Pain changes movement. Although undisputed, there is a surprising lack of agreement regarding the underlying mechanisms. This project involves an innovative mix of neurophysiological methods to investigate the drive to muscle cells from the nervous system and changes in the mechanics of contraction. These studies will resolve the perplexing problem of how pain changes our ability to activate muscle. Clear understanding of the underlying mechanisms can guide rehabilitation.
Changes In Motor Control And Kinaesthetic Sensations After Eccentric Exercise.
Funder
National Health and Medical Research Council
Funding Amount
$287,250.00
Summary
It is a well-known observation that after a period of intense exercise we are unsteady on our feet and are clumsy when attempting to make precision movements. Such impressions are particularly marked after eccentric exercise, during which the contracting muscles are forcibly lengthened. Activities such as walking downhill, skiing and horse riding involve eccentric exercise. The debilitating consequences of this kind of exercise are attributed, not just to the post-exercise effects of fatigue, bu ....It is a well-known observation that after a period of intense exercise we are unsteady on our feet and are clumsy when attempting to make precision movements. Such impressions are particularly marked after eccentric exercise, during which the contracting muscles are forcibly lengthened. Activities such as walking downhill, skiing and horse riding involve eccentric exercise. The debilitating consequences of this kind of exercise are attributed, not just to the post-exercise effects of fatigue, but to loss of muscle force from damage to fibres. Eccentric exercise also leads to longer term effects. The breakdown of the damaged tissue leads to sensations of stiffness and soreness the next day. This application proposes experiments aimed at studying a number of effects of eccentric exercise on motor control, and establishing the muscle, spinal and brain levels at which they occur. Three studies are planned. In the first, the question will be explored whether we are less able to use the motor areas of our brains to execute voluntary contractions after exercise. So fatigue is not just a matter of exhausted muscles but perhaps also exhausted brains. We will use brain and spinal cord stimulation to explore this point. Then we plan to listen to single motor units, the basic elements of muscle control, to try to understand the mechanism by which the brain minimises the debilitating effects of fatigue. Finally we want to examine subjects' ability to locate their limbs in space as a means of providing a basis for the clumsiness we experience after intense exercise. These are all important issues relevant to clinical medicine and rehabilitation as well as sports science and exercise.Read moreRead less
Harnessing Human Motor Cortical Plasticity For Performance And Rehabilitation
Funder
National Health and Medical Research Council
Funding Amount
$341,304.00
Summary
Motor learning allows us to interact with our environment and loss of this ability is catastrophic. The reorganisational capacity of the brain can be used to enhance recovery from brain injury. However, our ability to do so is limited by lack of understanding of the underlying mechanisms. These studies will use novel approaches to investigate how the human brain reorganises during motor skill learning. The outcomes will be important for the development of novel therapeutic approaches.
The Contribution Of Dopamine To Regulation Of Orofacial, Limb And Trunk Control: System Or Function Specific Effects?
Funder
National Health and Medical Research Council
Funding Amount
$493,124.00
Summary
Treatment for Parkinson's disease, including dopamine replacement therapy and deep brain stimulation, fail to produce the same beneficial effects on all movement systems. Whereas limb function is the primary beneficiary of these treatments, other functions such as speech and postural control are less responsive. Critical to the research is the postulate that such differences may have arisen due to the fact that previous studies of dopamine and movement control have investigated distinct motor sy ....Treatment for Parkinson's disease, including dopamine replacement therapy and deep brain stimulation, fail to produce the same beneficial effects on all movement systems. Whereas limb function is the primary beneficiary of these treatments, other functions such as speech and postural control are less responsive. Critical to the research is the postulate that such differences may have arisen due to the fact that previous studies of dopamine and movement control have investigated distinct motor systems via the assessment of distinct movement constructs, making cross system comparisons an impossible task. The proposed research will assess the effect of Parkinson's disease, deep brain stimulation and dopamine on identical muscle functions within the orofacial, trunk and limb muscle systems. To this end, the results generated from this resarch have the potential to reconceptualise working models of brain-muscle relationships. Further the research will provide guidance for future studies that aim to eradicate trade-off effects (e.g. limb function improved but not speech) relating to symptom relief for people with Parkinson's disease.Read moreRead less
The Influence Of Human Cortical Rhythms On The Induction Of Plasticity
Funder
National Health and Medical Research Council
Funding Amount
$298,898.00
Summary
The human brain has a great capacity to reorganise. This capacity is known as plasticity and is behind our ability to learn new skills. Plasticity is important for recovery from brain injury. The recently developed technique of transcranial magnetic stimulation can be used to manipulate plasticity in the human brain This approach offers new and exciting therapeutic opportunities. This project is aimed at optimising this technique.