Discovery Early Career Researcher Award - Grant ID: DE180100741
Funder
Australian Research Council
Funding Amount
$342,996.00
Summary
Harnessing neural plasticity with brain stimulation. This project aims to investigate the links between the molecular mechanisms underlying brain plasticity and the effects of non-invasive brain stimulation. It will use a novel approach that integrates genetics, electrophysiology and biological modelling. Plasticity underpins all learning, memory and aging. Brain stimulation can drive plasticity in humans, but these effects are extremely difficult to harness and vary widely between people. Expec ....Harnessing neural plasticity with brain stimulation. This project aims to investigate the links between the molecular mechanisms underlying brain plasticity and the effects of non-invasive brain stimulation. It will use a novel approach that integrates genetics, electrophysiology and biological modelling. Plasticity underpins all learning, memory and aging. Brain stimulation can drive plasticity in humans, but these effects are extremely difficult to harness and vary widely between people. Expected outcomes include a critical understanding of the fundamental mechanisms governing plasticity. This will provide significant benefits such as the development of individually optimised brain stimulation protocols, enabling tailored, reliable approaches to address brain function and cognition.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101102
Funder
Australian Research Council
Funding Amount
$378,536.00
Summary
Memory Engram Storage and Retrieval. This project aims to probe how long-term memory is stored in the brain. Recently, memory engram-labelling technology has revolutionised the way memory can be experimentally studied. It is now known that sparse populations of neurons that were active during a defined training window are both sufficient and necessary for retrieval of specific memories, and that activation of hippocampal engram causes further downstream activity in connected engram cells of othe ....Memory Engram Storage and Retrieval. This project aims to probe how long-term memory is stored in the brain. Recently, memory engram-labelling technology has revolutionised the way memory can be experimentally studied. It is now known that sparse populations of neurons that were active during a defined training window are both sufficient and necessary for retrieval of specific memories, and that activation of hippocampal engram causes further downstream activity in connected engram cells of other brain regions. However, it is unknown whether engram cell connectivity is important for memory function. The project aims to test this question. Understanding more about memory function in normal conditions may help us to understand and treat disorders of memory.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
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
Neural circuitry of maternal behaviour. Elaborate maternal care is a defining characteristic of mammalian species, suggesting conserved brain pathways evolved to orchestrate these responses. The neural substrates underscoring maternal behaviour have not been fully elucidated. This project aims to investigate the brain circuitry underpinning maternal care using a multidisciplinary approach combining behavioural assays and pharmacogenetic manipulations in mice alongside sophisticated molecular and ....Neural circuitry of maternal behaviour. Elaborate maternal care is a defining characteristic of mammalian species, suggesting conserved brain pathways evolved to orchestrate these responses. The neural substrates underscoring maternal behaviour have not been fully elucidated. This project aims to investigate the brain circuitry underpinning maternal care using a multidisciplinary approach combining behavioural assays and pharmacogenetic manipulations in mice alongside sophisticated molecular and functional analyses. The outcomes of this project are expected to improve our understanding of how specific brain pathways govern maternal behaviour. The novel insight gained is expected to advance theories regarding the organisation of maternal care and enable their practical testing.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100389
Funder
Australian Research Council
Funding Amount
$366,603.00
Summary
Effort for reward – neural processes underlying human motivation. This project aims to characterise the neurobiology of motivation by combining cutting-edge techniques in psychology, economics, computational modelling and neuroimaging. This project will provide novel mechanistic insights into the brain processes underlying motivation. It will form the basis for international collaborations that significantly advance the frontier field of decision neuroscience, and lay the foundation for future i ....Effort for reward – neural processes underlying human motivation. This project aims to characterise the neurobiology of motivation by combining cutting-edge techniques in psychology, economics, computational modelling and neuroimaging. This project will provide novel mechanistic insights into the brain processes underlying motivation. It will form the basis for international collaborations that significantly advance the frontier field of decision neuroscience, and lay the foundation for future interventions to improve motivation. The results from this project will therefore have wide-ranging translational implications for improving health and socioeconomic outcomes, including workplace productivity and quality of life.Read moreRead less
