaches to carefully characterise the actions of certain flavonoid compounds on the glycine-receptor channel. These compounds have recently been reported to act as modulators of ligand-gated ion channels, proteins integral to brain function and disease. However, no-one has studied in any detail the mechanisms by which these compounds act. By discovering their site and mechanisms of action we will further our understanding of these important proteins and their modulation, maintain Australia's significant expertise in this field and provide leads for future development of drugs with potential therapeutic value.Read moreRead less
Activation mechanisms of Cys-loop ion channel receptors. This proposal will employ a cutting edge approach to reveal fundamental new insights into the ways that proteins work. The information and technology developed here will broaden and strengthen Australia's research expertise across a number of basic scientific disciplines. The results will also have relevance to human health. Cys-loop ligand-gated receptors have an essential role in brain function and are targets for many therapies and drug ....Activation mechanisms of Cys-loop ion channel receptors. This proposal will employ a cutting edge approach to reveal fundamental new insights into the ways that proteins work. The information and technology developed here will broaden and strengthen Australia's research expertise across a number of basic scientific disciplines. The results will also have relevance to human health. Cys-loop ligand-gated receptors have an essential role in brain function and are targets for many therapies and drugs of abuse. New insights into how biological ligands and drugs affect ion channel structure and function may lead to novel therapeutic opportunities and improved drug structure predictions.Read moreRead less