Development Of A Non-invasive Magnetic Resonance Based Cartilage Damage Assessment Technique
Funder
National Health and Medical Research Council
Funding Amount
$556,131.00
Summary
This project will develop automated methods for the extraction of 3D maps of cartilage, bone and other anatomy from high field Magnetic Resonance Images of joints in the body.
MR Hip Intervention And Planning System To Enhance Clinical And Surgical Outcomes
Funder
National Health and Medical Research Council
Funding Amount
$668,069.00
Summary
Degenerative hip disorders and osteoarthritis are a major cause of chronic pain and disability. This project will develop a software tool that allows clinicians to assess, monitor and plan patient treatment using magnetic resonance imaging. It will be the first tool that models joint motion using assessments of bone, cartilage and labral tissue. This will help guide treatment selection and improve outcomes from hip surgeries performed on over 20,000 Australians each year.
Development Of A New Surgical-guidance Tool For Intra-operative Tumour Margin Assessment In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$557,982.00
Summary
One third of breast cancer patients undergoing breast conserving surgery have insufficient tissue removed, resulting in an increased risk of recurrence. We have developed a high resolution optical imaging probe with the potential to detect small areas of cancer. It could be used to help guide the surgeon to remove all cancerous tissue from the patient. This grant will allow us to develop the probe to a stage that it can be used during surgery, and perform the world’s first clinical scans.
Development Of Microscope-in-a-needle Devices For Improved Clinical Diagnostics
Funder
National Health and Medical Research Council
Funding Amount
$327,746.00
Summary
We have developed a new high-resolution optical imaging technology. The unique aspect of our research has been to redesign the imaging probe, miniaturising it to a few hundred microns in diameter, and encase it in a hypodermic needle – a ‘microscope-in-a-needle’. We are developing specific imaging probes to aid in the assessment of lung disease; the diagnosis of liver disease; and integrated into a brain biopsy needle to enable safer brain biopsies.
Single Shot X-ray Tomography For Real-Time Functional X-ray Imaging
Funder
National Health and Medical Research Council
Funding Amount
$322,641.00
Summary
Computed Tomography (CT) scanners produce three-dimensional images of vital organs that cannot be obtained by conventional two-dimensional (single projection) x-ray radiographs. However, the radiation exposure is hundreds of times higher than conventional radiography. We will develop the world’s first CT scanner that uses no more radiation than a single conventional x-ray image that will provide four-dimensional reconstructions of a patient’s moving internal organs.
From The Synchrotron To The Clinic: Translation Of A Novel Functional Lung Imaging Technology
Funder
National Health and Medical Research Council
Funding Amount
$891,834.00
Summary
Our team has recently developed a synchrotron technology with a startling capacity for dynamic functional imaging that can act as a sensitive regional indicator of lung disease. We will demonstrate that this technology can be translated from the synchrotron to the lab and eventually the clinic. We will provide proof of this concept by the application of this technology to emphysema, asthma, lung cancer, cystic fibrosis lung disease and neonatal resuscitation.
CSI-Sydney: New Technologies To Treat Chronic Sinus Infection
Funder
National Health and Medical Research Council
Funding Amount
$412,213.00
Summary
Chronic sinus infection (CSI) is prevalent and results in severe discomfort and pain for many Australians; yet amazingly, has no specific cure or effective treatment. Our multi-disciplinary research team and an Australian health and medical research company, (AFT Pharmaceuticals) have partnered to develop a novel device that specifically targets the sinuses and a formulation capable for simultaneously removing mucus, dispersing biofilms and killing bacteria in the nasal cavities.
We will create a new class of cancer radiotherapy system that solves the complex problem of how to target a tumour with precision and accuracy even as the patient’s anatomy changes during treatment. Our Nano-X system is built with real-time imaging guidance and treatment adaptation at the heart of the design process; and complex processing tasks have been moved from hardware to software, enabling radical changes to machine design. Together these innovations will ensure better treatment outcomes.
BrachyVision: A Novel Multipurpose Probe For In-body Radiation Imaging And Dosimetry.
Funder
National Health and Medical Research Council
Funding Amount
$532,627.00
Summary
BrachyVision is an in-body imaging and dosimetry system to assist physicians in providing efficient and optimized permanent seed implant brachytherapy cancer treatment. The system allows intra-operative preplanning, image guided treatment, post implant verification and direct rectal dosimetry. It represents a major advance in clinical technology that can improve quality of life of prostate cancer patients and, through reduced post treatment complications, lead to significant health cost savings.
Novel Prostate Cancer Target For Diagnosis, Imaging, Detection Of Recurrence And Response To Therapy
Funder
National Health and Medical Research Council
Funding Amount
$731,497.00
Summary
This project will generate the critical proof of concept to justify clinical development of a novel biomarker in prostate cancer which would bring significant benefit in terms of differential diagnosis of aggressive disease. The biomarker will be assessed for a functional role in prostate cancer and potential as a therapeutic target and use as a imaging agent in for monitoring disease progression and response to therapy. These investigations will be extended to other common solid tumours.