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.
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.
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.
Selective Activation Of Retinal Networks In Response To High Frequency Electrical Stimulation: A Computational Modelling, In Vitro And In Vivo Study
Funder
National Health and Medical Research Council
Funding Amount
$955,197.00
Summary
Arguably the greatest challenge facing designing a more effective bionic eye occurs at the interface between the electrodes and the retina. We will investigate new ways of steering electricity that will allow stimulation to specifically target pre-determined areas and cells in the retina. While contributing directly to our knowledge of how the retina functions, the work will also be a critical enabler of improved vision processing and stimulation strategies in future generations of a bionic eye.
What Is The Effect Of Alzheimer’s Disease On Eye And Can Ocular Changes Be Used As Biomarker For Alzheimer’s Disease?
Funder
National Health and Medical Research Council
Funding Amount
$718,002.00
Summary
Visual symptoms are frequent early complaints in Alzheimer’s (AD) patients. Examining eyes can be a simple, specific and inexpensive way to assess and diagnose AD and fill in an urgent need for a viable biomarker. Retina is unique part of central nervous system that can be imaged non-invasively and thus serves as a ‘window to the brain”. Monitoring the eyes will also help prevent negative effects of AD on vision by way of timely intervention, in addition to providing mechanistic insights in AD.
Energy Supply In Glaucoma: One Cell's Trash Is Another Cell's Treasure
Funder
National Health and Medical Research Council
Funding Amount
$122,712.00
Summary
Glaucoma is a leading cause of blindness and affects 65 million people worldwide, yet its underlying cause is not well understood. The work described in this research aims to understand the role of oligodendrocytes in provision of energy to retinal ganglion cell axons, and whether impaired energy supply in retinal ganglion cell axons and the optic nerve will lead to glaucoma. It is expected to provide new insight into glaucoma and potentially lead to new treatments.
Glaucoma is a leading cause of irreversible blindness, and its management is hindered by the lack of effective clinical measures of the disease. This project seeks to develop new clinical tests to take the “guesswork” out of its management – measures that can correctly identify those at high-risk of progression, accurately determine treatment efficacy and sensitively detect disease progression, thus preventing the irreversible loss of vision from this disease.
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.
Retinal Endothelial Cell Changes That Precede Retinal Vein Occlusion And The Retinal Extracellular Space Changes That Follow It
Funder
National Health and Medical Research Council
Funding Amount
$118,121.00
Summary
Dr. Min Hye Kang, at The University of Western Australia, is investigating microscopic blood vessel changes that precede the onset of devastating blindness. She is also studying functional changes that occur in the retina following deprivation of its blood supply. Her research has significantly improved our understanding of cellular mechanisms that lead to blindness. It has also aided in the development of new treatment strategies for the prevention of vision loss.
The Structural Basis Of Direction Selectivity In The Retina
Funder
National Health and Medical Research Council
Funding Amount
$401,705.00
Summary
The retina is part of the central nervous system and there are almost one hundred types of retinal neurons which process visual information before it is passed up the optic nerve to the brain. This project examines how some of these neurons are wired together to form a simple neuronal circuit that detects the direction of a moving object. The elucidation of the cellular mechanisms of direction selectivity will provide an important paradigm of complex processing by simple neuronal circuits, with ....The retina is part of the central nervous system and there are almost one hundred types of retinal neurons which process visual information before it is passed up the optic nerve to the brain. This project examines how some of these neurons are wired together to form a simple neuronal circuit that detects the direction of a moving object. The elucidation of the cellular mechanisms of direction selectivity will provide an important paradigm of complex processing by simple neuronal circuits, with direct relevance to information processing in other parts of the central nervous system. In particular, the project may provide strong evidence for two neuronal strategies that may be of general significance. First, information may be processed at a very local level, which would greatly increase the computational power of a single neuron. Second, neurons may make selective contact with only some processes of an input neuron, which would require novel mechanisms for producing the necessary specificity.Read moreRead less