Parkinson's Disease is caused by injury to a group of brain cells called the Basal Ganglia. Our current ideas about how this part of the brain works is dominated by a well know theory. This theory requires that the output pathway of the basal ganglia to have a negative or inhibitory influence on its target. However there are numerous reasons why this would be unlikely, including some recent evidence from experiments in our laboratory. The purpose of this study is to undertake an extensive re exa ....Parkinson's Disease is caused by injury to a group of brain cells called the Basal Ganglia. Our current ideas about how this part of the brain works is dominated by a well know theory. This theory requires that the output pathway of the basal ganglia to have a negative or inhibitory influence on its target. However there are numerous reasons why this would be unlikely, including some recent evidence from experiments in our laboratory. The purpose of this study is to undertake an extensive re examination of the output paths of the Basal Ganglia. If our suspicions are correct, it will lead to a review of the whole way in which we think the Basal Ganglia works.Read moreRead less
Motor Unit Synchronisation And Neuromuscular Performance
Funder
National Health and Medical Research Council
Funding Amount
$198,500.00
Summary
The fine control of force is important for many everyday tasks such as writing, grasping objects between index finger and thumb, and fastening buttons. Factors that influence the ability to control force include the coordinated activation of groups of muscle fibres called single motor units. This proposal focuses on the concept that the coordinated activation of motor units is influenced by muscle activity and can impair the ability to produce finely controlled muscle contractions. The goal of t ....The fine control of force is important for many everyday tasks such as writing, grasping objects between index finger and thumb, and fastening buttons. Factors that influence the ability to control force include the coordinated activation of groups of muscle fibres called single motor units. This proposal focuses on the concept that the coordinated activation of motor units is influenced by muscle activity and can impair the ability to produce finely controlled muscle contractions. The goal of these studies is to explore the boudary conditions of the adaptive nature of the nervous system to examine how coordinated motor unit activity influences these aspects of neuromuscular performance. The outcomes of these experiments will identify if altering muscle activity influences the control of movement by altering single motor unit activity. These results will have direct application to the interpretation of abnormal movement control and tremor that is observed in certain neurological diseases such as Parkinson's disease. Furthermore, new information will be gained on the adaptability of the motor system and its role in the execution of fine motor tasks that may aid in the development of rehabilitation strategies following stroke or spinal cord injury.Read moreRead less
I am a practicing neurologist with a clinical interest in movement disorders and dementia with an international reputation in neurosciences in the fields of neural stem cells, transgenic animal models of movement disorders and epilepsy. In line with my cl
The Regulation Of Pluripotency And Self-renewal In Embryonic And Germline Stem Cells.
Funder
National Health and Medical Research Council
Funding Amount
$491,767.00
Summary
Regulation of self-renewal and developmental potential in embryonic and germline stem cells. The capacity of some stem cells to self-renew and under specific conditions, give rise to all adult cell types, a property known as pluripotency , is the key to unlocking the potential of cell based therapies. The development of stem cell based therapies promises to revolutionize the treatment of many common human diseases. For instance, in neurodegenerative conditions such as Parkinsons disease, normal ....Regulation of self-renewal and developmental potential in embryonic and germline stem cells. The capacity of some stem cells to self-renew and under specific conditions, give rise to all adult cell types, a property known as pluripotency , is the key to unlocking the potential of cell based therapies. The development of stem cell based therapies promises to revolutionize the treatment of many common human diseases. For instance, in neurodegenerative conditions such as Parkinsons disease, normal embryonic stem cells grown in culture could be used to replace the lost or disabled neurons in the patient. Many other conditions including diabetes, cystic fibrosis, myocardial infarction (heart attack) and stroke could potentially be treated with stem cell based therapies. Understanding the molecular regulators that govern establishment and maintenance in culture of stem cell lines derived from embryos and from germ cells is the primary goal of this study. We will use well-established techniques to genetically manipulate mouse embryonic stem cells and embryos to examine the role of a specific gene, NANOG. Named after the Celtic legend of Tir NaNog (land of the ever young). When NANOG was forced to remain active, embryonic stem cells were able to grow in media deficient in factors usually required for self-renewal and did not lose their pluripotency even when treated with chemical agents that usually induce differentiation. Understanding the full capacity of NANOG to influence stem cell self-renewal and elucidation of the underlying molecular pathways regulated by this gene will provide valuable insights into the establishment and manipulation of stem cell lines from embryonic and adult tissues.Read moreRead less