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.
Analysis Of Low Radiation Dose Outside Of The Treatment Field Received By Cancer Patients Undergoing Radiotherapy
Funder
National Health and Medical Research Council
Funding Amount
$332,384.00
Summary
Every medical intervention is associated with risk. The present proposal aims to quantify the dose from radiation that is delivered outside the actual target region in radiotherapy of breast cancer patients. This information can help the development of better irradiation techniques as well as inform patients and their carers about possible long term side effects. Finally, the research can be used to finetune radiobiological models by comparing clinical outcomes and accurately calculated doses.
Optimising Synchrotron Microbeam Radiation Therapy For Cancer Treatment
Funder
National Health and Medical Research Council
Funding Amount
$682,000.00
Summary
Over 50% of cancer patients receive radiotherapy (RT). Tumour control using RT is limited by adverse normal tissue reactions. Unlike conventional RT machines, the Australian synchrotron has the capability to deliver strong radiation in very thin slices, termed microbeam RT (MRT). Tumour control has been obtained in animal models with a remarkable sparing of normal tissue using MRT. We will optimize MRT as a crucial step towards a potentially revolutionary cancer treatment.
Role Of Mouse Rad21 And Rec8 Genes In Recombination And Ionising Radiation Response
Funder
National Health and Medical Research Council
Funding Amount
$403,750.00
Summary
We have created a line of mice and are creating a second mouse line which lack two specific genes known as Mrec8 and Mrad21. These genes have a number of roles in mammals. These roles include acting as a glue to hold chromosomes together and allowing exchange of DNA between separate DNA molecules. The latter is important in physiological processes such as genetic exchange during meiosis, but also in the response of the cell to DNA damage, specifically, breakages in both strands of the DNA helix. ....We have created a line of mice and are creating a second mouse line which lack two specific genes known as Mrec8 and Mrad21. These genes have a number of roles in mammals. These roles include acting as a glue to hold chromosomes together and allowing exchange of DNA between separate DNA molecules. The latter is important in physiological processes such as genetic exchange during meiosis, but also in the response of the cell to DNA damage, specifically, breakages in both strands of the DNA helix. In the studies proposed here, we will breed these mice both with each other and with other mice that have specific, single gene defects which lead to abnormal responses to DNA strand breakages. We shall assess the effects of the different genes on response to DNA strand breaking agents in the animals, as well as in cells which have been derived from the animals. These experiments are expected to shed light onto the consequences of defects in DNA repair for the stability of cells and animals, and may provide information which ultimately benefits cancer patients, especially those having radiotherapy.Read moreRead less
This proposal will focus on determining the effect that disruption of molecules involved in repairing DNA has on development of adverse reactions following cancer radiation treatment. Radiation is efective for cancer but tissues that reside next to the tumour are also exposed to radiation (which can damage DNA) during radiotherapy. About 1-5% of radiotherapy patients develop unexpectedly severe side effects in their normal tissues. The dose of radiation used for treatment to the rest of patients ....This proposal will focus on determining the effect that disruption of molecules involved in repairing DNA has on development of adverse reactions following cancer radiation treatment. Radiation is efective for cancer but tissues that reside next to the tumour are also exposed to radiation (which can damage DNA) during radiotherapy. About 1-5% of radiotherapy patients develop unexpectedly severe side effects in their normal tissues. The dose of radiation used for treatment to the rest of patients (>95%) is restrained to assure only a small proportion risk developing severe reactions. If one could predict which individuals were more susceptible to these reactions, then their large dose could be lowered to avoid the problem, and importantly, the dose could be increased for the majority of the patients, which would lead to a higher cancer cure rate. There are over 130 genes involved in repairing DNA. We hypothesize that dysfunctional DNA repair molecules are likely candidates to cause radiosensitivity in these individuals. In fact, a few of these genes have already been found to cause radiosensitivity, but we aim to assess all of the DNA repair genes in samples from patients that have had severe reactions to radiotherapy. Here we will use biospecimens, unique to our study and obtained from clinically radiosensitive cancer patients. We will use very sensitive, state-of-the-art procedures to test RNA and protein levels in our patients' cells and the latest technology to test what happens when candidate DNA repair molecule levels are altered. Additionally, we will determine the changes in DNA repair molecule numbers in response to different doses of radiation. We anticipate that results from these experiments will lead to the development of a clinical assay to test the likelihood of an individual having a severe reaction to radiotherapy, thus allowing individualization of treatment and, reducing radiotherapy side effects ultimately increasing cancer cure rates.Read moreRead less