Improving Cancer Management By Direct Detection With Diffusion-weighted Magnetic Resonance Imaging.
Funder
National Health and Medical Research Council
Funding Amount
$421,549.00
Summary
Despite reliable methods of prostate and breast cancer diagnosis there remains considerable uncertainty as to whether the detected disease will have a significant impact on a patient’s quality of life. This uncertainty is largely due to the inability of current detection methods to show the extent of disease. This project will address this problem by developing new MRI methods that directly measure the microscopic tissue properties that define cancer.
Genetic factors responsible for risk of breast and prostate cancer are largely unknown. Mutations in genes currently known to be associated with susceptibility only account for a small proportion of the familial aggregation of these cancers. I will be applying new genetic technology to population-based studies of cancer to identify new genetic and epigenetic markers of cancer risk. I will use this information to improve health care for families with prostate and breast cancer.
Development Of Modified IGF-binding Proteins As Novel Anti-cancer Chemotherapeutics
Funder
National Health and Medical Research Council
Funding Amount
$77,375.00
Summary
We propose to enhance the effectiveness of current anti-cancer treatments by co-administering a protein to sequester growth factors that promote the resistance of cancer cells to chemotherapy. We aim to achieve improved destruction of breast and colorectal cancers but with reduced adverse side effects. Our in vitro data show the effectiveness of this novel co-therapeutic which is a modified form of a natural carrier protein for these growth factors. This application seeks funding to enable proof ....We propose to enhance the effectiveness of current anti-cancer treatments by co-administering a protein to sequester growth factors that promote the resistance of cancer cells to chemotherapy. We aim to achieve improved destruction of breast and colorectal cancers but with reduced adverse side effects. Our in vitro data show the effectiveness of this novel co-therapeutic which is a modified form of a natural carrier protein for these growth factors. This application seeks funding to enable proof of concept in vivo in order to attract commercial funding for clinical trials.Read moreRead less
The applicant's research is aimed at delineating the molecular mechanisms of action of steroid hormones in the pathogenesis of breast and prostate cancer with the goal of developing new diagnostic, prognostic and therapeutic response parameters of clinica
Pushing AR Toward Better Outcomes In Breast And Prostate Cancers
Funder
National Health and Medical Research Council
Funding Amount
$998,754.00
Summary
Breast and prostate cancers kill >6000 Australians each year. These cancers are strikingly similar, both driven by hormone receptors that have ‘gone bad’. Current therapies aim to eradicate the receptors. While often effective, therapeutic resistance is common and results in fatal disease. We aim to develop new, less toxic treatments that switch receptor behaviour from good to bad, without destroying them. This should improve quality of life, while preventing drug resistance and loss of lives ....Breast and prostate cancers kill >6000 Australians each year. These cancers are strikingly similar, both driven by hormone receptors that have ‘gone bad’. Current therapies aim to eradicate the receptors. While often effective, therapeutic resistance is common and results in fatal disease. We aim to develop new, less toxic treatments that switch receptor behaviour from good to bad, without destroying them. This should improve quality of life, while preventing drug resistance and loss of lives.Read moreRead less
Complex Statistical Analyses Of Genome-wide Association Studies Related To Breast And Prostate Cancers Using High Performance Supercomputing
Funder
National Health and Medical Research Council
Funding Amount
$656,073.00
Summary
Breast and prostate cancers are the most common cancers in Australian women and men. Simple analyses of genome-wide association (GWAS) studies explain only a fraction of why these cancers run in families. The University of Melbourne now has a supercomputer that can conduct much more complex analyses. We will apply these to the world’s GWAS data for breast and prostate cancers. We hope to learn more about the causes of these cancers, and expand an expert Australian workforce in supercomputing.