How brain oscillations influence our behaviour. This project aims to reveal how sudden, intense stimuli impair or facilitate concurrent actions. Startling sounds can disrupt the execution of movements and distract attention from vital events in the environment, with potential disastrous consequences when handling complex equipment such as airplanes, cars and trucks, or surgical instruments. This project will combine classic experimental and novel neuro-modulatory techniques with the measurement ....How brain oscillations influence our behaviour. This project aims to reveal how sudden, intense stimuli impair or facilitate concurrent actions. Startling sounds can disrupt the execution of movements and distract attention from vital events in the environment, with potential disastrous consequences when handling complex equipment such as airplanes, cars and trucks, or surgical instruments. This project will combine classic experimental and novel neuro-modulatory techniques with the measurement of oscillatory brain activity. Expect outcomes will inform theories of cognitive function and the design of interventions to reduce the negative effects of sudden, distracting events.Read moreRead less
Ageing drivers: Cognitive ageing and technology. This project aims to enhance our understanding of whether cognitive changes associated with ageing impacts older drivers' use of emerging vehicle automation and assistive technologies. Through analysis of insurance claims databases, a large consumer survey and a naturalistic driving study, evidence will be obtained on how ageing and cognition interact with assistive technology. Findings will inform older drivers, government policy makers and indus ....Ageing drivers: Cognitive ageing and technology. This project aims to enhance our understanding of whether cognitive changes associated with ageing impacts older drivers' use of emerging vehicle automation and assistive technologies. Through analysis of insurance claims databases, a large consumer survey and a naturalistic driving study, evidence will be obtained on how ageing and cognition interact with assistive technology. Findings will inform older drivers, government policy makers and industry on ageing, cognitive changes and the use of assistive technology in vehicles. This will provide benefits for older drivers by promoting optimal driving which will enhance social engagement as well as safety. Read moreRead less
Motor control of the upper airway muscle genioglossus. This project aims to evaluate a recent proposal about the motor control of the upper airway muscle Genioglossus. The upper airway muscles, the most complex in the human body, are critical for breathing and speaking, but are not well understood. Genioglossus draws the base of the tongue forward to maintain airway patency. This project will study genioglossus during wakefulness and sleep in normal healthy individuals. It is anticipated that th ....Motor control of the upper airway muscle genioglossus. This project aims to evaluate a recent proposal about the motor control of the upper airway muscle Genioglossus. The upper airway muscles, the most complex in the human body, are critical for breathing and speaking, but are not well understood. Genioglossus draws the base of the tongue forward to maintain airway patency. This project will study genioglossus during wakefulness and sleep in normal healthy individuals. It is anticipated that the project will suggest improved avenues for treatment of sleep related respiratory disorders.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100694
Funder
Australian Research Council
Funding Amount
$372,014.00
Summary
Does disconnection in the aging brain cause age-related movement decline? This project aims to use new neurophysiological approaches to understand the causal role of age-related changes in brain network connectivity to the movement control. Brain regions interact through complex and dynamic neural networks to control voluntary movement, but whether age-related changes in network connectivity drive age-related decline in movement control is unknown. This project will provide significant benefits ....Does disconnection in the aging brain cause age-related movement decline? This project aims to use new neurophysiological approaches to understand the causal role of age-related changes in brain network connectivity to the movement control. Brain regions interact through complex and dynamic neural networks to control voluntary movement, but whether age-related changes in network connectivity drive age-related decline in movement control is unknown. This project will provide significant benefits such as the neurophysiological knowledge required to develop targeted interventions to improve movement control in the aging population.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100575
Funder
Australian Research Council
Funding Amount
$423,604.00
Summary
Does neuroplasticity protect against late life cognitive impairment? This project aims to investigate neuroplasticity across the adult lifespan, using novel neurophysiological approaches to determine its role in protecting against age-related cognitive decline. This project expects to generate new knowledge in the area of human cognitive ageing, using an innovative and interdisciplinary approach. Expected outcomes of this project include a critical understanding of the basic neural mechanisms of ....Does neuroplasticity protect against late life cognitive impairment? This project aims to investigate neuroplasticity across the adult lifespan, using novel neurophysiological approaches to determine its role in protecting against age-related cognitive decline. This project expects to generate new knowledge in the area of human cognitive ageing, using an innovative and interdisciplinary approach. Expected outcomes of this project include a critical understanding of the basic neural mechanisms of healthy brain ageing. This will provide significant benefits, such as the neurophysiological knowledge required to develop novel biological markers to detect, as well as therapeutic agents to curb, cognitive decline in the aging population.Read moreRead less
