Action-reward Integration In The Amygdalocortical-striatal Network.
Funder
National Health and Medical Research Council
Funding Amount
$757,495.00
Summary
This research focuses on the neural bases of decision making, a general capacity affected by normal ageing, disorders associated with neurodegeneration, major psychiatric conditions, obesity and drug addiction. This program will contribute critical new knowledge on the brain systems through which cognitive and emotional processes are integrated to control choice and decision-making and the influence of neuropathology on this integrative process.
Mechanisms And Pathways Leading To Saccadic Suppression In Primate Brain
Funder
National Health and Medical Research Council
Funding Amount
$858,086.00
Summary
Only the central few degrees of the visual field are viewed in high resolution. Consequently, the eyes must be pointed at targets of interest using saccadic eye movements. Each saccade generates potentially disturbing image motion but this is never perceived: saccadic suppression. This project aims to characterise the neural basis of saccadic suppression using modern techniques. As a result, a prime question in Neuroscience for over 100 years can now be answered.
Visuomotor Integration In The Medial Parietal Cortical Areas
Funder
National Health and Medical Research Council
Funding Amount
$665,163.00
Summary
This project will find out how the electrical activity of brain cells is used to direct the arms to a specific position in the space around a person's body. By understanding the code used by brain cells to perform this control of the arms, we will be able to "read" the brain activity directly, and use it to allow control of artificial arms by people who have been paralysed or had amputations.
A decade ago the adult brain was thought of as a structurally-fixed organ. Against this are well-documented cases of slow recovery after massive injuries or stroke. Simple models of brain injury using the tactile, visual and auditory systems of animals as models have now revealed multiple stages of recovery (plasticity). Some of these are inbuilt into the wiring of the neural systems such that functional plasticity can result without the need for any structural or cellular changes. A second grou ....A decade ago the adult brain was thought of as a structurally-fixed organ. Against this are well-documented cases of slow recovery after massive injuries or stroke. Simple models of brain injury using the tactile, visual and auditory systems of animals as models have now revealed multiple stages of recovery (plasticity). Some of these are inbuilt into the wiring of the neural systems such that functional plasticity can result without the need for any structural or cellular changes. A second group of plastic phenomena depend upon minute changes in the connections between neurons and these are invoked in the first few days following an injury (synaptic plasticity; changes in the pattern and strength of the connections between neurons). Aside from being model systems, there are also parallels of this plasticity with clinical situations such as losses in hearing and sight, and of the adaptations made by the brain in response to prosthetics (e.g. bionic ear) and resorative surgery but the degree of relevance for these situations is unclear. An intriguing aspect of the experiments on auditory and visual systems is that neurons with inputs from both ears, or both eyes, undergo the plastic changes when the relevant sense organ on only one side is damaged but the other is intact. In fact, on the basis of the limited available evidence, it appears that the changes are independent of there being a normal input from the other side. This is difficult to explain in terms of the modern understanding neuronal plasticity at a cellular level. It is thus proposed to study both auditory and visual models of this brain plasticity with stimuli which are systematically varied to extract the extent of bilateral interaction in the induced plasticity. This will enable prediction of how these plasticity mechanisms will be involved in adaptations made to prosthetics and surgical corrections.Read moreRead less
Frontotemporal Dementia And Motor Neurodegenerative Syndromes
Funder
National Health and Medical Research Council
Funding Amount
$17,069,580.00
Summary
Frontotemporal degeneration of the brain is a leading cause of morbidity due to a pathologically heterogeneous, rapidly-progressive group of disorders with behavioural, language and motor deficits. Our internationally recognized team will continue to develop the necessary tools and therapies to effectively diagnose, manage and treat these disorders. Our focus in this program is to understand the unusual genetics underpinning these disorders, and to fast track any potential treatments.
Understanding The Brain In The Transition From Acute To Chronic Low Back Pain
Funder
National Health and Medical Research Council
Funding Amount
$107,049.00
Summary
A critical question in treating low back pain (LBP) is why some people get better after hurting their back while others do not. Physiological mechanisms, such as brain plasticity and central sensitisation, are believed to underpin the transition to persistent pain. This is the first study to evaluate these mechanisms longitudinally and their relationship with LBP outcomes. The result of this research will provide better understanding of pain mechanisms of LBP and assist to develop novel therapy.
Understanding The Organisation Of The Medial Parietal Cortex: Sensorimotor Integration For Goal-directed Behaviour
Funder
National Health and Medical Research Council
Funding Amount
$551,862.00
Summary
Reaching and grasping are of obvious significance for a productive life, and many of the brain areas known to be involved in the direction of arm movements are located in the parietal lobe. Stroke affecting this part of the brain causes disability, as people become unable to reach accurately, or to close their hands around objects with appropriate strength. This project will combine modern physiological and anatomical methods to reveal the brain circuitry responsible for such crucial skills.