Automated 3-Dimensional Biomedical Registration for Whole-body Images from Combined PET/CT Scanners. This project will aid rapid assimilation of very large medical imaging datasets from different imaging devices, and will have clinical applications in diagnosis and treatment and improve patient care. The research, when extended to protein registration, will facilitate analysis of DNA and advance research in bioinformatics and biotechnology. The research could also be used for target recognition, ....Automated 3-Dimensional Biomedical Registration for Whole-body Images from Combined PET/CT Scanners. This project will aid rapid assimilation of very large medical imaging datasets from different imaging devices, and will have clinical applications in diagnosis and treatment and improve patient care. The research, when extended to protein registration, will facilitate analysis of DNA and advance research in bioinformatics and biotechnology. The research could also be used for target recognition, mosaic construction, content-based retrieval, in remote sensing and multimedia. Benefits to Australia include the provision of a readily adaptable image registration program for patient care (e.g., early detection of cancers, dementia), cutting-edge research, high-quality training for students, and encouraging international research collaboration.Read moreRead less
Functionalised MMP Inhibitors as Radiodiagnostic, Radiotherapeutic, and Radiation-Sensitising Agents for Metastatic Cancer. Identifying and treating malignant cancers is one of the major challenges facing the scientific and medical communities. In order to minimise side effects that accompany most treatments of cancer it is necessary to find ways of targeting the therapy to tumours and away from healthy organs. A difference between tumours and healthy tissues is the amount of the proteins (calle ....Functionalised MMP Inhibitors as Radiodiagnostic, Radiotherapeutic, and Radiation-Sensitising Agents for Metastatic Cancer. Identifying and treating malignant cancers is one of the major challenges facing the scientific and medical communities. In order to minimise side effects that accompany most treatments of cancer it is necessary to find ways of targeting the therapy to tumours and away from healthy organs. A difference between tumours and healthy tissues is the amount of the proteins (called MMPs) that tumours use to break out of their surroundings, to break into and out of the blood system, and to establish new colonies of cancer cells or metastases. This difference also distinguishes the most aggressive cancers. The purpose of this project is to develop means of identifying and targeting cancers using molecules that bind to these MMP proteins.Read moreRead less
New methods to improve regional isotope therapy of liver tumours in cancer patients. The most common cause of death in cancer patients is secondary tumours in vital organs. Successful treatment of liver tumours with regional isotope therapy now offers improved survival rates. This project will research novel radiolabelled nanoparticles and advanced computer imaging algorithms to improve regional isotope therapy of liver tumours. It will provide better methods of objective assessment and manageme ....New methods to improve regional isotope therapy of liver tumours in cancer patients. The most common cause of death in cancer patients is secondary tumours in vital organs. Successful treatment of liver tumours with regional isotope therapy now offers improved survival rates. This project will research novel radiolabelled nanoparticles and advanced computer imaging algorithms to improve regional isotope therapy of liver tumours. It will provide better methods of objective assessment and management that can reduce risk and improve patient survival.Read moreRead less
An Australian Program in Precision Flavour Physics. Particle physics is a breakthrough scientific endeavour, addressing fundamental questions about the nature of the laws that govern the Universe we live in. Through engaging in appropriately chosen collaborative experiments at the cutting edge of the field, Australian science can make leading contributions to a deepening understanding that flows from discoveries in this area. Excellent training of young Australian researchers, enhancement of pub ....An Australian Program in Precision Flavour Physics. Particle physics is a breakthrough scientific endeavour, addressing fundamental questions about the nature of the laws that govern the Universe we live in. Through engaging in appropriately chosen collaborative experiments at the cutting edge of the field, Australian science can make leading contributions to a deepening understanding that flows from discoveries in this area. Excellent training of young Australian researchers, enhancement of public interest in science, and fostering of international cooperation and networking are all outcomes which this project will provide.Read moreRead less
Fibre Optic Dosimeters for Medical and Environmental Applications. We will develop fibre optic dosimeters for environmental monitoring and radiation therapy. A novel approach using refractive index gradients will be used to capture scintillator light while rejecting noise. New knowledge will be gained of the mechanisms of radiation damage in scintillators and glasses. The small, flexible, accurate fibre optic dosimeters will be equivalent in absorbing characteristics to human tissue, making them ....Fibre Optic Dosimeters for Medical and Environmental Applications. We will develop fibre optic dosimeters for environmental monitoring and radiation therapy. A novel approach using refractive index gradients will be used to capture scintillator light while rejecting noise. New knowledge will be gained of the mechanisms of radiation damage in scintillators and glasses. The small, flexible, accurate fibre optic dosimeters will be equivalent in absorbing characteristics to human tissue, making them superior to all currently available dosimeters. Fibre optic dosimeters will enable new adaptive radiotherapy techniques and provide quality assurance of dose delivery in radiotherapy. Their multiplexing capability will lead to applications in monitoring of workplaces and aerospace environments.Read moreRead less
