Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989788
Funder
Australian Research Council
Funding Amount
$108,481.00
Summary
Nuclear Magnetic Resonance Microimaging and Relaxometry Facility. Many of the research projects to be supported by the facility are dedicated to improving our understanding of conditions and diseases that detrimentally affect many in our community. Projects investigating Alzheimer's disease, the central nervous system and its ability to repair, cancer and associated therapeutic treatments are some of the areas that will benefit from access to this equipment. The new facility will also provide un ....Nuclear Magnetic Resonance Microimaging and Relaxometry Facility. Many of the research projects to be supported by the facility are dedicated to improving our understanding of conditions and diseases that detrimentally affect many in our community. Projects investigating Alzheimer's disease, the central nervous system and its ability to repair, cancer and associated therapeutic treatments are some of the areas that will benefit from access to this equipment. The new facility will also provide unique insights into aspects of fundamental plant biology, with implications for improving crop productivity and better managing our natural ecosystems. The community will also benefit from the development and testing within the facility of new diagnostic tools and markers for a range of diseases.Read moreRead less
Using magnetic nanotechnology to aid recovery from neurotrauma. Nanotechnology is an exciting new field that holds great promise to solve challenging health issues including neurotrauma associated with brain and spinal cord injury. Current methods to deliver drugs and stimulate tissue repair after neurotrauma do not work effectively and new approaches are urgently need. The recently established research team brings together expertise in nanotechnology and neuroscience to develop new, safe ways t ....Using magnetic nanotechnology to aid recovery from neurotrauma. Nanotechnology is an exciting new field that holds great promise to solve challenging health issues including neurotrauma associated with brain and spinal cord injury. Current methods to deliver drugs and stimulate tissue repair after neurotrauma do not work effectively and new approaches are urgently need. The recently established research team brings together expertise in nanotechnology and neuroscience to develop new, safe ways to deliver drugs and stimulate tissue repair after neurotrauma, and provide quality research training. Specifically designed nanomaterials will deliver drugs slowly over time and act as scaffolds to stop cells dying and stimulate them to restore broken connections and work again. Read moreRead less
Targeted enzymatic treatment of the injured central nervous system using innovative nanotechnology. Nanotechnology and other frontier areas in science have exciting potential to solve major challenges of the 21st century, including health. The proposed research provides the real possibility of discovering ways to alleviate the many complex problems associated with neurotrauma following, for example, brain and spinal cord injury. Current delivery of therapeutics do not work effectively and new ap ....Targeted enzymatic treatment of the injured central nervous system using innovative nanotechnology. Nanotechnology and other frontier areas in science have exciting potential to solve major challenges of the 21st century, including health. The proposed research provides the real possibility of discovering ways to alleviate the many complex problems associated with neurotrauma following, for example, brain and spinal cord injury. Current delivery of therapeutics do not work effectively and new approaches are urgently needed. The recently established powerful multidisciplinary research team combines expertise in nanotechnology, glycobiology and neuroscience to develop novel, safe ways to deliver therapeutic enzymes over biological time-courses. We aim to make broken connections work again, while providing quality research training.Read moreRead less
A nanoengineered solution to drug delivery in bone. This project presents an exciting new approach of applying nanotechnology to bone research. By combining our expertise in nanoengineering of new materials, mathematical modelling and bone biology, this project will result in a well-characterised model for drug delivery into bone and lead to a new therapeutic approach for treating bone diseases.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100146
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Multiphoton confocal microscope for high-speed, deep tissue imaging and multimodal nanoscale characterisation. This facility will provide the ability to optically section deep nanoparticles, cells, tissues and whole animals at high speed with unsurpassed spatial resolution at the atomic level. It will give biomedical, physical and life scientists and materials engineers the opportunity to image a range of dynamic processes and reconstruct these in three dimensions for the first time.
