Cell Swelling And EEG Ripples: Components In The Transformation Of Normal Brain Activity Into Seizure
Funder
National Health and Medical Research Council
Funding Amount
$370,090.00
Summary
Epilepsy is a highly debilitating conditioned and seizures are often poorly controlled. Using a novel multidisciplinary approach, the aim of this proposal is to define the participation of cell swelling and nerve cell brain activity during the start and spread of seizures. This research introduces a novel seizure induction mechanism and provides a paradigm shift in focus for epilepsy research, as well as suggests new pharmacologic targets for seizure-intervention.
The Role Of LIM Domain Kinase 1 In The Pathogenesis Of Alzheimer’s Disease
Funder
National Health and Medical Research Council
Funding Amount
$565,531.00
Summary
Alzheimer’s disease is characterized by progressive loss of cognition. Few Australians have remained untouched by the effects of Alzheimer’s disease in their families or social circles. Unfortunately, there is no cure and current therapies are limited to modest symptomatic relief. This project will explore the role of a protein that regulates the structural integrity of brain cells in disease, and test if targeting this protein could prevent disease progression.
Glial Reactivity During The Post-acute Phase Of Stroke: A Target For Promoting Functional Recovery
Funder
National Health and Medical Research Council
Funding Amount
$547,307.00
Summary
Recent studies suggest that the development of a type of scar around damaged tissue in the brain following a stroke can limit recovery. Our studies will improve understanding of events leading to scar formation and will test whether modifying these events can improve functional recovery in experimental stroke. The studies have excellent potential to identify targets for treatments that will reduce the long-term debilitating effects of stroke even when administered well after its onset.
Astrocytic Contributions To Tissue Damage And Dysfunction In Stroke
Funder
National Health and Medical Research Council
Funding Amount
$275,810.00
Summary
Stroke is a primary cause of disability and death in adults. The symptoms of stroke arise from damage to brain tissue following disruptions to blood flow. At present, there are few options for treatments to limit the extent of tissue damage and the consequent disruption to function. Although, there have been considerable advances in understanding the cellular and molecular processes underlying the tissue damage, many issues are unresolved. A better understanding of these processes is likely to o ....Stroke is a primary cause of disability and death in adults. The symptoms of stroke arise from damage to brain tissue following disruptions to blood flow. At present, there are few options for treatments to limit the extent of tissue damage and the consequent disruption to function. Although, there have been considerable advances in understanding the cellular and molecular processes underlying the tissue damage, many issues are unresolved. A better understanding of these processes is likely to open up new avenues for ameliorating damage and improving outcomes for stroke patients. Astrocytes are one of the major populations of cells in the brain. They play key roles in supporting normal brain function and protecting nerve cells in the brain. Because of their many functions, these cells offer considerable potential as a therapeutic target in stroke. Unfortunately, the responses of astrocytes in this disorder are poorly understood due partly to a lack of techniques to distinguish their contributions from that of other cells in the brain. We have recently designed a novel system using antibodies to deliver genes into selected populations of nerve cells in the nervous system and thus to selectively alter the function of these cells. In the proposed study, we will adapt this technique to selectively modify gene expression in astrocytes. We will then apply the procedure to determine the consequences of altering key functions in astrocytes on the brain damage and behavioural changes that develop in an animal model of stroke. The successful completion of this research will provide a powerful means to investigate the function of astrocytes, not only in diseases such as stroke but also in normal brain. We will also gain novel insights into the astrocytic role in the damage and dysfunction resulting from stroke that have potential applications in developing new therapies.Read moreRead less
Properties And Functions Of Reactive Astrocytes And Their Role In Neurological Disease
Funder
National Health and Medical Research Council
Funding Amount
$344,652.00
Summary
I am a developmental neuroscientist interested in the way alterations to normal brain development affect neuronal function later in life. I intend to investigate this by studying astrocytes – the cells that support and nourish brain nerve cells. In some diseases these astrocytes become stressed and instead of aiding the brain, set about destroying it. A better understanding of their action during development and disease may enable improved interventions for the treatment of many brain disorders.
My research focuses on understanding pathobiological mechanisms in acute and chronic neurodegenerative conditions such as stroke and Parkinson’s disease which have large burdens on the community through health care costs and on families because of the lack of effective treatments. An improved understanding of how brain cells die and of how the most abundant brain cell, the astrocyte, can be engineered to be a resource for regenerative medicine offer promise for improved clinical management.