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.
Development Of Human Sensory Receptors Of The Inner Ear
Funder
National Health and Medical Research Council
Funding Amount
$418,281.00
Summary
Normal development of our special sense organs is crucial for sight, taste, hearing, and balance. The balance system mediates important postural and eye reflexes that are essential for movement and vision. Abnormal development of the balance system results in dizziness, vertigo, gait deficits, and impaired learning and reading ability in children. This study will investigate how the organs of balance mature and connect with nerve fibres of the inner ear during human development.
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.
While there has been recent excitement about possible treatments for the symptoms of Autism, advances in understanding the underlying neuroscience of abnormal brain function that underlies autistic tendency are still painfully slow. This application aims to establish fully a physiological mechanism for altered autistic perception, to see if it can be applied to early diagnosis in infants and young children and to establish whether in such plastic young brains it is possible to guide perceptual l ....While there has been recent excitement about possible treatments for the symptoms of Autism, advances in understanding the underlying neuroscience of abnormal brain function that underlies autistic tendency are still painfully slow. This application aims to establish fully a physiological mechanism for altered autistic perception, to see if it can be applied to early diagnosis in infants and young children and to establish whether in such plastic young brains it is possible to guide perceptual learning to permanent improvement.Read moreRead less
Differentiation, Electrical Activity And Synapse Structure Of Human Stem Cell-derived Sensory Neurons
Funder
National Health and Medical Research Council
Funding Amount
$322,088.00
Summary
A major challenge in treating neurodegenerative conditions with stem cells, is to generate a population of donor cells which are capable of incorporating into the host nervous system and restoring function. This proposal will test the capacity of human stem cells to make functional connections in the auditory system, potentially enhancing hearing with a cochlear implant. These studies are critical in determining how stem cells may be used to promote functional regeneration of the damaged nervous ....A major challenge in treating neurodegenerative conditions with stem cells, is to generate a population of donor cells which are capable of incorporating into the host nervous system and restoring function. This proposal will test the capacity of human stem cells to make functional connections in the auditory system, potentially enhancing hearing with a cochlear implant. These studies are critical in determining how stem cells may be used to promote functional regeneration of the damaged nervous system.Read moreRead less
Understanding the structure of the human retina is important for understanding normal visual function. The goal of this study is to supply data on the distribution, density and connectivity of nerve cells in the human retina. Our study will provide a foundation for areas of clinical investigation of the human retina.
Brain Pathways Serving Conscious And Sub-conscious Vision
Funder
National Health and Medical Research Council
Funding Amount
$571,444.00
Summary
In humans and other primates the visual system comprises evolutionary new pathways (called magnocellular or M, and parvocellular or P) superimposed on evolutionary old pathways (called koniocellular or K). These parallel pathways carry visual information from the retina, through a brain centre in the thalamus called lateral geniculate nucleus (LGN), to the cerebral neocortex. Our aim is to study the role of the K pathway in visual processing.
The Cellular Organisation Of Interneurones In Human Retina
Funder
National Health and Medical Research Council
Funding Amount
$526,454.00
Summary
Our goal is to determine the numbers and types of nerve cells in the human retina: the part of the eye where visual processing starts. This data will serve as a baseline against which effects of visual disease can be measured.
The Role Of Gliosis In Advanced Retinal Degeneration
Funder
National Health and Medical Research Council
Funding Amount
$457,785.00
Summary
The development of treatments that restore vision assumes that the output neurons of the retina remain intact. Yet, there is now considerable evidence that the neurons that signal from the retina to the brain are altered in those that have degenerative diseases of the retina. Here, we will examine the cause of these cellular changes in an animal model and seek to prevent the loss of output neurons. This information is crucial for the development of treatments that seeks to restore vision.
Development Of Peripheral Sensory Pathways In Humans
Funder
National Health and Medical Research Council
Funding Amount
$477,504.00
Summary
To receive the appropriate information about the state of our muscles, joints, organs, and skin we need a properly 'connected' sensory system. Recent evidence suggests traumatic events during early development can alter sensory connections within the spinal cord. This can lead to debilitating movement disorders, digestive diseases, and increased pain. In this study we will examine how peripheral sensory fibres connect with the appropriate nerve cells in the human spinal cord during development.