Cognitive and neural mechanisms underlying lateral biases in human vision. Under conditions of unconstrained viewing, humans show a consistent and reliable asymmetry in their perception of visual stimuli. This bias, which favours the left side, arises at a post-retinal level and is hypothesised to reflect hemispheric asymmetry in the control of visuospatial attention. This program of research investigates the mechanisms underlying lateral biases in visual perception, using the latest cognitive n ....Cognitive and neural mechanisms underlying lateral biases in human vision. Under conditions of unconstrained viewing, humans show a consistent and reliable asymmetry in their perception of visual stimuli. This bias, which favours the left side, arises at a post-retinal level and is hypothesised to reflect hemispheric asymmetry in the control of visuospatial attention. This program of research investigates the mechanisms underlying lateral biases in visual perception, using the latest cognitive neuroscience techniques. The findings will provide important new information about the neural and cognitive bases for normal and disordered visuospatial perception. The goal is to develop a novel test of perceptual asymmetries for use in normal participants and neurological patients.Read moreRead less
Attentional biases that underlie free-viewing perceptual asymmetries: Endogenous and exogenous effects in a behavioural/imaging study. As we move our eyes and attention around us, we are capable of interacting with any part of our immediate environment. It is intriguing, therefore, to discover that the upper and leftward features of an object are more salient than those on the bottom or right. By investigating the nature of these attentional biases in normal individuals, this research will impro ....Attentional biases that underlie free-viewing perceptual asymmetries: Endogenous and exogenous effects in a behavioural/imaging study. As we move our eyes and attention around us, we are capable of interacting with any part of our immediate environment. It is intriguing, therefore, to discover that the upper and leftward features of an object are more salient than those on the bottom or right. By investigating the nature of these attentional biases in normal individuals, this research will improve our understanding of the thought processes and brain structures that control spatial attention. This research has important implications for the development of remedial programs for patients with attentional disorders. The test we use to measure attentional asymmetries has the potential to become an important tool for the early detection of clinical abnormalities in attention.
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Left of centre: Attentional distortions in the mental representation of space in healthy and clinical populations. Stroke patients cost the Australian economy $1.3bn pa in addition to their social burden, but effective diagnosis and rehabilitation is impeded by a lack of fundamental research into the cognitive and neural mechanisms that underlie attentional disorders. Our research will provide significant new insights into how the brain deploys attention in external and imagined space and will l ....Left of centre: Attentional distortions in the mental representation of space in healthy and clinical populations. Stroke patients cost the Australian economy $1.3bn pa in addition to their social burden, but effective diagnosis and rehabilitation is impeded by a lack of fundamental research into the cognitive and neural mechanisms that underlie attentional disorders. Our research will provide significant new insights into how the brain deploys attention in external and imagined space and will lead to more effective management and treatment of stroke victims. Our new test of attentional disorders is independent of a patient's inability to see or move and will enable more effective diagnosis. Our research provides the fundamental knowledge base for our discipline and is vital for developing the next generation of Australia's cognitive neuroscientists. Read moreRead less
Special Research Initiatives - Grant ID: SR0354793
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
A Neural Network: Understanding Brain Function. This proposal focuses on the mechanisms that regulate brain function, particularly those underpinning the changes in circuitry (plasticity) caused by altered inputs. As such, its core goal is to create an interface between researchers in the neurosciences, computational modelling, robotics and cognitive sciences in order to facilitate optimum collaborative interactions, identify key research questions and promote training opportunities across a mul ....A Neural Network: Understanding Brain Function. This proposal focuses on the mechanisms that regulate brain function, particularly those underpinning the changes in circuitry (plasticity) caused by altered inputs. As such, its core goal is to create an interface between researchers in the neurosciences, computational modelling, robotics and cognitive sciences in order to facilitate optimum collaborative interactions, identify key research questions and promote training opportunities across a multidisciplinary spectrum. This will drive an integrated and accelerated program of discovery and technological development, enhancing Australia's leadership in this crucial field and helping to highlight new biotechnology opportunities and capture social and economic benefits for the nation. Read moreRead less
Recognition of rotated objects: paying attention to orientation. This research will increase our understanding of what aspects of an object contribute to our conscious visual experience and how the brain integrates information about various visual attributes. Eventually, this could be used in industry to develop more sophisticated computer pattern recognition systems. The research will also enable the design of better rehabilitation and management strategies for patients with brain damage and de ....Recognition of rotated objects: paying attention to orientation. This research will increase our understanding of what aspects of an object contribute to our conscious visual experience and how the brain integrates information about various visual attributes. Eventually, this could be used in industry to develop more sophisticated computer pattern recognition systems. The research will also enable the design of better rehabilitation and management strategies for patients with brain damage and degenerative brain disorders, such as Alzheimer's disease.Read moreRead less
