Molecular Imaging As A Critical Tool In Discovery Of The Basis Of Tumour Heterogeneity And Developing Novel Therapies To Overcome Therapeutic Resistance
Funder
National Health and Medical Research Council
Funding Amount
$467,961.00
Summary
Determining treatment options for cancer currently relies on the size and extent of tumour deposits on imaging, combined with a biopsy. However, this approach fails to recognise the ability of tumours to evolve components that are, or become, resistant to treatment. My laboratory uses advanced molecular imaging, targeted biopsies, animal models and genetic analysis to detect and understand the basis of such resistance and thereby develop new, targeted treatments to improve patient outcomes.
Developing Improved Management For Peripheral Artery Diseases
Funder
National Health and Medical Research Council
Funding Amount
$569,219.00
Summary
~1 million Australians have peripheral artery disease. The current application is for a Practitioner Fellowship to support my research aimed at improving care of artery disease. The aim of the work is to develop improved management approaches for patients with blocked and weakened arteries. This work is particularly important given the recognised management deficiencies for patients with artery disease and the relative little research being undertaken in this area.
Using Mouse Models To Identify Better Therapies For Acute Leukemia And Myelodysplasia
Funder
National Health and Medical Research Council
Summary
Despite great advances in the understanding of the genes that cause cancers of the blood, cure rates for patients with acute leukemia, or a more indolent form called myelodyspslaia, has not improved significantly over the last 20 years, with the majority of patients dying from resistant or recurrent disease within 5 years. Our research will use mouse models of acute leukemia and myelodysplasia to identify the critical genetic pathways that drive these diseases and to design and test new therapie ....Despite great advances in the understanding of the genes that cause cancers of the blood, cure rates for patients with acute leukemia, or a more indolent form called myelodyspslaia, has not improved significantly over the last 20 years, with the majority of patients dying from resistant or recurrent disease within 5 years. Our research will use mouse models of acute leukemia and myelodysplasia to identify the critical genetic pathways that drive these diseases and to design and test new therapies that can be taken into clinical trials.Read moreRead less