A Role For The Pulvinar Nucleus In Visual Cortical Development And Plasticity
Funder
National Health and Medical Research Council
Funding Amount
$844,435.00
Summary
This project will investigate a part of the brain responsible for processing visual information, the pulvinar. This area has received little attention but has more recently been associated with the capacity for infants to recover vision following injuries such as stroke, as well as in mental health conditions such as schizophrenia. We will take a cell-to-system approach to uncover how this area develops and modulates the processing of visual information.
The Pulvinar Is Instrumental In The Development Of Visual Cortical Networks
Funder
National Health and Medical Research Council
Funding Amount
$1,192,911.00
Summary
This Project will elucidate the mechanisms and brain structures involved in visual system development and how their perturbation in early life can lead to neurodevelopmental and cognitive brain disorders, such as Williams and fragile-X syndromes as well as dyslexia. Furthermore, it will demonstrate how the visual brain has a greater capacity to compensate and achieve preservation of vision following an injury in early life.
Studies Of The Effects Of Asymmetric Hearing Loss On The Brain
Funder
National Health and Medical Research Council
Funding Amount
$920,076.00
Summary
Hearing loss impairs the normal development and maintenance of auditory pathways. Irreversible pathologies persist when hearing is not restored in a timely manner. While cochlear implantation is the accepted treatment for profound sensorineural hearing loss, there is significant variability in outcomes. Some of this variability is linked to the degree of hearing asymmetry. Thus, we propose to study brain changes in the auditory system that accompany asymmetric hearing impairment.
The Plastic Effects Of Long-term Partial Deafness And Chronic Cochlear Implant Use On The Response Of Primary Auditory Cortex To Combined Electro-acoustic Stimulation
Funder
National Health and Medical Research Council
Funding Amount
$560,267.00
Summary
Cochlear implants were originally used only in cases of profound deafness, but are now being used in patients who have some residual hearing at low frequencies. Our goal is to better understand how the electrical information from the cochlear implant and the acoustic information provided by the residual hearing are combined in the brain to produce unified perception of the auditory environment.
Bilateral Cochlear Implants: Restoring Binaural Processing By Experience And Training With Binaural Cues
Funder
National Health and Medical Research Council
Funding Amount
$968,030.00
Summary
Cochlear implantation in both ears is increasingly common and while there are benefits, performance falls short of expectations, likely due to the degradation of the long-term deaf brain’s sensitivity to small timing differences of sounds reaching each of the two ears. By confirming the hypothesis that experience with high-fidelity timing information will improve performance, this study will drive the technical innovations required to maximise the benefits and investment of bilateral implants.
Dizziness, vertigo, and imbalance affect nearly half the population by the age of 60 and balance-related falls, especially in the elderly, are a serious health concern. Surveys of primary care doctors have shown that dizziness and vertigo are as prevalent as hypertension and angina, and approximately 40% of the population experience dizziness severe enough to seek medical attention. Unfortunately, most symptoms are not relieved by currently available medical treatment. There is, however, a remar ....Dizziness, vertigo, and imbalance affect nearly half the population by the age of 60 and balance-related falls, especially in the elderly, are a serious health concern. Surveys of primary care doctors have shown that dizziness and vertigo are as prevalent as hypertension and angina, and approximately 40% of the population experience dizziness severe enough to seek medical attention. Unfortunately, most symptoms are not relieved by currently available medical treatment. There is, however, a remarkable hidden reserve of 'self-repair' in the balance system that can be triggered under certain conditions. We call this process 'vestibular compensation' and if we can understand those conditions and discover the means by which this reserve affects the nervous system, we may be able harness its power to alleviate the all distressing symptoms of imbalance. Perhaps we may even be able to apply these principles to other critical systems that may need repair. We propose to look at a key region in the central nervous system that is responsible for processing balance signals and may be very important in 'vestibular compensation'. We will try to activate this recovery process under controlled conditions so that we can understand the changes that occur. Specifically we will examine the role of vestibular (balance) neurons in the central nervous system that appear to be modified following trauma of the inner ear balance organs. We will use our new recording techniques to examine these vestibular neurons to see how their intrinsic properties may change and what external or internal factors influences this change. Our aim is to understand what factors promote and what factors inhibit full recovery.Read moreRead less
This is a study of the senses which arise from our muscles and which tell us where our different body parts are, at any point in time. These senses, collectively called proprioception, are also involved in the automatic, unconscious control of our muscles. So, ultimately, they allow us to stand and to move freely with precision and confidence, even in the dark. One of these senses, the sense of effort or of heaviness, is believed to be generated within the brain. It intensifies when we become fa ....This is a study of the senses which arise from our muscles and which tell us where our different body parts are, at any point in time. These senses, collectively called proprioception, are also involved in the automatic, unconscious control of our muscles. So, ultimately, they allow us to stand and to move freely with precision and confidence, even in the dark. One of these senses, the sense of effort or of heaviness, is believed to be generated within the brain. It intensifies when we become fatigued. These experiments will be concerned with finding out more about how this works. We have a method that uses magnetic stimulation of the brain to change its control of our muscles. Using it we will learn how this sense is generated. When we close our eyes and move our limbs we realise that we know exactly where they are at any point in time. It remains uncertain exactly how this information is generated within the nervous system. One idea, arising from some recent experiments which we want to test, is that as we move the limb, the skin over the moving parts is stretched and stretch-sensitive nerve endings in the skin provide us with information about the movement. Alternatively, perhaps it is the effort we exert to maintain limb position against the force of gravity which tells us where the limb is. In another recent study we have found that when a muscle has become painful from excessive exercise or from some local strain injury, our ability to control the muscle and so move the limb is no longer as effective. We want to study the underlying nervous mechanisms responsible for the changes in movement control. Are they designed to spare the muscle while it recovers from injury? How are they brought about? All of this work is important for a better understanding of ourselves, for a better clinical diagnosis when something goes wrong and for improved treatment of diseased or injured muscles.Read moreRead less