A new theory for retinotectal map formation. How brains become wired up during development is a question of
importance to both biology and computing. In this project we adopt a
novel computational approach to understanding the development of
topographic maps, a wiring pattern that is ubiquitous in biological
nervous systems. This project will build capacity for research in
computational neuroscience in Australia. It may also lead to
technological benefits such as new ideas for the design o ....A new theory for retinotectal map formation. How brains become wired up during development is a question of
importance to both biology and computing. In this project we adopt a
novel computational approach to understanding the development of
topographic maps, a wiring pattern that is ubiquitous in biological
nervous systems. This project will build capacity for research in
computational neuroscience in Australia. It may also lead to
technological benefits such as new ideas for the design of self-wiring
computing devices, and new insights into
the causes of wiring defects both during normal development and
rewiring after injury.
Read moreRead less
Temporal interactions of dorsal/ventral visual streams. This project aims to understand the temporal interactions between the dorsal and ventral visual streams that control skilled actions. The neural pathways for visual perception of objects may be distinct from those associated with movements towards the object, but the speed of activation and interactions of these two cortical visual streams have not been investigated. This project will use the temporal sensitivity of neuroscience brain imagi ....Temporal interactions of dorsal/ventral visual streams. This project aims to understand the temporal interactions between the dorsal and ventral visual streams that control skilled actions. The neural pathways for visual perception of objects may be distinct from those associated with movements towards the object, but the speed of activation and interactions of these two cortical visual streams have not been investigated. This project will use the temporal sensitivity of neuroscience brain imaging techniques (MEG, EEG, fMRI) to measure the real-time sequence of interactions between the two visual streams during goal-directed grasping. It intends to extend the most influential model of visual processing by discovering ‘when’ these pathways activate and interact. Such knowledge will affect delivery of social and commercial outcomes, by providing new directions for the rehabilitation of sensorimotor performance in many neurodevelopmental disorders, and by improving design of control systems for robotic effectors, prosthetic limbs, and more seamless human-machine interfaces.Read moreRead less
Control of cellular differentiation in the developing brain. This project aims to understand how mature brain cells form during foetal life. The central hypothesis is that a specific transcription factor family, called NFI, regulates the epigenetic state of the cell, allowing chromatin accessibility and subsequent transcriptional activation and repression to control cellular differentiation. Aims 1 and 2 will investigate how brain cells transition from proliferating progenitor cells to different ....Control of cellular differentiation in the developing brain. This project aims to understand how mature brain cells form during foetal life. The central hypothesis is that a specific transcription factor family, called NFI, regulates the epigenetic state of the cell, allowing chromatin accessibility and subsequent transcriptional activation and repression to control cellular differentiation. Aims 1 and 2 will investigate how brain cells transition from proliferating progenitor cells to differentiated mature cell types. Aim 3 will investigate how differentiation is maintained in the adult brain. Methods used involve genome and chromatin analyses of cells isolated from transgenic mouse models. Outcomes and benefits are substantial knowledge gain applicable to stem cell regulation and brain health.Read moreRead less
Brain connectome: from synapse, large-scale network to behaviour. This project aims to investigate how behaviour shapes the large-scale network synchrony by determination of task-specific networks using whole-brain resting-state functional Magnetic Resonance Imaging (MRI) and its relationship with synaptic plasticity. Enhanced synaptic connectivity has been suggested as a mechanism of memory but the system-level circuit dynamics in memory process are not clear. The outcome is anticipated to brid ....Brain connectome: from synapse, large-scale network to behaviour. This project aims to investigate how behaviour shapes the large-scale network synchrony by determination of task-specific networks using whole-brain resting-state functional Magnetic Resonance Imaging (MRI) and its relationship with synaptic plasticity. Enhanced synaptic connectivity has been suggested as a mechanism of memory but the system-level circuit dynamics in memory process are not clear. The outcome is anticipated to bridge the knowledge gap between brain and behaviour.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100778
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
Mapping the neural circuits that underlie emotional learning. This project aims to understand the precise neural circuits that mediate the formation of emotional memories. Recent findings have identified a novel complexity in these circuits and the goal of this proposal is to resolve the underlying mechanism that drives emotional memories. In detail, this project will combine state of the art dual- optical stimulation techniques combined with behaviour-dependent tagging of neurons to investigate ....Mapping the neural circuits that underlie emotional learning. This project aims to understand the precise neural circuits that mediate the formation of emotional memories. Recent findings have identified a novel complexity in these circuits and the goal of this proposal is to resolve the underlying mechanism that drives emotional memories. In detail, this project will combine state of the art dual- optical stimulation techniques combined with behaviour-dependent tagging of neurons to investigate the precise brain circuits linked to emotional learning, an approach that also allows knowledge transfer to other research fields. Expected outcomes and benefits of the project is a significant shift in our understanding of the neural mechanisms that underlie emotional learning.Read moreRead less
