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Special Research Initiatives - Grant ID: SR120200004
Funder
Australian Research Council
Funding Amount
$30,000,000.00
Summary
Australian Synchrotron Access Program. The Australian Synchrotron epitomises scientific research excellence in Australian and New Zealand. Its impact spans nearly every research sector. This proposal brings together over 30 Australian universities working together to ensure that world-class peer-reviewed science continues to be performed at the Australian Synchrotron.
Spatiotemporal dynamics and analysis of functional magnetic resonance imaging. Functional magnetic resonance imaging (fMRI) produces signals generated by brain activity in fine detail, but links between activity and images are poorly understood, posing a barrier to full use of the technology. Predictions from our new theory of such links will be made, tested experimentally and used to improve fMRI and discover new phenomena.
Engineering an artificial protein molecular motor. This project aims to use non-motor protein building blocks to construct an artificial protein motor. Nature already uses nanotechnology as the basis for all its machinery, and uses proteins to construct machines. Each protein component in the motor will have a well-understood function; this artificial protein will elucidate how it converts chemical energy to motion. This process is not understood as molecular motors do not obey the same principl ....Engineering an artificial protein molecular motor. This project aims to use non-motor protein building blocks to construct an artificial protein motor. Nature already uses nanotechnology as the basis for all its machinery, and uses proteins to construct machines. Each protein component in the motor will have a well-understood function; this artificial protein will elucidate how it converts chemical energy to motion. This process is not understood as molecular motors do not obey the same principles as macroscopic machines. Comparing the artificial motor with biological motors will provide insight into the workings of natural motors. This project should lead to molecular motors for nanobiotechnology.Read moreRead less
Visualising chaperones disentangle and refold proteins - one molecule at a time. Chaperones are enzymes that maintain the proper function of proteins in the cell. This research aims to visualise, at the single molecule level, how chaperones facilitate the folding of individual proteins and how they can disentangle proteins that have aggregated as a result of cell stress.
Australian Laureate Fellowships - Grant ID: FL140100025
Funder
Australian Research Council
Funding Amount
$2,617,462.00
Summary
The physical brain: emergent, multiscale, nonlinear, and critical dynamics. The physical brain: emergent, multiscale, nonlinear, and critical dynamics. This project aims to transform the understanding of the structure and function of the brain as a complex physical system. It aims to reveal and unify new aspects of information processing, transitions in conscious state, and nonlinear brain interactions by translating and applying concepts and methods from physics and mathematics. It will treat b ....The physical brain: emergent, multiscale, nonlinear, and critical dynamics. The physical brain: emergent, multiscale, nonlinear, and critical dynamics. This project aims to transform the understanding of the structure and function of the brain as a complex physical system. It aims to reveal and unify new aspects of information processing, transitions in conscious state, and nonlinear brain interactions by translating and applying concepts and methods from physics and mathematics. It will treat brain structure and dynamics together to address emergent phenomena like waves and patterns on multiple scales, treating waves as equal participants alongside neurons. Innovative predictions of brain phenomena will aim to be verified against data and used to understand brain networks, dynamics, and the physical phenomena underlying information processing and consciousness.Read moreRead less
Light on a nanoscale: channelling energy through space and time to control neuronal activity. Quantum-mechanical effects of energy transfer and resonance will be harnessed to yield ultrabright nanoscale light sources. Research will unveil the intricate interplay between energy harvesting, transferring and emitting centres designed so that the flow of energy exhibits a directed character. This focussed intense energy will produce abundant visible photons from infrared light. Genetically engineere ....Light on a nanoscale: channelling energy through space and time to control neuronal activity. Quantum-mechanical effects of energy transfer and resonance will be harnessed to yield ultrabright nanoscale light sources. Research will unveil the intricate interplay between energy harvesting, transferring and emitting centres designed so that the flow of energy exhibits a directed character. This focussed intense energy will produce abundant visible photons from infrared light. Genetically engineered cells able to be stimulated optically by using an optogenetics method will be illuminated by our nanoscale light causing modulation of cell activity. This new capability will enable remote control of neuronal activity in specific circuits within the nervous system without the limitation of surgically inserted optical fibres.Read moreRead less
Probing Anaesthetic Effects with New Functional Imaging Paradigms. This project seeks new insights into the effects of anaesthetics on brain function and repair. Anaesthesia is used in small-animal imaging to immobilise the animal, but in many cases the anaesthesia itself affects the neurophysiological parameters under study. It has also been shown that many anaesthetics enhance recovery after brain injury in small animals. This project plans to exploit a novel functional brain-imaging technique ....Probing Anaesthetic Effects with New Functional Imaging Paradigms. This project seeks new insights into the effects of anaesthetics on brain function and repair. Anaesthesia is used in small-animal imaging to immobilise the animal, but in many cases the anaesthesia itself affects the neurophysiological parameters under study. It has also been shown that many anaesthetics enhance recovery after brain injury in small animals. This project plans to exploit a novel functional brain-imaging technique for conscious animals to gain new insights into the effects of anaesthetics on brain function and recovery from injury. The knowledge gained is expected to improve knowledge of anaesthetic action, guide future anaesthetic use in small animal imaging to improve the accuracy of image-derived research data, and help to clarify how anaesthetics confer neuroprotective effects in brain injury.Read moreRead less
Proteotyping for the rapid identification of pandemic influenza. Future influenza pandemics will develop more rapidly providing a relatively short window with which to survey and assess the nature of the virus and administer effective treatments. Application of a new proteotyping approach will allow strains of pandemic potential to be characterised more directly and rapidly than current surveillance methods.
Dynamics of droplets and nanoparticles in turbulent flames. This project aims to study the dynamics of liquid fragments and the morphology of synthesised nanoparticles in atomising spray flames. Outcomes will include experimental databases and predictive models for atomising spray flames and nanoparticle inception, as well as a novel atomiser for flame spray pyrolysis. These will provide significant benefits to researchers and industry working on the optimisation of nanostructured material synth ....Dynamics of droplets and nanoparticles in turbulent flames. This project aims to study the dynamics of liquid fragments and the morphology of synthesised nanoparticles in atomising spray flames. Outcomes will include experimental databases and predictive models for atomising spray flames and nanoparticle inception, as well as a novel atomiser for flame spray pyrolysis. These will provide significant benefits to researchers and industry working on the optimisation of nanostructured material synthesis for smart sensors and catalysts, and the next generation efficient and low emission combustion engines.Read moreRead less
The Formation and Emission of Soot Nanoparticles from Turbulent Flames. This project aims to develop experimental and numerical approaches that will enable designers to control the formation and emission of soot nanoparticles from combustors. Ultrafine particles polluting our atmosphere originate from combustion sources and are now confirmed to pose serious health risks. As a result, new regulations will impose strict limits on the number of particles that can be emitted from engines. Satisfying ....The Formation and Emission of Soot Nanoparticles from Turbulent Flames. This project aims to develop experimental and numerical approaches that will enable designers to control the formation and emission of soot nanoparticles from combustors. Ultrafine particles polluting our atmosphere originate from combustion sources and are now confirmed to pose serious health risks. As a result, new regulations will impose strict limits on the number of particles that can be emitted from engines. Satisfying such regulations requires a yet unavailable understanding of the mechanisms that control the evolution of soot in turbulent flames. This project plans to use laser diagnostic methods to construct the experimental framework that will facilitate model development. The resulting predictive capabilities would contribute to a platform that enables engineers to optimise combustor designs.Read moreRead less