Enhancement Of The Anti-tumour Efficacy Of Ionising Radiation Through Inhibition Of Phosphoinositide 3-kinase
Funder
National Health and Medical Research Council
Funding Amount
$123,503.00
Summary
Radiation treatment alone is given to many cancer patients, however often it does not prevent cancers from recurring. Significant promise is offered by new drugs that target molecules which play a key role in cancer growth, and combining these drugs with radiation treatment may lead to improved patient outcomes. Understanding how these drugs enhance the anti-cancer effects of radiation is critical to selecting the most appropriate patients for treatment with this combination.
Targeting TRPV4 Activation Mechanisms To Reveal Novel Pain Therapies
Funder
National Health and Medical Research Council
Funding Amount
$580,938.00
Summary
Pain nerves sense painful chemical and physical stimuli, by opening protein "ion channels" which let small electric currents traverse the cell membrane. This pain signal is transmitted to the spinal cord and then the brain, where it is perceived as pain and elicits a reaction. But we don't know how the ion channels open. This project will investigate how receptors for painful substances open ion channels to cause pain. Understanding this mechanism will help us to make new drugs to treat pain.
I am a molecular-cell biologist studying the genetic regulation of intestinal homeostasis in development and disease with the aim of identifying novel molecular targets for the treatment of disease and that can be validated in relevant preclinical mouse models.
Phosphoinositide 3-kinase Signalling And Skeletal Muscle Mass.
Funder
National Health and Medical Research Council
Funding Amount
$597,598.00
Summary
Maintenance of skeletal muscle mass is essential for human health and locomotion. In ageing and cancer, loss of muscle mass leads to severe weakness and immobilization causing morbidity and mortality. This grant aims to characterise a novel gene that when deleted in mice leads to significant muscle damage. The molecular pathways within the cell that lead to the observed muscle damage will be investigated and this may provide insights into the pathways that control muscle damage and its regenerat ....Maintenance of skeletal muscle mass is essential for human health and locomotion. In ageing and cancer, loss of muscle mass leads to severe weakness and immobilization causing morbidity and mortality. This grant aims to characterise a novel gene that when deleted in mice leads to significant muscle damage. The molecular pathways within the cell that lead to the observed muscle damage will be investigated and this may provide insights into the pathways that control muscle damage and its regenerationRead moreRead less