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.
Optimising Radiation Therapy Delivery For Cancer Patients Using Daily Image Guidance To Maximize Cure And Reduce Normal Tissue Side Effects
Funder
National Health and Medical Research Council
Funding Amount
$510,968.00
Summary
When using radiotherapy to kill tumours, the radiation beams need to be targeted at the tumour, plus a margin of error around it to ensure that it receives sufficient dose despite uncertainties in its exact location relative to reference points used for beam alignment. Advanced statistical modelling techniques applied to data collected from patients will be used to determine the optimal margin width for individual patients to maximise cancer cure while minimising normal tissue side effects.
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 phenomenological approach to improve radioembolisation treatment of cancer. In recent years, radioembolisation for liver cancer has become an effective therapeutic option. However, it is likely that patients are being “under-treated” as doses remain based on results from external radiation therapy. This project will develop a phenomenological approach to radionuclide therapy to improve outcomes for cancer patients.
The Surface Science of Vacuum Glazing. In order to achieve a stable vacuum in evacuated glazing, high temperature baking during evacuation is required. The high temperature processing prevents the use of strengthened glass, such as tempered glass. However, samples made at low temperatures suffer from poor vacuum characteristics, particularly when exposed to UV radiation. In this project, we aim to discover the chemical and physical processes occurring on the glass surface responsible for vacuum ....The Surface Science of Vacuum Glazing. In order to achieve a stable vacuum in evacuated glazing, high temperature baking during evacuation is required. The high temperature processing prevents the use of strengthened glass, such as tempered glass. However, samples made at low temperatures suffer from poor vacuum characteristics, particularly when exposed to UV radiation. In this project, we aim to discover the chemical and physical processes occurring on the glass surface responsible for vacuum degradation. We will use this knowledge to develop a low temperature manufacturing process that can be used with tempered glass and results in a high-quality vacuum, stable over the device service life.Read moreRead less
Through this Australia Fellowship, Prof Keall and his tream will substantially improve the accuracy and effectiveness of radiation therapy for cancer by developing new techniques that will be able to ‘target’ a tumour in real-time and ‘concentrate fire’ on the most resistant and aggressive parts of it. Success in physiological targeting will create a paradigm shift in radiation therapy and could literally be a lifesaver. It’s a big challenge, but if this five-year research program succeeds, it w ....Through this Australia Fellowship, Prof Keall and his tream will substantially improve the accuracy and effectiveness of radiation therapy for cancer by developing new techniques that will be able to ‘target’ a tumour in real-time and ‘concentrate fire’ on the most resistant and aggressive parts of it. Success in physiological targeting will create a paradigm shift in radiation therapy and could literally be a lifesaver. It’s a big challenge, but if this five-year research program succeeds, it will pay big dividendsRead moreRead less
Reducing The Greatest Uncertainty In Radiotherapy.
Funder
National Health and Medical Research Council
Funding Amount
$594,197.00
Summary
The weakest link in radiotherapy is defining treatment volumes (contouring). Lack of accuracy and consistency in clinical trial contouring has been shown to result in reduced patient outcomes. Manual review of contouring is resource intensive, expensive and for advanced treatments unachievable in a timely fashion. We will assess an automated approach to contouring assessment using 4 clinical trial datasets, changing practice for future studies and enabling consistent assessment in the clinic.
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.
Tracking Epidermal Clonal Evolution During Skin Cancer Induction And Progression
Funder
National Health and Medical Research Council
Funding Amount
$558,168.00
Summary
Skin cancer is the most frequent form of cancer in Australia and in many parts of the world. It is strongly connected to ultraviolet radiation from the sun. In this project, we will use our capacity to track individual cells, to observe the heterogeneity of tumours and the lesions that precede them. We will show the importance of this heterogeneity in tumour progression unveiling the limits of current therapies against skin cancer.