Mobile computation in human perception and feature binding. Perception is so complex that still we cannot give computers more than a fraction of the human ability to perceive things. Experiments with humans can unravel the computations that underlie human abilities. Here we focus on distinguishing between perceptual mechanisms that analyze information from only patches of the visual world and those that combine information from across the visual field as an object moves across it. Results should ....Mobile computation in human perception and feature binding. Perception is so complex that still we cannot give computers more than a fraction of the human ability to perceive things. Experiments with humans can unravel the computations that underlie human abilities. Here we focus on distinguishing between perceptual mechanisms that analyze information from only patches of the visual world and those that combine information from across the visual field as an object moves across it. Results should also help to understand the general issue of how the brain combines information from different groups of neurons. Australian understanding of brains should be advanced, benefiting neuroscience, medicine, and eventually computer science.Read moreRead less
Intracortical inhibition evaluated by paired-pulse TMS during choice and simple reaction time tasks. The research will investigate the neurophysiological processes responsible for the selection and initiation of movement in response to an external stimulus. Slowness in the initiation and execution of movement is a common feature of 'neurological aging', neurodegenerative disease, and brain injury. Understanding the brain mechanisms involved in response selection and movement initiation will pro ....Intracortical inhibition evaluated by paired-pulse TMS during choice and simple reaction time tasks. The research will investigate the neurophysiological processes responsible for the selection and initiation of movement in response to an external stimulus. Slowness in the initiation and execution of movement is a common feature of 'neurological aging', neurodegenerative disease, and brain injury. Understanding the brain mechanisms involved in response selection and movement initiation will provide information for the development of specific intervention techniques to improve motor function in these groups.Read moreRead less
Presynaptic mechanisms of general anaesthesia in the fly brain. General anaesthesia is a routine procedure for both human and veterinary surgery and for any experimental paradigms requiring immobilization of animals. By abolishing consciousness, these drugs provide practitioners with an ideal way of manipulating subjects under conditions when responsiveness might be undesirable. Understanding how manipulating synaptic release mechanisms might modulate anaesthetic potency will be valuable for eve ....Presynaptic mechanisms of general anaesthesia in the fly brain. General anaesthesia is a routine procedure for both human and veterinary surgery and for any experimental paradigms requiring immobilization of animals. By abolishing consciousness, these drugs provide practitioners with an ideal way of manipulating subjects under conditions when responsiveness might be undesirable. Understanding how manipulating synaptic release mechanisms might modulate anaesthetic potency will be valuable for eventually being able to better control the anaesthetized state in human and animal subjects. By understanding general anaesthesia across multiple levels of brain function, we will at the same time be answering fundamental questions pertaining to mechanisms of perception and awareness. Read moreRead less
Neural mechanisms underlying interlateral transfer of ballistic motor skill. This project seeks to discover why practicing a task with one limb can improve performance with the corresponding limb (which does no physical work) on the opposite side of the body. Identifying the changes in the brain that cause acquisition of skill without direct training is crucial to determine whether the effect might be exploited to improve rehabilitation outcomes for movement disorders that chiefly affect one sid ....Neural mechanisms underlying interlateral transfer of ballistic motor skill. This project seeks to discover why practicing a task with one limb can improve performance with the corresponding limb (which does no physical work) on the opposite side of the body. Identifying the changes in the brain that cause acquisition of skill without direct training is crucial to determine whether the effect might be exploited to improve rehabilitation outcomes for movement disorders that chiefly affect one side of the body (e.g. after a stroke). The research will provide basic information that might lead to new treatment approaches that help to minimize the social cost of the persistent and severe movement difficulties experienced by many patients after neurological injury.Read moreRead less
The role of the Supplementary Motor Area in time processing. The neural bases of timing mechanisms (0.1-100s range) are the subject of much debate. We hypothesise that the Supplementary Motor Area (SMA), a major cortical structure involving important dopaminergic pathways, subtends duration encoding, in the way depicted by the 'accumulator model'. Using transcranial magnetic stimulation (TMS) over the SMA, we will test healthy subjects in motor and perceptual timing tasks, compared to Parkinson' ....The role of the Supplementary Motor Area in time processing. The neural bases of timing mechanisms (0.1-100s range) are the subject of much debate. We hypothesise that the Supplementary Motor Area (SMA), a major cortical structure involving important dopaminergic pathways, subtends duration encoding, in the way depicted by the 'accumulator model'. Using transcranial magnetic stimulation (TMS) over the SMA, we will test healthy subjects in motor and perceptual timing tasks, compared to Parkinson's disease patients whose timing performance is impaired due to dopaminergic dysfunction. We expect TMS inhibitory effects to induce predictable performance trends, providing support for the accumulator model and the key role of the SMA in timing.Read moreRead less