Understanding The Molecular Mechanisms Of Cell Death In Radiotherapy
Funder
National Health and Medical Research Council
Funding Amount
$643,856.00
Summary
Radiotherapy (RT) is responsible for 40% of cancer cures. New technology enables RT delivery in fewer treatments using higher radiation dosages through a technique called 'ART'. While ART is effective in the clinic, the underlying mechanisms of cancer cell death are unclear. Here we show that ART induces two distinct waves of cancer cell death. We will characterize these waves of cell death and determine how to enhance tumour cell killing with pharmacological intervention.
Antibiotic Potentiators As An Alternative Therapeutic Option For The Treatment Of Extensively Drug-resistant Gram-negative Infections
Funder
National Health and Medical Research Council
Funding Amount
$856,858.00
Summary
Antibiotic mono-therapies are increasingly ineffective for hard-to-treat bacterial infections, forcing clinicians to rely on combinations of antibiotics. Our project has identified compounds that have weak to no antimicrobial potency in their own right, yet when combined with an existing antibiotic they potentiate its activity and restore its ability to treat resistant infections. These antibiotic potentiators are exciting alternatives to current therapies with reduced risk of induced resistance
Improving Clinical Outcomes Of Antimicrobial Resistant Infections With A Drug-free Intervention
Funder
National Health and Medical Research Council
Funding Amount
$999,581.00
Summary
Superbugs, or antimicrobial-resistant pathogens, cause recurring infections and non-healing wounds after surgery as existing therapies fail to effectively kill them. We will develop a medical device to fight superbugs with UV light that is effective against bacteria and fungi without causing harm to human cells. This could eradicate superbugs at infection sites, aid wound healing and actively improve health outcomes after surgery.
Hijacking A Death Switch In Pancreatic And Lung Cancer Cells To Develop A Novel Therapy
Funder
National Health and Medical Research Council
Funding Amount
$738,947.00
Summary
Pancreatic (PC) and lung (LC) cancer have a high mortality rate and poor response to current treatments. We have identified a protein whose inhibition in both PC and LC cells sensitises them to a cancer-cell specific therapy called TRAIL and switches signals that normally promote tumour growth into tumour death signals. This project aims to develop a novel therapeutic that inhibits our target and delivers TRAIL to PC and LC tumours, and could potentially improve survival for PC and LC patients.
Therapeutic Induction Of Tertiary Lymph Nodes In Cancer
Funder
National Health and Medical Research Council
Funding Amount
$995,010.00
Summary
Immunotherapy has been an important recent advance in cancer treatment by using the body's own immune cells to fight cancer. Although there have been unprecedented dramatic results, not all patients benefit, and most benefits are temporary. The cellular environment in which cancers are embedded is crucial for controlling treatment success. We aim to apply novel 'precision' therapies to this environment to expose the cancer and enable attack by immune cells for improved immunotherapy.
Developing Smart Nanomedicine To Enable Advanced Diagnosis And Stimuli-responsive Treatment For Atherosclerosis And Thrombosis
Funder
National Health and Medical Research Council
Funding Amount
$523,342.00
Summary
The early detection and accurate characterization of life-threatening diseases such as cardiovascular diseases are critical to the design of treatment. A therapeutic approach that provides an efficient treatment with minimal side-effects is highly desired by both patients and healthcare systems. This project aims to develop smart nanomedicine with incorporated diagnostic sensor and external stimuli-responsive treatment mechanisms for cardiovascular diseases.
New Therapies Requiring Ultra Large Scale Monoclonal Ab Production In Microalgae
Funder
National Health and Medical Research Council
Funding Amount
$630,089.00
Summary
Monoclonal antibodies target pathogens and molecules with exquisite specificity, and are essential for therapeutics and diagnostics. They are currently made using high-tech/limited-capacity mammalian cell cultures which limit them to low-dose applications. We aim to enable new, high-dose antibody therapies (e.g. antiviral treatments, passive immunisation) via rapid, low-cost, dramatically larger-scale production of valuable medicinal antibodies in a photosynthetic-driven, green algae system.
Hybrid Optical-electrical Stimulation For Precise Neural Stimulation
Funder
National Health and Medical Research Council
Funding Amount
$935,579.00
Summary
In world-first research, we have evidence that combining electrical stimulation with optical stimulation significantly and safely improves precision of neural activation for devices such as cochlear and retinal implants. In this proposal we will use gene therapy to make nerves responsive to light in pre-clinical animal models to establish proof of concept that hybrid stimulation will significantly improve outcomes for recipients of cochlear and retinal implants.
A Novel, Actionable Pathway Promoting Metastasis Of Triple Negative Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$708,272.00
Summary
Triple negative breast cancer (TNBC) is particularly aggressive and lacks targeted therapies, limiting treatment to chemotherapy. A protein termed PEAK1 drives TNBC but has remained 'undruggable'. Recently, we identified an enzyme, termed CAMK2D, that acts downstream of PEAK1 and mediates its effects. In this grant we will characterize the mechanism of CAMK2D and determine the effect of a drug that blocks its action. This may lead to a new targeted and personalized treatment for TNBC.
Resolving Eosinophil And Inflammatory Heterogeneity In Chronic Allergic Airway Disease For Safer, Effective And Lasting Precision Therapies
Funder
National Health and Medical Research Council
Funding Amount
$1,166,165.00
Summary
Many patients with upper airway inflammation and asthma have poorly controlled disease and are in need of new effective therapies. We have discovered new cell subsets in the airways of these patients. We will use cutting edge single cell and spatial analysis of human tissues to define human allergic disease and inflammatory cells at unprecedented resolution. This will identify new targets for treatment and match patients with effective therapies to facilitate precision therapy.