Low Cost High Precision Radiotherapy: A Synergistic Framework For Tumour Tracking During Treatment
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
Advances in technology have enabled radiotherapy to become more sophisticated and more efficient at treating cancer. Yet, despite its sophistication, today radiotherapy suffers from a major problem: whilst we routinely image patients prior to treatment, no anatomical information is available during treatment. This project aims to solve this problem by making use of a number of sensors that are already available in a radiotherapy to track the tumours positions during treatment, when it counts.
Improving Patient Safety In Radiation Therapy With The Watchdog Real-time Treatment Delivery Verification System
Funder
National Health and Medical Research Council
Funding Amount
$593,742.00
Summary
Radiation therapy is a highly effective cancer treatment with extremely high doses delivered using very complex treatment machines. Unfortunately errors have occurred resulting in cases of patient death and mistreatment. We have developed a novel method to assess the treatment delivery in real-time to prevent errors. The method uses imaging devices that are already present on the treatment machine meaning that this method could have a major impact on patient safety in modern radiation therapy.
Investigation Of A New Electronic Portal Imaging Device For Radiation Therapy Dose Delivery Verification
Funder
National Health and Medical Research Council
Funding Amount
$408,101.00
Summary
In external beam radiotherapy highly complex radiation fields are used to deliver high doses of radiation to the tumour while sparing normal tissues. Inaccurate treatment could result in poor patient outcome or damage to normal tissues. We aim to investigate a novel imaging device to measure the dose accuracy of these fields. This work has the potential to make a significant and fundamental difference to existing verification techniques for radiotherapy treatments to ensure patient outcomes.
High-average-power all-solid-state lasers based on new crystalline Raman materials. We have recently made significant advances in development of all-solid-state intracavity Raman lasers generating multiwatt average powers in the near infrared and (by frequency doubling) visible spectrum, with important applications in biomedicine and remote sensing. A new generation of Raman crystals, especially tungstates, offer superior optical, mechanical and thermal properties, promising high Raman gains and ....High-average-power all-solid-state lasers based on new crystalline Raman materials. We have recently made significant advances in development of all-solid-state intracavity Raman lasers generating multiwatt average powers in the near infrared and (by frequency doubling) visible spectrum, with important applications in biomedicine and remote sensing. A new generation of Raman crystals, especially tungstates, offer superior optical, mechanical and thermal properties, promising high Raman gains and choice of Stokes frequency shift. The project will investigate a range of key issues for these materials including control of the Stokes wavelength, associated polarisation control, and pump-resonator configurations giving maximum Raman laser power and efficiency. The project will lead to state-of-the-art source technology with outstanding prospects for commercialisation and practical application.Read moreRead less
Optical fibre devices for sideways delivery of laser light during keyhole surgery. Mulitmode optical fibres are typically used to deliver high power laser light which is emitted from the end of the fibre to irradiate tissue during surgery. For intravenous delivery of laser light in the treatment of cardiac fibrillation (heart flutter) we require a sideways-directed illuminating beam. However reliable methods of delivering high power laser light in a sideways-directed beam are not currently avai ....Optical fibre devices for sideways delivery of laser light during keyhole surgery. Mulitmode optical fibres are typically used to deliver high power laser light which is emitted from the end of the fibre to irradiate tissue during surgery. For intravenous delivery of laser light in the treatment of cardiac fibrillation (heart flutter) we require a sideways-directed illuminating beam. However reliable methods of delivering high power laser light in a sideways-directed beam are not currently available. Using the ultraviolet laser fibre processing expertise already developed at Macquarie University, we propose to develop and characterise novel fibre-based devices which would allow controllable delivery of light sideways.Read moreRead less
Development of Novel Two-dimensional Techniques for Magnetic Resonance In-vivo Spectroscopy. Body chemistry alters with functionality, pain, ageing and disease. These changes can be recorded by magnetic resonance (MR) spectroscopy (MRS) in vivo in a whole body MR scanner. When changes in chemistry can be recorded rapidly, and the individual species assigned, it will be possible to make a definitive diagnosis and in some cases allow the tailoring of treatment on an individual basis. This is curre ....Development of Novel Two-dimensional Techniques for Magnetic Resonance In-vivo Spectroscopy. Body chemistry alters with functionality, pain, ageing and disease. These changes can be recorded by magnetic resonance (MR) spectroscopy (MRS) in vivo in a whole body MR scanner. When changes in chemistry can be recorded rapidly, and the individual species assigned, it will be possible to make a definitive diagnosis and in some cases allow the tailoring of treatment on an individual basis. This is currently hampered by our inability to separate the composite resonances in a one dimensional MR spectrum. Research will allow two dimensional MRS to be implemented and provide detailed chemical information on human organs in vivo. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100009
Funder
Australian Research Council
Funding Amount
$1,064,000.00
Summary
Ultra-high resolution magnetic resonance imaging (MRI) system for physical applications. Ultra-high resolution magnetic resonance imaging (MRI) system for physical applications: Ultra-high field magnetic resonance imaging provides unique high contrast images at previously inaccessible levels of resolution (<0.1mm). It non-invasively provides unprecedented information on chemical and biochemical processes including functional biological mechanisms. This infrastructure will be the focal point for ....Ultra-high resolution magnetic resonance imaging (MRI) system for physical applications. Ultra-high resolution magnetic resonance imaging (MRI) system for physical applications: Ultra-high field magnetic resonance imaging provides unique high contrast images at previously inaccessible levels of resolution (<0.1mm). It non-invasively provides unprecedented information on chemical and biochemical processes including functional biological mechanisms. This infrastructure will be the focal point for more than 100 academics and HDR students. It will take Australia to the forefront of magnetic resonance imaging capability as well as providing unique insights into diffusion and electrophoretic problems central to designing next generation energy storage. Outcomes will range from agricultural advances, higher performing batteries, and more effective cancer treatments as well advancing Australia's fundamental scientific capabilities.Read moreRead less
Modulating neuron activity with terahertz light. The increasing prevalence of high frequency electromagnetic radiation for military applications, communication and imaging has prompted interest in the effects of these frequencies in neuroscience. The primary aim of this project is to understand the interactions and effects of terahertz light (or T-rays) on neurons and brain tissue and will build on Australia's position as a leader in terahertz technology. This work will identify optimal paramete ....Modulating neuron activity with terahertz light. The increasing prevalence of high frequency electromagnetic radiation for military applications, communication and imaging has prompted interest in the effects of these frequencies in neuroscience. The primary aim of this project is to understand the interactions and effects of terahertz light (or T-rays) on neurons and brain tissue and will build on Australia's position as a leader in terahertz technology. This work will identify optimal parameters for neuronal modulation with one of the potential outcomes being the possibility of controlling neuron firing rates which has applications in neuroscience. It also has clinical implications in terms of the suppression of pain and other neurological disorders.Read moreRead less