A Novel Treatment For Ischemic Stroke: Preclinical Assessment In The Nonhuman Primate
Funder
National Health and Medical Research Council
Funding Amount
$762,246.00
Summary
A major source of repair inhibition after brain injury is debris from dying cells, which contains proteins that hinder repair. This project will examine the expression of these proteins in a clinically-relevant model of ischemic stroke and determine if blocking the effect of these proteins neutralises their repair-inhibiting properties. If successful, there is likelihood that this drug, and method of delivery, could be translated into the human for treatment following an ischemic stroke.
Intravascular Leukocyte Trafficking During Thromboinflammation
Funder
National Health and Medical Research Council
Funding Amount
$668,742.00
Summary
Unblocking blood vessels to treat heart attack and stroke can unfortunately cause a paradoxical worsening of organ damage, due to increased inflammation upon blood flow restoration. We have identified a novel way in which this side-effect is regulated by the small blood clotting cells platelets, and the protein fibrin. We will investigate ways to reduce the pro-inflammatory role for platelets, and define safer clot busting treatments.
Brain Repair Following Stroke: The Role Of Npas4, A Neural-specific Transcription Factor
Funder
National Health and Medical Research Council
Funding Amount
$611,053.00
Summary
Stroke is the #1 cause of adult disability in Australia and #2 cause of death. About 60,000 Australians suffer a stroke each year while about 250,000 live with the disabilities of stroke, costing over $2B/year. The Queen Elizabeth Hospital and University of Adelaide will study why the Npas4 gene switches on after stroke and the role it plays in brain repair. Future health benefits may be tests to help improve stroke outcome in patients and therapy to decrease loss of brain cells after stroke.
Aurora Kinase: Molecular, Cellular And Functional Studies Deciphering Its Role In Stroke Injury
Funder
National Health and Medical Research Council
Funding Amount
$580,993.00
Summary
In stroke patients, oxygen deprivation indirectly induces massive nerve cell death by activating an enzyme called aurora kinase A (AURKA). We aim at unravelling (i) how AURKA is activated by oxygen deprivation, (ii) where the activated AURKA is localised in cells, and (iii) how the activated AURKA induces nerve cell death.The study will benefit development of therapeutic strategies to protect against brain damage in stroke since this is novel and different target for drug targeting.
Enhancing Erythropoietin Therapy In Ischaemia-reperfusion Injury Of Heart And Kidney
Funder
National Health and Medical Research Council
Funding Amount
$361,021.00
Summary
Heart attacks and kidney disease from a lack of blood flow are common causes of morbidity and have poor treatment options. Erythropoietin (epo) is a useful new treatment, but there remain some caveats to its use in humans: eg. it may cause excessive scarring during repair. Use of epo with an anti-inflammatory drug may decrease scarring and provide benefit to long-term health. We plan to carefully define the biomolecular pathways of injury and repair, to better plan this therapy for human use.
The Role Of Renal Dendritic Cells In Infection And Immunity Under Immunosuppression
Funder
National Health and Medical Research Council
Funding Amount
$475,143.00
Summary
Kidney transplantation is the best treatment for kidney failure but it is frequently complicated by bacterial and viral infections that can cause rejection and may cause loss of the kidney. This grant will study the role that dendritic cells in the kidney play in causing rejection and preventing infection. With the knowledge gained from these studies, we will be able to discover new ways to prevent rejection and treat infections of the kidney post transplant.
Contribution Of Disturbed Blood Flow And Cerebral Metabolism To White Matter Damage In The Perinatal Brain
Funder
National Health and Medical Research Council
Funding Amount
$369,375.00
Summary
It has been known for some time that the white matter regions of the developing brain are particularly vulnerable to damage. These regions are deep in the brain near the ventricles, and are rich in myelin sheaths wrapped around the nerve fibres running from cell-rich areas in the outer layers of the brain to other regions, and down into the spinal cord. Damage to white matter usually leads to behavioural, learning and motor problems in the newborn infant - in its severest form, seen as cerebral ....It has been known for some time that the white matter regions of the developing brain are particularly vulnerable to damage. These regions are deep in the brain near the ventricles, and are rich in myelin sheaths wrapped around the nerve fibres running from cell-rich areas in the outer layers of the brain to other regions, and down into the spinal cord. Damage to white matter usually leads to behavioural, learning and motor problems in the newborn infant - in its severest form, seen as cerebral palsy. Such outcomes are often associated with the presence of asphyxia and infection during pregnancy, leading to the belief that the damage first arises while the baby is still in utero. In this application we suggest that asphyxia and-or infection during pregnancy cause prolonged disturbances in the regulation of blood flow and integrity of the blood-brain barrier in the developing brain, together with changes in metabolism that result in accumulation of prostaglandins and the toxic hydroxyl radical, leading irreversibly to cell death. If this series of events proves to be true, we have suggested and will test several protocols for protecting the fetal brain, which should be readily translatable to clinical practice.Read moreRead less