Understanding working memory: from cells to brain stimulation. This project aims to understand the neural mechanisms of working memory, a fundamental cognitive function in humans, using a novel framework which combines non-invasive brain stimulation, neuroimaging, pharmacological and experimental manipulations, and biological modelling. Expected outcomes include a critical understanding of the cellular mechanisms underlying both neural activity and working memory ability in healthy individuals a ....Understanding working memory: from cells to brain stimulation. This project aims to understand the neural mechanisms of working memory, a fundamental cognitive function in humans, using a novel framework which combines non-invasive brain stimulation, neuroimaging, pharmacological and experimental manipulations, and biological modelling. Expected outcomes include a critical understanding of the cellular mechanisms underlying both neural activity and working memory ability in healthy individuals and a detailed knowledge of how to non-invasively interact with these mechanisms using brain stimulation. This will provide significant benefits such as the development of individually optimised brain stimulation protocols, enabling tailored approaches to reliably alter brain function and cognition.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101708
Funder
Australian Research Council
Funding Amount
$406,821.00
Summary
New directions for using brain stimulation to understand brain function. Neuroplasticity is of fundamental importance to brain function as it mediates learning, memory and development. Deficits in neuroplasticity are observed in a number of neurological conditions and thought to contribute to cognitive dysfunction. This study is designed to develop a better understanding of the neurochemical and genetic factors impacting on neuroplasticity. In addition, it aims to (i) upregulate brain connectivi ....New directions for using brain stimulation to understand brain function. Neuroplasticity is of fundamental importance to brain function as it mediates learning, memory and development. Deficits in neuroplasticity are observed in a number of neurological conditions and thought to contribute to cognitive dysfunction. This study is designed to develop a better understanding of the neurochemical and genetic factors impacting on neuroplasticity. In addition, it aims to (i) upregulate brain connectivity in a precise and targeted manner, (ii) elicit functional increases in cognitive performance and (iii) demonstrate the relationship between functional connectivity and cognition. Outcomes include a better understanding of plasticity in the brain & a enhanced capacity to examine and modulate brain plasticity.Read moreRead less
Human hippocampus subregions organisation and associative memory processes. This proposal will investigate the hippocampus, a highly inter-connected structure containing many subregions. Although considered the memory centre of the brain, we still do not know the exact roles of these subregions during memory processes. Using novel brain neuroimaging acquisition methods and analyses, this project aims to map the internal structure and functions of the hippocampus and its functional networks under ....Human hippocampus subregions organisation and associative memory processes. This proposal will investigate the hippocampus, a highly inter-connected structure containing many subregions. Although considered the memory centre of the brain, we still do not know the exact roles of these subregions during memory processes. Using novel brain neuroimaging acquisition methods and analyses, this project aims to map the internal structure and functions of the hippocampus and its functional networks under different memory conditions and how these functions change with age. The intended outcome of this proposal is to provide the foundations for the first integrated model of human memory and its biological basis and to generate a benchmark against which future development of memory interventions and retraining can be measured.Read moreRead less
Charting age-related changes in the quality of episodic memory. As we get older, our capacity to remember events in rich detail becomes less efficient. The mechanisms driving these changes remain unclear, severely limiting our capacity to accurately assess and optimise memory function in later years. This project aims to determine how memory accuracy and memory quality change across the adult lifespan using cutting-edge experimental and neuroimaging techniques. It will deliver new insights into ....Charting age-related changes in the quality of episodic memory. As we get older, our capacity to remember events in rich detail becomes less efficient. The mechanisms driving these changes remain unclear, severely limiting our capacity to accurately assess and optimise memory function in later years. This project aims to determine how memory accuracy and memory quality change across the adult lifespan using cutting-edge experimental and neuroimaging techniques. It will deliver new insights into the relationship between confidence, memory success and memory quality, and the underlying neural substrates of these processes. This work will provide the essential empirical foundation to augment memory function, ensuring that older adults can continue to participate as active members of society.Read moreRead less
Individualised predictions of circadian timing, sleep, and performance. The body's 24-hour clock regulates when we feel sleepy or alert. In shift workers, disrupted sleep and rhythms leads to fatigue and costly, often deadly, workplace accidents. Existing methods for measuring body clock timing are costly, impractical for operational settings, and do not work in real time. Using a shift-worker population, this project will develop models that accurately predict body timing, sleep/wake patterns, ....Individualised predictions of circadian timing, sleep, and performance. The body's 24-hour clock regulates when we feel sleepy or alert. In shift workers, disrupted sleep and rhythms leads to fatigue and costly, often deadly, workplace accidents. Existing methods for measuring body clock timing are costly, impractical for operational settings, and do not work in real time. Using a shift-worker population, this project will develop models that accurately predict body timing, sleep/wake patterns, and performance for an individual, requiring only a simple activity/light sensor and an assessment of the body clock's sensitivity to light. The new model would revolutionise fatigue management and make safer work environments for millions of shift workers. Read moreRead less