Novel Transmission Scanning and Computational Strategies for Quantitative microPET Imaging. Advances in detector technologies have led to the development and commercialisation of small animal imaging systems such as microPET which provide high resolution images of radioactive compounds in live animals, but the images can only be interpreted qualitatively. Our aim is to develop quantitative technologies for these new imaging systems. Major outcomes will include novel methods of measuring and corr ....Novel Transmission Scanning and Computational Strategies for Quantitative microPET Imaging. Advances in detector technologies have led to the development and commercialisation of small animal imaging systems such as microPET which provide high resolution images of radioactive compounds in live animals, but the images can only be interpreted qualitatively. Our aim is to develop quantitative technologies for these new imaging systems. Major outcomes will include novel methods of measuring and correcting for signal loss due to photon interactions in the body and integrated image reconstruction algorithms. This will lead to a new generation of quantitative imaging devices; the new technologies will be directly translatable to clinical imaging systems and will broaden the range of microPET applications in the life sciences.Read moreRead less
Novel imaging technologies for continuous measurement of tracer kinetics in awake animals. The fates of biologically relevant molecules, such as proteins and antibodies, in the body are fundamentally important for understanding the mechanisms and treatment of disease. This project will enable for the first time continuous imaging of the location and time course of labelled molecules in conscious, freely moving animals.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100006
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
An adaptable and dedicated linear accelerator for medical radiation research. Leading radiation scientists developing innovative methods and devices for treating cancer patients will collaborate in future research using this highly adaptable linear accelerator for medical radiation research. Innovations in tumour targeting, better patient safety, new medical devices and improved cancer outcomes are expected.
A novel scintillating optical fibre array for cancer imaging and therapy. This project aims to realise a next-generation detector technology that delivers the first fully integrated solution to the X-ray imaging and dose measurement needs of cancer radiation therapy. It is planned that this will be achieved by optimising an experimental prototype device employing a scintillating optical fibre array to generate an optical signal that preserves a tissue-equivalent detector response. The acquired d ....A novel scintillating optical fibre array for cancer imaging and therapy. This project aims to realise a next-generation detector technology that delivers the first fully integrated solution to the X-ray imaging and dose measurement needs of cancer radiation therapy. It is planned that this will be achieved by optimising an experimental prototype device employing a scintillating optical fibre array to generate an optical signal that preserves a tissue-equivalent detector response. The acquired digital image can thus be used to simultaneously verify geometric accuracy (correct patient positioning) and dosimetric accuracy (correct dose distribution). This is not currently possible with existing X-ray detector technology and offers an improvement in treatment accuracy.Read moreRead less
Advanced computational algorithms for brain imaging studies of freely moving animals. Current brain imaging technology requires the animal to be unconscious. This project will remove this barrier by developing computational algorithms that measure brain function in freely moving animals. These technologies will provide brain scientists with new tools to study behaviour altering diseases, such as schizophrenia and depression.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454184
Funder
Australian Research Council
Funding Amount
$155,792.00
Summary
Silicon Imaging Device Construction Facility - Wirebonder. The development of state-of-the-art, high precision semiconductor imaging devices (for high energy particle physics, synchrotron science and medical imaging ) requires a significant capability in modern assembly facilities. In constructing test and 'production' modules consisting of fine-grained, multi-channel bare silicon or other semiconductor imaging devices and custom electronic chips, a high-reliability, highly flexible wire-bonding ....Silicon Imaging Device Construction Facility - Wirebonder. The development of state-of-the-art, high precision semiconductor imaging devices (for high energy particle physics, synchrotron science and medical imaging ) requires a significant capability in modern assembly facilities. In constructing test and 'production' modules consisting of fine-grained, multi-channel bare silicon or other semiconductor imaging devices and custom electronic chips, a high-reliability, highly flexible wire-bonding machine is an essential tool. The international reputation from success in several challenging projects under difficult conditions, gained by the Chief Investigators has resulted in several more projects being planned in addition to a foreseen program of device development. A modern wirebonder, to replace the existing 30 year-old machine, has become critical to maintain our leading position in this area.Read moreRead less
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
New Imaging Instrumentation and Algorithms for the Simultaneous Measurement of Multiple Radio-labelled Probes in vivo. Medical imaging plays an increasingly important role in basic biological research and health care. This project will lead to new imaging technologies that allow the simultaneous measurement of more than one biological process at a time in living subjects, providing new insights into disabling diseases, such as cancer and mental illness. An immediate benefit will be to strengthen ....New Imaging Instrumentation and Algorithms for the Simultaneous Measurement of Multiple Radio-labelled Probes in vivo. Medical imaging plays an increasingly important role in basic biological research and health care. This project will lead to new imaging technologies that allow the simultaneous measurement of more than one biological process at a time in living subjects, providing new insights into disabling diseases, such as cancer and mental illness. An immediate benefit will be to strengthen the expertise in biomedical engineering and instrumentation development in Australia, where we have international leadership. The technologies developed will provide advanced tools for making fundamental biological discoveries and translating them into biotechnological or clinical applications.Read moreRead less
Simultaneous measurement of brain function and behaviour in fully conscious laboratory animals. MicroPET is an advanced imaging technology that measures important biochemical processes, such as enzyme activity rates and receptor binding, in the living rodent brain. However, the requirement for the animal to be anaesthetised precludes the study of behavioural changes in response to sensory or drug stimulus during the imaging study. In this research, we will develop novel motion tracking and compu ....Simultaneous measurement of brain function and behaviour in fully conscious laboratory animals. MicroPET is an advanced imaging technology that measures important biochemical processes, such as enzyme activity rates and receptor binding, in the living rodent brain. However, the requirement for the animal to be anaesthetised precludes the study of behavioural changes in response to sensory or drug stimulus during the imaging study. In this research, we will develop novel motion tracking and computational algorithms that enable microPET to non-invasively image the brains of conscious, freely moving animals while simultaneously observing their behaviour. These new technologies will, for the first time, allow neuroscientists to study the genetic, behavioural and neurochemical correlates of brain disease.Read moreRead less
Rare isotopes as tracers of prosthesis debris. The incidence of knee replacement surgery in Australia is 30,000 per year. Limited by wear debris, the lifespan of knee implants is only 10-15 years and can be much shorter. Due to increasing life expectancy, many patients need several surgical procedures. As a multi-disciplinary team of materials-, isotope-tracing- and medical-experts, we aim to understand and monitor wear debris in prostheses. Knee replacement surgery alone imposes a high burden o ....Rare isotopes as tracers of prosthesis debris. The incidence of knee replacement surgery in Australia is 30,000 per year. Limited by wear debris, the lifespan of knee implants is only 10-15 years and can be much shorter. Due to increasing life expectancy, many patients need several surgical procedures. As a multi-disciplinary team of materials-, isotope-tracing- and medical-experts, we aim to understand and monitor wear debris in prostheses. Knee replacement surgery alone imposes a high burden of annually half a billion dollars on the Australian health budget. Controlling and reducing wear debris in prosthesis joints would reduce these costs and improve patients' quality of life.Read moreRead less