Quantum dynamics of solid-state qubits. The primary aim of this project is to carry out a critical assessment of several solid-state qubit systems and quantum logic gate operations through detailed theoretical calculations. This project will address important issues such as precise control of electron flux and spin interactions, optimal operating conditions, errors due to imperfection in the system and possible mechanisms for error elimination, as well as reliable measurements of the output qubi ....Quantum dynamics of solid-state qubits. The primary aim of this project is to carry out a critical assessment of several solid-state qubit systems and quantum logic gate operations through detailed theoretical calculations. This project will address important issues such as precise control of electron flux and spin interactions, optimal operating conditions, errors due to imperfection in the system and possible mechanisms for error elimination, as well as reliable measurements of the output qubit register. In addition, qubit systems have shown themselves to be tiny laboratories in which fundamental concepts in quantum mechanics can be tested and a new regime of physics can be learnt.Read moreRead less
Nano-scale modification of gold surfaces for sensing mercury from gaseous effluents of alumina refineries. The Australian alumina industry contributes more than $5.4 billion export income annually. It is also a major driver of the rural economy with all but one of Australia's seven alumina refineries located in rural areas. In response to the industry's attempts to reduce the environmental impact of its processes, this project will conduct basic strategic research into the interaction between m ....Nano-scale modification of gold surfaces for sensing mercury from gaseous effluents of alumina refineries. The Australian alumina industry contributes more than $5.4 billion export income annually. It is also a major driver of the rural economy with all but one of Australia's seven alumina refineries located in rural areas. In response to the industry's attempts to reduce the environmental impact of its processes, this project will conduct basic strategic research into the interaction between mercury vapour and gold surfaces at the nano-level. Our principal aim is to develop mercury sensor technology suited to alumina refineries. This innovative technology will be a significant breakthrough in the control of mercury emissions and have many other applications.
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Investigation of spin excitations in ferromagnetic submicro- and nanostructures. The project will last 12 months and will be devoted to investigation of spin-wave dynamics in thin ferromagnetic-film sub-micro- and nano-structures for possible applications to microwave\millimetre wave electronic devices and to novel magnetic memory devices. Excitation of spin-wave modes in confined in magnetic nano- and submicro-objects (from the super-paramagnetic size limit up to 700 nm) will be theoreticall ....Investigation of spin excitations in ferromagnetic submicro- and nanostructures. The project will last 12 months and will be devoted to investigation of spin-wave dynamics in thin ferromagnetic-film sub-micro- and nano-structures for possible applications to microwave\millimetre wave electronic devices and to novel magnetic memory devices. Excitation of spin-wave modes in confined in magnetic nano- and submicro-objects (from the super-paramagnetic size limit up to 700 nm) will be theoretically studied. In co-operation with other research groups the obtained theoretical results will be experimentally verified. New information on microwave properties of the structures will be obtained. Possibility of application of the magnetic structures to construct new microwave devices will be considered.Read moreRead less
Processing Pearl Nacre for Bio-Nanotechnology. Nanotechnology has exciting potential to solve major health challenges of the 21st century. The proposed research focuses on developing health care products, derived from a renewable waste stream resource from the pearling industry, en route to establishing products to benefit the rural community, and beyond. The processed pearl nacre provides the possibility of alleviating problems associated with neurotrauma following injury, and for skin regenera ....Processing Pearl Nacre for Bio-Nanotechnology. Nanotechnology has exciting potential to solve major health challenges of the 21st century. The proposed research focuses on developing health care products, derived from a renewable waste stream resource from the pearling industry, en route to establishing products to benefit the rural community, and beyond. The processed pearl nacre provides the possibility of alleviating problems associated with neurotrauma following injury, and for skin regeneration following burns. The recently established powerful multidisciplinary research team in partnership with Pearl Technology combines expertise in chemical processing, nanotechnology, biochemistry, neuroscience and tissue engineering, also providing a basis for quality research training.Read moreRead less
Magnetically controlled drug release from tissue scaffolds for the treatment of acute burns. Severe skin burns are frequently associated with functionally disabling scarring and the risk of death. New magnetically activated wound seals for the treatment of acute burns will be developed that reduce the need for frequent painful dressing changes and hence facilitate rapid healing with a significantly reduced chance of scarring.