Structure And Function Of The Third Geniculocortical Pathway In Primates.
Funder
National Health and Medical Research Council
Funding Amount
$296,777.00
Summary
Our understanding of the human visual system has been based on the idea that there are two main nerve pathways from the eye to the brain. One, called the parvocellular pathway, is for colour and detail vision, and the other, called the magnocellular pathway, is for movement perception. Damage to either pathway by disease such as glaucoma, or a lesion such as stroke, will cause specific changes in visual perception and these changes can be used to diagnose the nature of the disease or lesion. We ....Our understanding of the human visual system has been based on the idea that there are two main nerve pathways from the eye to the brain. One, called the parvocellular pathway, is for colour and detail vision, and the other, called the magnocellular pathway, is for movement perception. Damage to either pathway by disease such as glaucoma, or a lesion such as stroke, will cause specific changes in visual perception and these changes can be used to diagnose the nature of the disease or lesion. We will study a recently recognised third subdivision of the visual pathway, called the koniocellular pathway. The properties of koniocellular cells have not previously been studied in anthropoid primates, and their importance for human vision is not well understood. We will study the way that koniocellular cells respond to moving and patterned stimuli, and their connections with the cerebral cortex, in order to determine whether this pathway could contribute to aspects of normal and abnormal visual perception. We will follow up our preliminary evidence that koniocellular cells respond to visual stimuli of the type used to diagnose the early stages of eye diseases such as glaucoma. The results will give us a better understanding of the way that the nervous system processes visual information, and will clarify the basis of disturbances to normal visual function.Read moreRead less
Origin And Specificity Of Neuronal Signals For Colour Vision In Primates.
Funder
National Health and Medical Research Council
Funding Amount
$490,500.00
Summary
How do we see colours? What do colour blind people see? Although colour is one of the most important attributes of objects in the visual world, the way that colour is processed in the brain is poorly understood. The aim of this project is to study the way that nerve cells in the eye (the retina) and the visual part of the brain are specialised to transmit signals for colour perception. The visual system of humans and other primates includes nerve cells which are selective for a limited range of ....How do we see colours? What do colour blind people see? Although colour is one of the most important attributes of objects in the visual world, the way that colour is processed in the brain is poorly understood. The aim of this project is to study the way that nerve cells in the eye (the retina) and the visual part of the brain are specialised to transmit signals for colour perception. The visual system of humans and other primates includes nerve cells which are selective for a limited range of wavelengths reflected by objects in the visual world. We will study how this selectivity is generated, by examining how the colour receptors are connected within the retina to the cells which transmit nerve impulses to the brain. Between 5 and 7 percent of male humans have colour vision defects. Many objects which appear clearly different to colour-normal observers cannot be discriminated by colour-defective observers, and entry to professions such as the police and airline industry is restricted for individuals with colour vision defects. We will study the basis of reduced colour perception ability in red-green colour blindness. This will be done by measuring the responses of nerve cells in a species of primate (marmoset) in which many animals have colour vision receptors resembling those of humans with colour vision defects. We will measure the reliability with which individual neurones can transmit signals for colour vision when they receive input from such abnormal receptors. It is known that nerve cells transmit their message within the brain by means of brief electrical impulses called action potentials. In addition to studying the basis of human colour discrimination, the project also addresses one of the fundamental questions of sensory processing, by studying the reliability of the coded message carried by action potentials within the central nervous system.Read moreRead less
Non-standard Receptive Fields In The Primate Visual System
Funder
National Health and Medical Research Council
Funding Amount
$392,983.00
Summary
We recently discovered that an evolutionary ancient brain pathway transmits visual signals for blue-yellow colour vision. We now plan to discover whether this pathway could also contribute to form and movement perception, and to visual functions (called blindsight) that survive damage to the main visual area of the brain. This project will contribute to understanding the effects of damage to visual pathways following stroke or brain injury, as well as to understanding normal visual function.
