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.
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.
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.
Brm And Brg-1 Protect From Ultraviolet Radiation-induced Skin And Ocular Damage
Funder
National Health and Medical Research Council
Funding Amount
$555,325.00
Summary
Ultraviolet radiation within sunlight is the most important environmental hazard to which Australians are exposed. It causes cancers of the skin and eye, in addition to other forms of skin and eye damage. However sunlight also has health benefits such as vitamin D production. To protect our health from the sun we need to understand how it causes damage and the meachanisms involved. We have discovered a new pathway that we plan to study, called Brm and Brg-1, that provides protection from UV.
Heparin Induced Thrombocytopenia (HIT): Further Characterization Of Disease Mechanism Will Improve Patient Treatment
Funder
National Health and Medical Research Council
Funding Amount
$456,484.00
Summary
Thrombus formation occurs as a side effect of heparin treatment in many patients. This condition is called Heparin Induced Thrombocytopenia (HIT). The clots may be stabilised by secretions from cells called neutrophils. In this project we will study this possibility using a mouse model of HIT and will explore therapeutic approaches to inhibit clot stabilisation.
A Phase I Study Of Autologous CD19 Specific Chimeric Antigen Receptor T-cells For Therapy Of Relapsed And Refractory B-cell Leukaemia And Lymphoma (The Auto-CAR19 Trial).
Funder
National Health and Medical Research Council
Funding Amount
$584,666.00
Summary
Most people with leukaemia and lymphoma who relapse early after chemotherapy die of their disease. Inserting special genes into immune cells can enable them to kill leukaemia and lymphoma and has led to dramatic cures, but the cost of the viral vectors used to make these cells is prohibitively expensive. We will make leukaemia and lymphoma specific immune cells from patients using an inexpensive non-viral system, then administer the immune cells to patients to assess their safety and efficacy.
Targeting Neutrophil Extracellular Traps To Reduce Inflammation In Severe Asthma
Funder
National Health and Medical Research Council
Funding Amount
$585,240.00
Summary
People with severe asthma, a chronic disease of the lungs, often have many inflammatory cells in the airways called neutrophils. Neutrophils release a meshwork of fibers in a web like trap called NETs, which are made of the cells DNA and other proteins that fight infection. These NETs can promote inflammation in the persons airways. Current asthma treatments have no effect on NETs. This project will measure NETs in the airways and test a new treatment to reduce NETs, and relieve asthma symptoms.
Alpha-particles linked to recombinant antibodies targeting tumour cells have potential to effectively treat tumours while minimising normal tissue side effects. We will explore a novel alpha-particle therapy approach to solid tumours, by delivering 225Ac directly into tumour cells, or into cells that support the tumour (microenvironment). This approach will hopefully result in development of a new approach to treatment of cancers that are resistant to conventional therapies.
A Phase I Study Of PiggyBac CD19 Specific Chimeric Antigen Receptor T-cells For Therapy Of Persistent And Relapsed B-cell Leukaemia And Lymphoma Post Allogeneic Stem Cell Transplantation (The CARTELL Study).
Funder
National Health and Medical Research Council
Funding Amount
$357,590.00
Summary
Most people with relapsed leukaemia and lymphoma after bone marrow transplant die of their disease. Inserting special genes into immune cells can enable them to kill leukaemia and lymphoma and has led to dramatic cures, but there is little experience in bone marrow transplant patients. We will make leukaemia and lymphoma specific immune cells from normal bone marrow transplant donors, then administer the immune cells to transplant patients to assess their safety and effectiveness.
Melanotransferrin: A “Missing Link” And A Novel Pharmacological Target For Treatment
Funder
National Health and Medical Research Council
Funding Amount
$613,848.00
Summary
Despite >30 years of research, the precise function of the protein, melanotransferrin (MTf), is unknown. However, we have breakthrough evidence that MTf stimulates WNT signalling as a major driver in cancer progression. We will investigate this hypothesis, which will underpin new cancer therapies. Indeed, we designed a new class of drugs that target the WNT pathway via up-regulating the WNT inhibitor, NDRG1. This drug (DpC) inhibits MTf expression to block tumour cell growth and metastasis.