Chronic pain and functional impairment following traumatic injury: an investigation into the impact of compensation status and experience. This project will enhance understanding of the impact of the psychosocial factors and the compensation process on recovery from traumatic injury. The project will generate new resources (screening and referral guidelines; educational materials) to improve decision making consistency, client experience, and recovery from road trauma.
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
Real-time friction sensing, feedback and control for dexterous prosthetic and robotic manipulation. Prosthetic and robotic hands demonstrate poor dexterity during object manipulation, often dropping objects. Humans rarely allow objects to slip because we can sense when an object is slippery and adjust our grip. Exceptionally little research has been directed at replicating this ability to sense friction. This project aims to enable artificial hands to estimate frictional properties while graspin ....Real-time friction sensing, feedback and control for dexterous prosthetic and robotic manipulation. Prosthetic and robotic hands demonstrate poor dexterity during object manipulation, often dropping objects. Humans rarely allow objects to slip because we can sense when an object is slippery and adjust our grip. Exceptionally little research has been directed at replicating this ability to sense friction. This project aims to enable artificial hands to estimate frictional properties while grasping an object. Non-invasive methods to feed back this frictional information to an amputee will also be investigated. Finally, the friction-sensing system will be used to improve robotic gripper control. The outcomes of this research will significantly advance the fields of prosthetics, telesurgery, and service and manufacturing robotics.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
Spatiotemporal signatures of learning in brain reward systems. Learning to strengthen behaviours that secure resources and warrant survival is one of the primary functions of the brain. This Project seeks to establish the rules that govern the integration of learning in brain reward systems by studying how neuronal circuits change their molecular signatures as animals assimilate new knowledge. These studies will combine novel experimental designs to investigate learning with multidisciplinary me ....Spatiotemporal signatures of learning in brain reward systems. Learning to strengthen behaviours that secure resources and warrant survival is one of the primary functions of the brain. This Project seeks to establish the rules that govern the integration of learning in brain reward systems by studying how neuronal circuits change their molecular signatures as animals assimilate new knowledge. These studies will combine novel experimental designs to investigate learning with multidisciplinary methods for mapping, recording and functionalising teaching signals in behaving mice. The outcomes will create a significant shift in our understanding of the neural bases that underlie reward learning, and will critically expand the field by providing a new model of learning integration in brain systems.Read moreRead less
Mechanisms of memory integration in brain systems. Learning from our interactions with the environment is one of the brain’s most important functions, yet how and where this process takes place at the neural network level has proven difficult to establish. This Project seeks to investigate how major neuromodulatory signals in the brain coordinate the encoding of reward-based learning in large ensembles of neurons. These studies will combine novel behavioural paradigms with the most recent neuros ....Mechanisms of memory integration in brain systems. Learning from our interactions with the environment is one of the brain’s most important functions, yet how and where this process takes place at the neural network level has proven difficult to establish. This Project seeks to investigate how major neuromodulatory signals in the brain coordinate the encoding of reward-based learning in large ensembles of neurons. These studies will combine novel behavioural paradigms with the most recent neuroscience techniques for functional mapping and manipulation of specific neural circuits in behaving mice. The outcomes of this research will lead to a significant shift in our understanding of the mechanisms underpinning the integration of learning in brain systems and its implications for behaviour.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
Creating subject-specific mathematical models to understand the brain. This project aims to develop a mathematical framework that bridges the different scales of brain activities to provide a new tool for understanding the brain. Methods will be developed that unify individual neural activity with large scale brain activity. The approach will be validated by comparing predictions of interconnected models of neural populations (called mean-field models) to experimental data. The creation of subje ....Creating subject-specific mathematical models to understand the brain. This project aims to develop a mathematical framework that bridges the different scales of brain activities to provide a new tool for understanding the brain. Methods will be developed that unify individual neural activity with large scale brain activity. The approach will be validated by comparing predictions of interconnected models of neural populations (called mean-field models) to experimental data. The creation of subject-specific models from data is important, as there is large variability in neural circuits between individuals despite seemingly similar network activity. The intended outcome is new insights into the processes that govern brain function and methods for improving functional imaging of, and interfacing to, the brain.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
PET imaging of learning-related plasticity in awake behaving rats. The objective of the project is to combine an investigation of basic learning paradigms with functional Positron emission tomography (PET) imaging in rats in order to answer critical questions about the neurobiological basis of learning and decision-making in the brain. MicroPET technology provides PET images without the confounds induced by anaesthesia. Using this technology, the project intends to observe whole-brain changes in ....PET imaging of learning-related plasticity in awake behaving rats. The objective of the project is to combine an investigation of basic learning paradigms with functional Positron emission tomography (PET) imaging in rats in order to answer critical questions about the neurobiological basis of learning and decision-making in the brain. MicroPET technology provides PET images without the confounds induced by anaesthesia. Using this technology, the project intends to observe whole-brain changes in dopamine neurotransmission in awake, behaving rats while they learn to predict motivationally relevant outcomes based on environmental cues and on their own actions (ie during Pavlovian and instrumental conditioning, respectively). The outcomes of this research may improve our understanding of the neural changes responsible for debilitating disorders of the brain and mind.Read moreRead less