Multidimensional Coding Of Visual Information In The Retina
Funder
National Health and Medical Research Council
Funding Amount
$359,431.00
Summary
Although both the retina and visual cortex are part of the central nervous system, the coding of visual information in the two laminar structures differs markedly in that all three dimensions of the cortical sheet are used to code multiple response axes but only one dimension of the retinal sheet. This project examines how visual response properties are mapped through the depth of the retina and this will provide a comparatively simple paradigm of complex information processing in the brain.
Interactions Between Afferent Channels In Vision: Basic Neurophysiology And Implications For The Pathology Of Dyslexia
Funder
National Health and Medical Research Council
Funding Amount
$423,662.00
Summary
We intend to study the interactions between different information channels in the primate visual system. The pathways from the eyes to the brain consist of different types of nerve fibres carrying distinct sorts of information. These channels have been believed to remain separate as they transmit the information through various levels of the brain. Finally, in the neocortex, it has been suggested that the visual information goes along two major streams, one dorsally to the parietal cortex and th ....We intend to study the interactions between different information channels in the primate visual system. The pathways from the eyes to the brain consist of different types of nerve fibres carrying distinct sorts of information. These channels have been believed to remain separate as they transmit the information through various levels of the brain. Finally, in the neocortex, it has been suggested that the visual information goes along two major streams, one dorsally to the parietal cortex and the other ventrally to the temporal cortex. Based upon recent studies, we question this strict segregation of the pathways and propose to study how interactions occur between the two streams and whether the two channels do come together at early levels of the visual pathway. We will also test our idea whether, of the dorsal and ventral streams, one stream might actually gate the other and decide what goes through the other stream. In fact, from our own recent studies, we have reason to believe that the way our attentional system might operate to select salient aspects of the visual scene may be through the dorsal stream selecting what goes into the ventral stream, which seems to be responsible for identifying objects. In the proposed project we will test this idea rigorously. From various lines of evidence, we also argue that the neural mechanisms that underlie this attentional spotlight is exploited by human children when they learn to read. It follows that any defect in the dorsal pathway or in the fibres and cells that feed into this will cause difficulties in reading. We believe this to be the underlying problem in dyslexic children. The project will undertake a number of experiments to test this idea.Read moreRead less
Electroretinogram Recordings Of Human Scotopic Dark Adaptation Following Intense Bleaching Exposures
Funder
National Health and Medical Research Council
Funding Amount
$272,250.00
Summary
After a human subject has been exposed to intense illumination, it can take many minutes for the eye to regain full sensitivity, as one experiences (for example) when entering a dark cave after being out on a bright sunny beach. This project will investigate the processes that occur in the cells of retina lining the back of the eye, that prevent the instantaneous recovery of vision following intense illumination. Electrical recordings will be made from the eyes of normal individuals, using new t ....After a human subject has been exposed to intense illumination, it can take many minutes for the eye to regain full sensitivity, as one experiences (for example) when entering a dark cave after being out on a bright sunny beach. This project will investigate the processes that occur in the cells of retina lining the back of the eye, that prevent the instantaneous recovery of vision following intense illumination. Electrical recordings will be made from the eyes of normal individuals, using new techniques that allow the activity of different types of nerve cell in the retina to be monitored. The study will determine how it is that events in the light-detector cells of the eye (the rod and cone photoreceptors) influence the activity of subsequent nerve cells in the visual system, and how these events contribute to the poor vision that one experiences following bright lights.Read moreRead less
Cortical Interactions Of Parallel Afferent Channels Underlying Visual Perception, Attention And Memory
Funder
National Health and Medical Research Council
Funding Amount
$410,250.00
Summary