Old brain cells perform new tricks to allow life-long learning. In the brain, nerve cells transmit electrical signals more quickly and reliably when they are insulated. The insulating cells undergo small adaptive changes that speed up information transfer during learning, and the faster the electrical signal, the better the learning outcomes. This project aims to understand the signals that direct insulating cells to adapt and support life-long learning. In the longer term, this knowledge may be ....Old brain cells perform new tricks to allow life-long learning. In the brain, nerve cells transmit electrical signals more quickly and reliably when they are insulated. The insulating cells undergo small adaptive changes that speed up information transfer during learning, and the faster the electrical signal, the better the learning outcomes. This project aims to understand the signals that direct insulating cells to adapt and support life-long learning. In the longer term, this knowledge may be used to: develop interventions that improve learning and educational outcomes; counteract age-related memory decline and enable longer work force participation; develop strategies to circumvent the memory loss caused by brain diseases, or improve the design of computer hardware.Read moreRead less
Molecular control of adult neural stem cell quiescence. The objective of this project is to improve our understanding of adult neural stem cell biology and function. Within the central nervous system of the brain, neural stem cells persist throughout adult life. These cells continually produce new neurons that are pivotal for processes including learning and memory, and deficits in adult neurogenesis have been linked to age-related cognitive decline. Adult neural stem cells are predominantly qui ....Molecular control of adult neural stem cell quiescence. The objective of this project is to improve our understanding of adult neural stem cell biology and function. Within the central nervous system of the brain, neural stem cells persist throughout adult life. These cells continually produce new neurons that are pivotal for processes including learning and memory, and deficits in adult neurogenesis have been linked to age-related cognitive decline. Adult neural stem cells are predominantly quiescent, dividing rarely to ensure that they are not prematurely exhausted. However, the factors that maintain this quiescence are very poorly defined. The project aims to understand how stem cell quiescence is controlled at both a molecular and cellular level in vivo within the adult mouse brain.Read moreRead less
Transcriptional regulation of brain size during development. This project aims to understand the fundamental mechanisms through which intermediate progenitor cell (IPC) formation is regulated within the cerebral cortex. The cerebral cortex plays a key role in functions central to our existence, including emotion, behaviour, learning and memory. During development, cortical neural stem cells produce neurons via IPCs. This project expects to discover the genetic programs regulating neuronal produc ....Transcriptional regulation of brain size during development. This project aims to understand the fundamental mechanisms through which intermediate progenitor cell (IPC) formation is regulated within the cerebral cortex. The cerebral cortex plays a key role in functions central to our existence, including emotion, behaviour, learning and memory. During development, cortical neural stem cells produce neurons via IPCs. This project expects to discover the genetic programs regulating neuronal production, providing significant conceptual advances in this key field. This will provide significant benefits, such as enhancing our understanding of how overall brain size is regulated during development.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101578
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
How does neurogenesis in the adult hippocampus influence learning & memory? One of the primary brain structures critical for learning and memory in animals and humans is the hippocampus, where regulated production of new neurons throughout life (i.e. adult neurogenesis) underpins these cognitive functions. The project aims to unravel how adult-born neurons exert their influence over behaviour by determining when newly born neurons become critical for behaviour and the connections made by these c ....How does neurogenesis in the adult hippocampus influence learning & memory? One of the primary brain structures critical for learning and memory in animals and humans is the hippocampus, where regulated production of new neurons throughout life (i.e. adult neurogenesis) underpins these cognitive functions. The project aims to unravel how adult-born neurons exert their influence over behaviour by determining when newly born neurons become critical for behaviour and the connections made by these cells within the hippocampal network. It aims to provide fundamental new insight into the stages at which these neurons are important for the acquisition of spatial task versus the recall of spatial tasks.Read moreRead less
Early formation of the preplate establishes the cerebral cortex. The cerebral cortex is arguably the most complex area of the brain due to its ability to process and integrate a wide variety of information in a seamless manner. To understand how this occurs, it is essential to understand how the cerebral cortex is built during embryonic life. The focus of this project is on the formation of the very earliest neurons of the cortex, called preplate neurons. This project aims to: test a new model f ....Early formation of the preplate establishes the cerebral cortex. The cerebral cortex is arguably the most complex area of the brain due to its ability to process and integrate a wide variety of information in a seamless manner. To understand how this occurs, it is essential to understand how the cerebral cortex is built during embryonic life. The focus of this project is on the formation of the very earliest neurons of the cortex, called preplate neurons. This project aims to: test a new model for preplate development with regards to their origin; their function in formation of the cerebral cortex; and the the molecular mechanisms underlying their development. This work provides a developmental framework for understanding how the cerebral cortex is established.Read moreRead less