Biomedical Investigations Of Pharmacology And Pathology For Disease Treatment
Funder
National Health and Medical Research Council
Funding Amount
$863,413.00
Summary
I am an NHMRC SPRF & Director of the Molecular Pharmacology & Pathology Program consisting of 34 researchers. The breadth of our studies is diverse & continues to expand. Excitingly, we have recently obtained commercialisation support to develop our anti-tumour drug, DpC. My vision for the next 5 yrs is to direct development of these agents together with investigations of basic mechanism. These studies will be done with a team of outstanding researchers I am mentoring and an established group of ....I am an NHMRC SPRF & Director of the Molecular Pharmacology & Pathology Program consisting of 34 researchers. The breadth of our studies is diverse & continues to expand. Excitingly, we have recently obtained commercialisation support to develop our anti-tumour drug, DpC. My vision for the next 5 yrs is to direct development of these agents together with investigations of basic mechanism. These studies will be done with a team of outstanding researchers I am mentoring and an established group of experienced collaborators.Read moreRead less
New Treatments For Malaria Targeting Both The Sexual And Asexual Stages Of The Causative Parasite, Plasmodium Falciparum
Funder
National Health and Medical Research Council
Funding Amount
$731,155.00
Summary
We have discovered a potent antimalarial compound class. In this research plan we will improve their metabolic stability such that we can progress them as potential oral cures for malaria. We will also elucidate their mechanism of action and this will aid therapeutic development.
Pre-clinical Development Of A Novel Second Generation Chemotherapeutic For Cancer Therapy
Funder
National Health and Medical Research Council
Funding Amount
$584,907.00
Summary
Cancer cells have a high iron requirement for DNA synthesis and many clinical trials have shown that iron chelators are effective anti-cancer drugs. Their potential to act as anti-tumour agents has been confirmed by the entrance of the iron chelator, Triapine, into widespread NCI clinical trials. In this NHMRC Development Grant, we will perform toxicological studies to enable clinical trials of our most potent and selective anti-cancer agent to commence.
Development Of A New Class Of Broad-Stage Antimalarial Agents
Funder
National Health and Medical Research Council
Funding Amount
$729,037.00
Summary
In 2017, there were almost 220 million cases of malaria across 90 different countries, associated with 435,000 deaths, and with 65-70% of all malaria deaths tragically being children under the age of 5 years old. No significant progress in reducing global malaria cases has been made over the last 4 years and the need for new and better treatments remains dire. In this research and development plan, we will develop novel and safer drugs for the treatment of drug resistant malaria.
Determining The Impacts Of Epigenetic Modifying Drugs On Germline Programming And Offspring Health
Funder
National Health and Medical Research Council
Funding Amount
$863,918.00
Summary
New drugs have been developed that inhibit specific enzymes that regulate epigenetic pathways in cells. These pathways significantly affect growth and development in offspring and may represent a risk to future children of patients taking the drug. This project will determine these risks and provide data for developing clinical guidelines for safe use of the drugs.
Pharmacology Of Potential Anti-Tumour Agents: Iron Chelators Of The BpT Class
Funder
National Health and Medical Research Council
Funding Amount
$585,455.00
Summary
Pharmacology of Potential Anti-Tumour Agents: Iron Chelators of the BpT Class Cancer cells have a high iron requirement for DNA synthesis and many clinical trials showed Fe chelators are effective anti-cancer drugs. Their potential to act as anti-tumour agents has been confirmed by the entrance of Triapine into widespread NCI clinical trials. In this NHMRC Renewal, we will perform pharmacological and preclinical studies to promote the development of BpT chelators as novel anti-tumour agents.
Toxicological And Pre-clinical Assessment Of The Anti-cancer Compound Bp4eT
Funder
National Health and Medical Research Council
Funding Amount
$198,900.00
Summary
Cancer cells have a high iron requirement for DNA synthesis and many clinical trials showed Fe chelators are effective anti-cancer drugs. Their potential to act as anti-tumour agents has been confirmed by the entrance of Triapine into widespread NCI clinical trials. In this NHMRC Development Grant, we will perform toxicological studies to enable clinical trials of our most promising novel iron chelator to commence.
Perturbation of the extracellular architecture to promote the absorption and lymphatic transport of biological macromolecules. Macromolecules therapeutics such as proteins, antibodies or polymer conjugates pose a number of pharmaceutical challenges. Where the dose is high, drainage of that dose from a subcutaneous injection site into the circulation, poses a particular problem. Here the project aims to explore how recombinant hyaluronidase, an enzyme that breaks down a structural component (hya ....Perturbation of the extracellular architecture to promote the absorption and lymphatic transport of biological macromolecules. Macromolecules therapeutics such as proteins, antibodies or polymer conjugates pose a number of pharmaceutical challenges. Where the dose is high, drainage of that dose from a subcutaneous injection site into the circulation, poses a particular problem. Here the project aims to explore how recombinant hyaluronidase, an enzyme that breaks down a structural component (hyaluronan) of the interstitum, can be used promote absorption into the draining blood and lymph capillaries. The project aims to also explore the downstream effects of hyaluronidase on lymph nodes and evaluate whether the enzyme is able to temporarily disrupt the lymph node structure and promote drug penetration into the lymph node mass. This has significant potential for improved drug targeting.Read moreRead less
Understanding the Cellular Pathways of Nuclear Receptor Activation. The success of drug treatment depends critically on specificity, i.e., stimulation of a therapeutic response at a target site, and avoidance of activity at other (potentially toxic) locations. This project aims to explore how drug interactions with binding proteins in the cytosol can induce nuclear transport and tissue specific activation of nuclear receptors - a major drug target. The project intends to employ molecular, struct ....Understanding the Cellular Pathways of Nuclear Receptor Activation. The success of drug treatment depends critically on specificity, i.e., stimulation of a therapeutic response at a target site, and avoidance of activity at other (potentially toxic) locations. This project aims to explore how drug interactions with binding proteins in the cytosol can induce nuclear transport and tissue specific activation of nuclear receptors - a major drug target. The project intends to employ molecular, structural and cell biology approaches to map drug-binding protein-receptor interactions and to determine how the structure of these complexes dictates receptor activation. The data could provide a roadmap to design drugs that interact with the right protein in the right tissue and in doing so dramatically enhance drug specificity.Read moreRead less
Artificial intelligence to explore and combat eukaryotic pathogens. The revolution in artificial intelligence (AI) provides unprecedented opportunities for integrative analyses of complex multi-omics data sets and for creating radically new strategies to control some of the world’s most serious animal diseases. In a strong partnership with international experts, we will use AI-based methods to make major conceptual advances in our understanding of eukaryotic pathogens and host-pathogen interacti ....Artificial intelligence to explore and combat eukaryotic pathogens. The revolution in artificial intelligence (AI) provides unprecedented opportunities for integrative analyses of complex multi-omics data sets and for creating radically new strategies to control some of the world’s most serious animal diseases. In a strong partnership with international experts, we will use AI-based methods to make major conceptual advances in our understanding of eukaryotic pathogens and host-pathogen interactions, discover the "choke-points" in biological pathways, and develop novel treatments, vaccines and diagnostics. This leap forward will substantially enhance the global profile of pathogen research in Australia, build major capacity in a priority area, and enable access to international research funding and networks.Read moreRead less