The visual pathways from the eyes to the brain consist of distinct groups of cells which are specialised to signal different aspects of the visual scene such as colour, contrast and movement. As the information they carry is relayed through and processed in many different regions of the brain these parallel information channels were, until recently, believed to remain completely separate from each other. Furthermore, it had been proposed that as the information reaches the visual neocortex the i ....The visual pathways from the eyes to the brain consist of distinct groups of cells which are specialised to signal different aspects of the visual scene such as colour, contrast and movement. As the information they carry is relayed through and processed in many different regions of the brain these parallel information channels were, until recently, believed to remain completely separate from each other. Furthermore, it had been proposed that as the information reaches the visual neocortex the information is channeled through two main largely parallel information processing streams, a dorsal stream to the parietal cortex (a where system) and a ventral stream to the temporal cortex (a what system). However, our recent functional studies (and anatomical studies from other laboratories) have indicated that the different information channels do interact already at a relatively early level of the visual pathway, namely in the primary visual cortex. We have shown this in two ways: (1) there is convergence of different information channels on individual neurones in the primary visual cortex; (2) signals from the faster where pathway comes back to the primary visual cortex to gate the slower channels going into the ventral what pathway. We have seen this occur in an attention paradigm and in a memory task. We will explore these interactions further to test hypotheses about: (1) how the convergence of different information channels relate to the functional and anatomical architecture of the visual cortex; (2) investigate at length the most poorly understood, the so-called koniocellular pathway from the retina to the cortex. This pathway seems to contain a specialised component which carries information about blue objects; (3) identify the source of the spotlight of attention we have discovered and (4) how and from where early visual structures receive the gating inputs in certain memory tasks.Read moreRead less
The Signals Of Nerve Cells That Provide The Capacity For Sight
Funder
National Health and Medical Research Council
Funding Amount
$385,115.00
Summary
Sight relies on the signals of nerve cells in the brain, but we know little about the way in which nerve cells support this, or why in some people sight is diminished. In this work we will measure the signals of nerve cells in the visual pathway to gain knowledge of these processes: we will make measurements in normal animals and in those that suffer from brain disorders. Our work will provide a scientific basis for the diagnosis and treatment of these disorders.
The Mechanism Of Action Of Muscarinic Receptor Antagonists In Preventing Axial Myopia
Funder
National Health and Medical Research Council
Funding Amount
$242,545.00
Summary
Myopia (short-sightedness) is the most common refractive error and is due to the eye being too long and, if uncorrected, results in blurred distance vision. Approximately 30% of the population in developed countries, such as Australia, suffer from myopia. In a significant minority of individuals with high degrees of myopia, it is a sight threatening condition and a leading cause of blindness. It has been found that the pharmacological agent, atropine, is effective in preventing myopia in childre ....Myopia (short-sightedness) is the most common refractive error and is due to the eye being too long and, if uncorrected, results in blurred distance vision. Approximately 30% of the population in developed countries, such as Australia, suffer from myopia. In a significant minority of individuals with high degrees of myopia, it is a sight threatening condition and a leading cause of blindness. It has been found that the pharmacological agent, atropine, is effective in preventing myopia in children and in animal models of myopia. However the side effects of blurred vision at near, glare from dilated pupils and the unknown long term effects of chronic atropine treatment have prevented this approach to myopia control from becoming an established treatment in children. It was originally thought that the drug worked by preventing the eye from accommodating for near objects, however it has now been shown that atropine does not to work by this mechanism, but rather by another non-accommodative mechanism. The aim of this project is to determine the mechanism of action of this class of drugs (known as muscarinic antagonists) in preventing myopic eye growth. The project will investigate in which ocular tissues the various subtypes of muscarinic receptors sensitive to these drugs are located and how these are changed in myopic eyes. It will also determine the specific receptor subtype these drugs act on and whether these drugs inhibit eye growth in myopia by altered retinal signalling activity. The results from this study will elucidate the mechanism and route of action of muscarinic antagonists in preventing myopic eye growth. These findings will advance the probability of developing an effective selective muscarinic antagonist drug to use for the prevention of axial myopia without the side effects associated with the broad-band antagonist atropine. The development of such drugs will have a major economic benefit to the Australian population.Read moreRead less