A programme to study quarkonium-like states at ATLAS. Particle physics, the study of the fundamental building blocks of matter, has pioneered the use of large collaborations --- hundreds of scientists working in dozens of countries --- to solve difficult research problems. Australian groups have contributed to several such experiments, studying cosmic rays, neutrinos, and broken symmetries, as well as developing ATLAS, a vast experiment dedicated to understanding the origin of mass. This projec ....A programme to study quarkonium-like states at ATLAS. Particle physics, the study of the fundamental building blocks of matter, has pioneered the use of large collaborations --- hundreds of scientists working in dozens of countries --- to solve difficult research problems. Australian groups have contributed to several such experiments, studying cosmic rays, neutrinos, and broken symmetries, as well as developing ATLAS, a vast experiment dedicated to understanding the origin of mass. This project seeks to use ATLAS for a new purpose: searching for exotic mesons. Our existing commitment to ATLAS provides an opportunity to develop this as a new avenue of fundamental research in this country.Read moreRead less
High Precision Silicon Pixel Detectors for High Energy Physics , Synchrotron and Medical Imaging Applications. Australia participates actively in the frontier field of high-energy particle physics to understand the fundamental building blocks of matter, their origins and interactions. This field excites the best minds in the scientific world and provides excellent training. To maintain our position in this field we must continue the development of the powerful instrumentation required for high- ....High Precision Silicon Pixel Detectors for High Energy Physics , Synchrotron and Medical Imaging Applications. Australia participates actively in the frontier field of high-energy particle physics to understand the fundamental building blocks of matter, their origins and interactions. This field excites the best minds in the scientific world and provides excellent training. To maintain our position in this field we must continue the development of the powerful instrumentation required for high-energy experiments. This project will satisfy that role. The application of particle detector expertise to state-of-the-art X-ray imaging detectors for the Australian Synchrotron and medical imaging is a perfect example of fundamental science tools applied to other fields. Australian Synchrotron experiments stand to gain much.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453432
Funder
Australian Research Council
Funding Amount
$257,250.00
Summary
Support for the Australian Experimental High Energy Physics Program. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest.The ATLAS and Belle experime ....Support for the Australian Experimental High Energy Physics Program. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest.The ATLAS and Belle experiments probe two of the most significant questions in fundamental physics: what is the origin of mass, and why do we live in a universe composed of matter rather than antimatter? This proposal seeks support to maintain access to the international high energy physics program in Europe and Japan.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0230224
Funder
Australian Research Council
Funding Amount
$220,255.00
Summary
Support for the Australian Experimental High Energy Physics Program. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest. The ATLAS and Belle experim ....Support for the Australian Experimental High Energy Physics Program. High energy particle physics studies the most fundamental constituents of matter. This microscopic frontier requires the highest energy and highest intensity particle accelerators. Through the Big Bang Model, high energy physics also sheds light on the development of the very early Universe. It is thus crucial for the understanding of nature at the very largest of scales as well as the very smallest. The ATLAS and Belle experiments probe two of the most significant questions in fundamental physics: what is the origin of mass, and why do we live in a universe composed of matter rather than antimatter? This proposal seeks support to maintain access to the international high energy physics program in Europe and Japan.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775488
Funder
Australian Research Council
Funding Amount
$1,350,000.00
Summary
Support for the Australian Experimental High Energy Physics Program. This project will support physicists in the expected era of discovery in the knowledge of fundamental particles that makes up our Universe. Having participated in developing the giant $½ billion ATLAS experiment, Australian scientists will be making major discoveries in this era. ATLAS will hunt down the Higgs boson, to understand the origin of mass of fundamental particles. ATLAS will also search for particles to explain Dark ....Support for the Australian Experimental High Energy Physics Program. This project will support physicists in the expected era of discovery in the knowledge of fundamental particles that makes up our Universe. Having participated in developing the giant $½ billion ATLAS experiment, Australian scientists will be making major discoveries in this era. ATLAS will hunt down the Higgs boson, to understand the origin of mass of fundamental particles. ATLAS will also search for particles to explain Dark Matter, which makes 25% of our Universe. ATLAS will search for undiscovered laws of nature to help us unify our understanding of the forces of nature. Excellent training, public interest, international cooperation and networking, and national pride will be enhanced by this project.
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