The corticospinal pathway is the major route from the brain to the spinal cord for the control of voluntary movement in people. Little is known about how transmission through this pathway might alter with activity. It is known that, elsewhere in the brain, connections between nerve cells can be made stronger or weaker by specific patterns of activity and it is thought that such changes underlie learning and memory. We propose that similar changes might happen in the spinal cord at the connection ....The corticospinal pathway is the major route from the brain to the spinal cord for the control of voluntary movement in people. Little is known about how transmission through this pathway might alter with activity. It is known that, elsewhere in the brain, connections between nerve cells can be made stronger or weaker by specific patterns of activity and it is thought that such changes underlie learning and memory. We propose that similar changes might happen in the spinal cord at the connection between the nerve cells which carry signals from the brain and the nerve cells which carry the signals out to the muscle. This project will demonstrate that the connections in the pathway from the brain to the muscle can be strengthened or weakened in a controlled way by imposed patterns of activity. In addition, we know that after voluntary contractions, there are dramatic changes in the way signals in this pathway are transmitted to muscles. After brief strong voluntary contractions, muscle responses are immediately reduced. After longer contractions in which the muscles become fatigued, the reduction is followed by an increase in responses which can last many minutes. Thus, this project will also study changes in the pathway from the brain to the muscle after natural activity. The effects of changes induced by artificial or natural activity on the control of voluntary movement will also be investigated. Understanding how activity drives changes in the pathway that controls voluntary movement is important for all situations that involve learning motor tasks. These include normal development and learning of motor skills, as well as rehabilitation after all kinds of nerve or muscle injury. It is also important in understanding motor changes that occur when activity is altered by disorders like spinal cord injury or stroke. Improved understanding of the processes occuring should allow improvement in rehabilitation therapies.Read moreRead less
Novel Assessments Of The Central And Peripheral Control Of The Human Hand
Funder
National Health and Medical Research Council
Funding Amount
$365,105.00
Summary
This is a study of how the human hand works. The hand is supremely adapted for manual skills ranging from writing and playing a musical instrument to non-verbal communications via gesture and pointing. How is the range of hand skills achieved? We are motivated to study this because the ability of the hand to recovery from some neurological disorders, particularly stroke, is very poor. One important element in virtually all activities of the hand is precise movement of the thumb. The tip of the t ....This is a study of how the human hand works. The hand is supremely adapted for manual skills ranging from writing and playing a musical instrument to non-verbal communications via gesture and pointing. How is the range of hand skills achieved? We are motivated to study this because the ability of the hand to recovery from some neurological disorders, particularly stroke, is very poor. One important element in virtually all activities of the hand is precise movement of the thumb. The tip of the thumb is flexed by a single muscle, a muscle only present in humans. We want to determine how this muscle works, and how the force it produces affects the whole hand. We will use specialised neurophysiological techniques to do this in human volunteers. There is no comparable animal model for this type of work due to significant differences at both the level of the brain and the level of the muscle. Second, we want to understand better how the cells in the spinal cord which control the hand (and other) muscles work. We have two new ways to do this, including a novel technique which can activate these cells with a form of stimulation that may help us improve functional electrical stimulation. Finally, with 27 bones and more than 25 muscles which operate it, the hand is not simple to control. We will use a new apparatus to measure how well it is controlled, and we will directly stimulate the motor areas of the brain to evaluate the control. From this, we will come up with new understanding, as well as new stimulus and measurement techniques that can be applied to patients with impaired hand function, as occurs all too often after stroke.Read moreRead less
The Role Of Neuronal Hyper-excitability In An Animal Model Of Motor Neuron Disease
Funder
National Health and Medical Research Council
Funding Amount
$558,170.00
Summary
Every day at least one person in Australia dies of the fatal and untreatable adult neurodegenerative disease of amyotrophic lateral sclerosis (motor neuron disease). This research examines the factors driving early increases in neural activity which may lead to the loss of upper and lower motor neurons in adulthood. The use of new methods to suppress production of specific proteins causing increased neural activity may lead to novel treatments for this disease.
I will use non-invasive brain stimulation to study the operation of the corticospinal pathway in humans while they perform tasks requiring precise control of fingers and thumb. This pathway from brain to spinal cord is important for independent finger movements, and these experiments will provide insight into the cortical mechanisms by which independent finger movements are produced. I will also investigate relationships between patterns of corticospinal activation (which I have shown differ bet ....I will use non-invasive brain stimulation to study the operation of the corticospinal pathway in humans while they perform tasks requiring precise control of fingers and thumb. This pathway from brain to spinal cord is important for independent finger movements, and these experiments will provide insight into the cortical mechanisms by which independent finger movements are produced. I will also investigate relationships between patterns of corticospinal activation (which I have shown differ between subjects and hands) and digital dexterity. While it seems reasonable to assume that digital dexterity is dependent on the operation of the corticospinal system, the relationship is obscure, even at a gross level. Digital dexterity can vary considerably between subjects, and even between hands in the same subject. Are people more skilled with their hands because they are better able to engage the corticospinal system in control of the digits? The present study will address this fundamental question. The brain stimulation techniques that I will use are the only techniques presently available which can answer these questions in humans. This information will assist us to understand how normal subjects perform skilled tasks with their hands, as well as helping us to understand how damage to the nervous system (e.g., stroke, multiple sclerosis, Parkinson's disease) produces deficits in movement control. The information gained may suggest training regimes for skill acquisition in normal subjects, and to promote recovery of function in patients with neurological damage or disease.Read moreRead less
Central pathways regulating visceral pain. This project aims to investigate the neural pathways within the spinal cord and brain processing colorectal pain perception. The project aims to identify the spinal cord neurons relaying colorectal signalling into the brain and the influence of descending modulation from the brainstem upon these pathways. The outcomes will greatly benefit fundamental understanding of the central pathways processing visceral pain.
Transcriptional control of neural stem cell differentiation during development and disease. Understanding the molecular mechanisms that control how neural stem cells differentiate is critical to provide potential therapeutic treatment for neurodegenerative diseases and for brain cancer. This project will aim to discover, using an animal model system, the genes and molecules regulating these key biological processes.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100074
Funder
Australian Research Council
Funding Amount
$520,000.00
Summary
Facilities for automated high-throughput slide scanning and stereology. The equipment requested will facilitate the work of the Australian Mouse Brain Mapping Consortium, a consortium of Australian research groups collaborating to provide the only mouse model brain mapping capability in the country. The consortium brings together laboratory, neuroimaging and computational expertise in a comprehensive framework for imaging the mouse brain. This will help researchers to study mouse models of genet ....Facilities for automated high-throughput slide scanning and stereology. The equipment requested will facilitate the work of the Australian Mouse Brain Mapping Consortium, a consortium of Australian research groups collaborating to provide the only mouse model brain mapping capability in the country. The consortium brings together laboratory, neuroimaging and computational expertise in a comprehensive framework for imaging the mouse brain. This will help researchers to study mouse models of genetic and acquired disorders across the life-span. Remote viewing and analysis capabilities will help overcome the 'tyranny of distance', increasing national access to the facility. Repositories of digitised images will increase the availability of valuable research material to other Australian and international researchers.Read moreRead less