Copper complexes for the diagnostic imaging of Alzheimer's disease. This research will develop new chemistry to produce new imaging agents for earlier and more accurate diagnosis of Alzheimer's disease.
The effect of Pt binding to CTR1 on Cu homeostasis and cell phenotype. The copper transport protein CTR1 is commonly believed to transport active cisplatin (a platinum-based anticancer agent) into the cell, but this model is inconsistent with the chemical properties of platinum (Pt) and CTR1. The project aims to interrogate the interaction between CTR1 and Pt in cells by developing new chemical tools for the study of Pt species within cells. It will then study the effect of the CTR1-Pt interacti ....The effect of Pt binding to CTR1 on Cu homeostasis and cell phenotype. The copper transport protein CTR1 is commonly believed to transport active cisplatin (a platinum-based anticancer agent) into the cell, but this model is inconsistent with the chemical properties of platinum (Pt) and CTR1. The project aims to interrogate the interaction between CTR1 and Pt in cells by developing new chemical tools for the study of Pt species within cells. It will then study the effect of the CTR1-Pt interaction on copper homeostasis and cell phenotype. It is expected that the results will provide valuable information on the status of CTR1 and Pt following interaction, and reveal whether less toxic complexes are just as effective in decreasing cell malignancy as cisplatin itself.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101650
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Rational design of novel metal-based chaperones for tumour-selective drug delivery. This work aims to develop new drug delivery systems based on transition metal complexes for selective delivery and release of a drug in the tumour.
New methods for the chemical synthesis of a library of glycopeptide-based tri-component cancer vaccines. A novel method for the synthesis of tumour-associated glycopeptides will be developed in this research as well as the preparation of a library of glycopeptide-based cancer vaccines. These vaccines will be tested in immunological studies with a view to elucidating new immune-based therapies for the treatment of cancer.
Total Synthesis of Myxobacteria Metabolites and Analogues. This project will investigate the total chemical synthesis of complex myxobacteria metabolites. In addition, the synthesis of new analogues of some of these natural products will also be investigated. The project endeavours to develop new methods for chemical synthesis and also to produce new therapeutic products which may possess greater efficacy and superior biological activities than the natural compounds. Most significantly, this pro ....Total Synthesis of Myxobacteria Metabolites and Analogues. This project will investigate the total chemical synthesis of complex myxobacteria metabolites. In addition, the synthesis of new analogues of some of these natural products will also be investigated. The project endeavours to develop new methods for chemical synthesis and also to produce new therapeutic products which may possess greater efficacy and superior biological activities than the natural compounds. Most significantly, this project will deliver natural and new compounds for analysis of anti-cancer activity. The rewards of the development of new synthetic methods are enormous for the community and in the education of our scientists.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101281
Funder
Australian Research Council
Funding Amount
$300,036.00
Summary
Biomimetic lipidic self-assembly materials for protein encapsulation. This project intends to improve understanding of the interactions between proteins and lipidic materials to guide the development of new biomaterials. Proteins and peptides play an increasingly important role as drugs, vaccines and diagnostics. However, these fragile, often large, macromolecules come with challenges for drug delivery. Lipid-based materials are ideal matrices for encapsulation of functionally active proteins. T ....Biomimetic lipidic self-assembly materials for protein encapsulation. This project intends to improve understanding of the interactions between proteins and lipidic materials to guide the development of new biomaterials. Proteins and peptides play an increasingly important role as drugs, vaccines and diagnostics. However, these fragile, often large, macromolecules come with challenges for drug delivery. Lipid-based materials are ideal matrices for encapsulation of functionally active proteins. They also offer advantages as drug delivery vehicles including controlled release properties. The combination of strategies creates an ideal delivery system for protein therapeutics. The project aims to characterise the physicochemical interactions between the protein and the lipid matrix. This may guide the development of novel lipidic materials for the encapsulation and controlled release of protein therapeutics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101632
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Development of Innovative Chemical Tools for Studying Glycosyltransferases . This project aims to develop chemical probes capable of selectively binding and inhibiting two classes of carbohydrate processing enzymes known as O-linked beta-N-acetylglucosamine transferase and sialyltransferases. These enzymes are overexpressed in various cancers and play critical roles in cancer progression. Probes will be developed to analyse the activities of these enzymes in cancer cells.
Multifunctional and Multimodal Theranostics: Manipulating Material Properties for Advanced Diagnostics. The utilisation of polymers in nanomedicine requires a bottom-up approach, where the fundamental chemistry is well-established and understood before it enables an application. This project develops branched polymers as new nanomaterials for theranostics; imaging modalities that “switch-on” when miRNA is released will quantify how much nanomaterial gets to a specific site, while a built-in sens ....Multifunctional and Multimodal Theranostics: Manipulating Material Properties for Advanced Diagnostics. The utilisation of polymers in nanomedicine requires a bottom-up approach, where the fundamental chemistry is well-established and understood before it enables an application. This project develops branched polymers as new nanomaterials for theranostics; imaging modalities that “switch-on” when miRNA is released will quantify how much nanomaterial gets to a specific site, while a built-in sensor based on physical changes in the nanomaterial will measure the onset and progression of necrosis. The aim is to develop a fundamental understanding of how polymer architecture and functionality can be utilised to drive device performance, providing a platform to probe new technology and methodologies for development of next generation theranostics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101547
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Novel smart materials: development of positively thermo-responsive polymers for biomedical applications. The project will develop novel materials, which drastically change their structure and shape on a microscopic level in response to subtle temperature changes. In modern pharmaceuticals, this smart behaviour can be exploited to cause tailored microscopic containers to open inside the body and release medicine exactly where and when it is needed.
The development of carboranes as new agents in the diagnosis and treatment of brain disease. The treatment of brain diseases is one of society's major challenges. To address these challenges, we need a better understanding of the molecular mechanisms involved in brain disease. This project will develop innovative agents to probe disease progression, assess efficacy of treatment, and ultimately treat a wide range of brain disorders.