Circadian photoreceptor sensitivity and impacts of modern lighting on sleep. Light has powerful non-visual effects, including effects on sleep. These non-visual effects are mediated by cells in the eye that are most sensitive to blue light. There are large individual differences in sensitivity to non-visual effects of light that are not understood and that would give great insight into suboptimal sleep, which has become widespread in modern society. This study will be the first systematic examin ....Circadian photoreceptor sensitivity and impacts of modern lighting on sleep. Light has powerful non-visual effects, including effects on sleep. These non-visual effects are mediated by cells in the eye that are most sensitive to blue light. There are large individual differences in sensitivity to non-visual effects of light that are not understood and that would give great insight into suboptimal sleep, which has become widespread in modern society. This study will be the first systematic examination of individual differences in the effect of blue light on sleep and will uncover how alterations in the gene responsible for the effects of blue light on sleep (OPN4) contribute to these differences. This will lead to scalable individualised solutions to the unmet problem of how modern light environments impact sleep.Read moreRead less
Dissecting the Brain Circuitry Shaping Fear Regulation Across Development. Adolescence is an important time when individuals learn to manage stress-related emotions like fear. This project aims to understand how maturational changes in the prefrontal cortex of the brain hinder adolescents when learning to reduce reactivity to threats. It aims to do so by dissecting the brain circuitry shaping learning, memory, and emotional regulation across pre-adolescence, adolescence, and adulthood. The proje ....Dissecting the Brain Circuitry Shaping Fear Regulation Across Development. Adolescence is an important time when individuals learn to manage stress-related emotions like fear. This project aims to understand how maturational changes in the prefrontal cortex of the brain hinder adolescents when learning to reduce reactivity to threats. It aims to do so by dissecting the brain circuitry shaping learning, memory, and emotional regulation across pre-adolescence, adolescence, and adulthood. The project expects to generate new knowledge about why developmental changes in the brain are necessary for mature forms of learning and memory. The expected outcomes of this project include a significantly richer knowledge of the developing brain, which will ultimately inform approaches for improving emotion regulation in youth.Read moreRead less
Cognitive neuroscience of spatial asymmetry: behaviour, genes and brain imaging. When humans distribute their attention in space, biases or asymmetries of spatial attention exist. Healthy individuals exhibit a processing advantage favouring left space but this advantage is lost in disorders such as unilateral spatial neglect, ADHD and dyslexia. This project will develop novel electrophysiological methods to dissociate the sensory, attentional, decision-making and motoric contributions to spatial ....Cognitive neuroscience of spatial asymmetry: behaviour, genes and brain imaging. When humans distribute their attention in space, biases or asymmetries of spatial attention exist. Healthy individuals exhibit a processing advantage favouring left space but this advantage is lost in disorders such as unilateral spatial neglect, ADHD and dyslexia. This project will develop novel electrophysiological methods to dissociate the sensory, attentional, decision-making and motoric contributions to spatial asymmetries. By interfacing electrophysiology with genetic, neurochemical and brain imaging methods, this project will comprehensively map the biology of spatial asymmetry. This knowledge is vital to developing effective treatments for disorders where atypical patterns of spatial asymmetry index neurological vulnerability.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100588
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Gene-environment interactions in the regulation of neuroplasticity and cognitive function . This project will study the effects of different housing conditions on neuroplasticity-related cognitive function by combining an innovative operant conditioning behavioural test (computerised touch-screen technology) and new molecular approaches. Potential gene-environment interactions will be revealed using genetically targeted mice which have never been assessed in that context (mutants with altered gl ....Gene-environment interactions in the regulation of neuroplasticity and cognitive function . This project will study the effects of different housing conditions on neuroplasticity-related cognitive function by combining an innovative operant conditioning behavioural test (computerised touch-screen technology) and new molecular approaches. Potential gene-environment interactions will be revealed using genetically targeted mice which have never been assessed in that context (mutants with altered glucocorticoid and serotonin signalling). This project will study whether specific stages of the neuroplasticity process are differentially modulated through gene-environment interactions, ultimately resulting in changes to behaviour and cognitive functions. This will lead to a better understanding of the potential approaches that could be used to improve cognitive function.Read moreRead less