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
Testing the ghost with the machine: Empirical investigations of cognition using high-field functional magnetic resonance imaging. The primary aim of the project is to test hypotheses about the cognitive architecture of word production and negative priming using high-field functional magnetic resonance imaging (fMRI). Additional aims/outcomes are to apply a novel fMRI acquisition sequence that permits overt verbal responding with rapid presentation of trials and collection of the time course of t ....Testing the ghost with the machine: Empirical investigations of cognition using high-field functional magnetic resonance imaging. The primary aim of the project is to test hypotheses about the cognitive architecture of word production and negative priming using high-field functional magnetic resonance imaging (fMRI). Additional aims/outcomes are to apply a novel fMRI acquisition sequence that permits overt verbal responding with rapid presentation of trials and collection of the time course of the blood oxygen level dependent (BOLD) signal, and to further develop a methodology that delineates the logic of making inferences about cognitive systems from functional neuroimaging data. These represent potentially significant developments in the fields of cognitive neuroscience and functional neuroimaging.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
Testing posterior parietal cortex contributions to human episodic memory. This project aims to determine the involvement of parietal brain regions for episodic memory. Using novel experimental tasks and multimodal neuroimaging techniques in young and healthy aging, this project expects to clarify the role of posterior parietal structures, and their interactions with core memory structures, during memory retrieval. Expected outcomes include advanced understanding of how we remember the past in ri ....Testing posterior parietal cortex contributions to human episodic memory. This project aims to determine the involvement of parietal brain regions for episodic memory. Using novel experimental tasks and multimodal neuroimaging techniques in young and healthy aging, this project expects to clarify the role of posterior parietal structures, and their interactions with core memory structures, during memory retrieval. Expected outcomes include advanced understanding of how we remember the past in rich contextual detail, and how such processes are altered in healthy aging. This potentially provides significant benefits in predicting and treating memory dysfunction due to brain injury or neurodegeneration.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101275
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Contribution of basal ganglia networks to the fine-tuning of action. This project aims to identify the changes occurring in specific brain circuits when new behaviours are learned. Our ability to perform efficient goal-directed actions involves a learning process in which separate movements are organised into sequences of action. This project aims to determine how this is encoded in the brain by mapping basal ganglia networks that are directly engaged during different stages of learning. This pr ....Contribution of basal ganglia networks to the fine-tuning of action. This project aims to identify the changes occurring in specific brain circuits when new behaviours are learned. Our ability to perform efficient goal-directed actions involves a learning process in which separate movements are organised into sequences of action. This project aims to determine how this is encoded in the brain by mapping basal ganglia networks that are directly engaged during different stages of learning. This project also seeks to identify specific neural circuits that are important for the refinement of action. The knowledge developed in this project is expected to support the development of training programs to instruct individuals in specialised tasks and may be used in the design of biologically inspired robots.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
A longitudinal study of neuropsychological and neuromotor effects of low level manganese exposure. This study will investigate the neuropsychological and neuromotor effects of low level exposure to mangenese particulate. Previous studies have indicated symptomology of high level exposure, but there is contention in the literature regarding the effects of low levels of exposure. Our aim is to refine measures of cumulative exposure and develop a more comprehensive and senstitive testing protocol t ....A longitudinal study of neuropsychological and neuromotor effects of low level manganese exposure. This study will investigate the neuropsychological and neuromotor effects of low level exposure to mangenese particulate. Previous studies have indicated symptomology of high level exposure, but there is contention in the literature regarding the effects of low levels of exposure. Our aim is to refine measures of cumulative exposure and develop a more comprehensive and senstitive testing protocol than has been reported thus far. These measures and protocols will be incorporated into a longitudinal design, which has not been conducted in research studies to date. In addition, a database of exposure variables will be developed to facilitate long-term, accurate research into the effects of the low levels of exposure.Read moreRead less
Role of shifting thalamostriatal networks in action refinement. This project aims to determine the changes occurring in specific brain circuits when automatic behaviours are established. Ability to acquire new skills depends on the dynamic reorganisation of particular neural networks across brain territories throughout training. This project seeks to investigate how the thalamus-to-striatum pathway, a neural circuit that is central to motor control, progressively adjusts its activity as animals ....Role of shifting thalamostriatal networks in action refinement. This project aims to determine the changes occurring in specific brain circuits when automatic behaviours are established. Ability to acquire new skills depends on the dynamic reorganisation of particular neural networks across brain territories throughout training. This project seeks to investigate how the thalamus-to-striatum pathway, a neural circuit that is central to motor control, progressively adjusts its activity as animals automatise their actions. The project will combine behavioural designs with the latest neuroscience techniques for tracing, functional mapping and manipulation of specific neural circuits in behaving mice. The outcomes of this project will lead to a better understanding of the mechanisms underpinning the refinement of action at the systems level, which is critical for performance and professional dexterity.Read moreRead less
The genetic basis of human memory. This project will examine the relationship between genetic variation and performance of normal individuals on a comprehensive range of memory test indicators. Results of the study will clarify the genetic basis of human memory and provide a better understanding of this important function.
Neural metrics for space time and numerosity. What we propose is ground-breaking research. It will increase Australia's international competitiveness is science, expand the knowledge base of brain function and psychology and provide valuable training for research scientists.