X-Tream: A Realtime X-ray Treatment Monitoring And Dosimetry System For Submillimetric Radiosurgery
Funder
National Health and Medical Research Council
Funding Amount
$408,544.00
Summary
We plan to develop a commercial prototype of a new clinical product called X-Tream, together with pre-clinical experimental and Monte Carlo data to demonstrate its performance in one potential clinical application involving an exciting and rapidly developing radiosurgery technique known as microbeam radiation therapy. We intend to show that the X-Tream system has the demonstrated ability to provide essential measurements with the necessary accuracy to allow for future clinical trials.
Fast And Efficient Assessment Of Dose In Small Targets In Radiotherapy: Effect Of Motion In Clinical Research And Implementation Of Dynamic Therapy
Funder
National Health and Medical Research Council
Funding Amount
$501,265.00
Summary
The continued progress of radiation therapy for cancer patients has been driven by technology developments that have increased the complexity of radiation delivery, but has come at the cost of increased potential for errors in radiation planning and delivery. The aim of this project is to implement an instrument for verification of treatment delivered to organs with large variation of shape and position due to respiration. This will enhance treatment outcome and patient quality of life.
Breathe Well: Improving Cancer Imaging And Targeted Radiotherapy Using Audiovisual Biofeedback
Funder
National Health and Medical Research Council
Funding Amount
$606,847.00
Summary
Irregular breathing causes anatomical errors in medical images and consequently cancer targeting accuracy, resulting in poorer clinical outcomes and increased health care costs. We have developed and patented the Breathe Well Audio Visual (AV) biofeedback device, to improve breathing regularity. Our goal is to gather critical scientific information and reach commercial proof-of-concept objectives that will allow us to attract investment to establish a viable medical device enterprise.
Cancer Radiotherapy 2020: Accounting For Tumour Deformation In Real Time To Improve Treatment Outcome
Funder
National Health and Medical Research Council
Funding Amount
$371,616.00
Summary
Tumours in lung and prostate cancer change shape during radiotherapy treatment. This is not accounted for in current care, compromising the therapeutic efficacy. We will develop the first radiotherapy system that can adjust the radiation beam in real time to follow the changing tumour shape. We will assess the performance of the system and quantify the clinical benefit. It is expected that clinical implementation of this technique will improve the cure rates and decrease the treatment toxicity.
A Computerised Treatment Planning System For Synchrotron Radiotherapy Trials At The Australian Synchrotron’s Imaging & Medical Beamline.
Funder
National Health and Medical Research Council
Funding Amount
$646,812.00
Summary
Microbeam Radiotherapy (MRT) using synchrotron-generated X-rays has shown tremendous promise in pre-clinical trials in tumour-bearing rodents, with remarkable sparing of normal tissue. Synchrotron MRT has the potential to radically alter the way radiotherapy is performed for human cancers. Every radiotherapy patient undergoes some form of computerised treatment planning before their treatment starts. We aim to test and implement a synchrotron Treatment Planning System, as an essential step in re ....Microbeam Radiotherapy (MRT) using synchrotron-generated X-rays has shown tremendous promise in pre-clinical trials in tumour-bearing rodents, with remarkable sparing of normal tissue. Synchrotron MRT has the potential to radically alter the way radiotherapy is performed for human cancers. Every radiotherapy patient undergoes some form of computerised treatment planning before their treatment starts. We aim to test and implement a synchrotron Treatment Planning System, as an essential step in realising synchrotron radiotherapy trials.Read moreRead less
Cancer Imaging And Targeted Radiation Therapy: From Discovery To Clinical Practice
Funder
National Health and Medical Research Council
Funding Amount
$2,114,215.00
Summary
This program will create a new pipeline of cancer imaging and targeted radiotherapy medical devices, translating discoveries to new first-in-world clinical trials and engaging with industry to see these innovations used in broad clinical practice. The research is applicable to all major cancer types and radiation therapy is essential for cancer cure and symptom control for half of all cancer patients, success means a global real-world impact on the lives of millions of cancer patients.
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.