Complement Activation As A Therapeutic Target And Clinical Biomarker For Parkinson's Disease
Funder
National Health and Medical Research Council
Funding Amount
$497,941.00
Summary
Parkinson’s disease is the second most common neurological disease in Australia, yet there is no treatment to slow disease progression. Our study is investigating inflammation within the brain as a major contributing factor in Parkinson’s disease. We will examine this inflammatory pathway in human patients suffering from Parkinson’s, and will test a novel anti-inflammatory drug in animal models of Parkinson’s disease, in order to identify a novel treatment to reduce disease pathology.
Metal-mediated Mechanisms And Therapeutic Approaches For Treating Brain Injury Across Age
Funder
National Health and Medical Research Council
Funding Amount
$1,229,769.00
Summary
This grant will examine the role of zinc and iron in the neuronal changes that occur following brain injury, with a specific focus on the role of these metals in functional outcomes. We will also examine how the role of these metals changes across the normal lifespan, and also whether these metal changes are consistent across different types of brain injury. Finally, we will examine the therapeutic potential of zinc- and iron-targeted compounds.
Therapeutic Targeting Of Neuroinflammation To Slow The Progression Of Neurodegenerative Disease
Funder
National Health and Medical Research Council
Funding Amount
$463,652.00
Summary
My research has identified key components of our immune system, that can worsen disease in conditions such as Parkinson’s disease and motor neuron disease. I hope that exploring these components in animal models, and patients suffering from these diseases, my group can identify new therapeutic drug candidates that can be progressed in clinical trials. Ultimately, this may lead to new treatments to reduce disease burden in patients suffering from these neurodegenerative conditions.
Central Neural Regulation Of Brown Fat Function – Glucose Sensing And CNS Pathways
Funder
National Health and Medical Research Council
Funding Amount
$761,942.00
Summary
Our research aims to identify how specific brain cells detect changes in glucose levels and how ageing and diet affect their function. We identified a subset of nerve cells that detect changes in glucose and the “hunger” hormone ghrelin, their ability to do so adapting with age and nutritional status. This project will investigate the potential of these nerve cells as targets for therapeutic and diet- intervention strategies to target obesity, diabetes and promote healthy ageing.
The Role Of BMP Signalling During Chronic Demyelination And Myelin Repair
Funder
National Health and Medical Research Council
Funding Amount
$67,381.00
Summary
Multiple sclerosis (MS) is the most common neurodegenerative disease affecting young adults. It is a disease that kills myelin cells, which are important support cells for neurons and critical for neuronal function. This research investigates the role of a specific signaling pathway with respect to myelin cell production and repair with the ultimate aim of identifying regenerative therapeutics for MS.
Characterisation And Modelling Of Schizophrenia-associated Dysregulation Of MiR-137 Expression
Funder
National Health and Medical Research Council
Funding Amount
$581,661.00
Summary
We have identified mutation-associated changes in the expression of a non-coding microRNA gene in the cerebral cortex in schizophrenia. This gene, known as MIR137, functions by repressing hundreds of target genes and therefore has major implications for schizophrenia. The project will identify the genetic mechanism affecting the expression of MIR137, and determine the biological and behavioural implications of this change in the context of schizophrenia.
Cell Death In The Retina: Analysing The Switch That Triggers Dependency On Target-derived Trophic Factors
Funder
National Health and Medical Research Council
Funding Amount
$428,414.00
Summary
Construction of the developing nervous system in the embryo involves the creation of nerve cells and their connections, but also involves loss of a proportion of these cells prior to maturation. We will study this process of cell death and how developing nerve cells switch on their dependency to survival factors. In so doing we will better understand what happens when brain development goes wrong and also devise new ways to protect nerve cells in the injured or degenerate adult nervous system.
To Understand The Role Of The Plasminogen Activating And Matrix Metalloproteinase Systems In Traumatic Brain Injury
Funder
National Health and Medical Research Council
Funding Amount
$499,321.00
Summary
Tissue-type plasminogen activator (t-PA) is known for its role as a clot dissolving protein. It is present in the brain and following traumatic brain injury (TBI), it can worse brain cell damage. We have established a mouse model of TBI . We will compare brain damage in mice that are deficient in or have high amounts of t-PA. We will also determine whether the recovery rate post-TBI can be improved using specific t-PA blockers. This project may provide new therapies for TBI.
Generating multi-component scaffolding to influence the differentiation of embryonic stem cells. Nervous system diseases are debilitating and will develop in over 50 per cent of people at some time in their life. This project will develop strategies so that stem cells can be utilised to encourage brain repair for the treatment of Parkinson's disease. The technology developed will also be of benefit for the treatment of other nervous system disorders.
Special Research Initiatives - Grant ID: SR1101002
Funder
Australian Research Council
Funding Amount
$21,000,000.00
Summary
Stem Cells Australia. Despite progress in stem cell research, scientists do not understand how stem cells “decide” what to become. Stem Cells Australia will draw upon strengths within Australia’s premier stem cell research universities and institutes. This collaboration between leading bioengineering, nanotechnology, stem cell and advanced molecular analysis experts, will fast-track efforts to deliver a fundamental understanding of the mechanisms of stem cell regulation and differentiation, and ....Stem Cells Australia. Despite progress in stem cell research, scientists do not understand how stem cells “decide” what to become. Stem Cells Australia will draw upon strengths within Australia’s premier stem cell research universities and institutes. This collaboration between leading bioengineering, nanotechnology, stem cell and advanced molecular analysis experts, will fast-track efforts to deliver a fundamental understanding of the mechanisms of stem cell regulation and differentiation, and the ability to control and influence this process. Stem Cells Australia will deliver new methods for stem cell propagation and manipulation, new translational technologies for therapeutic applications, and will prepare Australia’s future stem cell scientific leaders.Read moreRead less