Nanoengineering materials to combat antimicrobial resistance. This project aims to understand how nanoengineered materials can be designed to kill bacteria and fungi without causing antimicrobial resistance. Resistance to antimicrobial drugs already leads to many thousands of deaths annually and costs society billions of dollars. Nanomaterials have unique abilities to attack microbes in multiple ways that could limit resistance. This project will engineer new antimicrobial nanomaterials tailored ....Nanoengineering materials to combat antimicrobial resistance. This project aims to understand how nanoengineered materials can be designed to kill bacteria and fungi without causing antimicrobial resistance. Resistance to antimicrobial drugs already leads to many thousands of deaths annually and costs society billions of dollars. Nanomaterials have unique abilities to attack microbes in multiple ways that could limit resistance. This project will engineer new antimicrobial nanomaterials tailored to selectively kill microbes with reduced likelihood of developing resistance by using synergies between inorganic nanoparticles and antimicrobial peptides. This technology could be used to prevent infections and biofilms on surfaces in a wide range of future applications, such as medical / veterinary devicesRead moreRead less
AI Assisted Continuous Flow Electrochemistry for Pharmaceutical Manufacture. This project aims to develop new chemical manufacturing processes for pharmaceutical products. In collaboration with Sun Pharma, it will tackle the challenge of replacing expensive and toxic chemicals in industrial reactions, to lower cost of manufacturing and improve its sustainability profile. Central to the realisation of this ambition is the use of electrocatalysis, machine learning and implementation of advanced co ....AI Assisted Continuous Flow Electrochemistry for Pharmaceutical Manufacture. This project aims to develop new chemical manufacturing processes for pharmaceutical products. In collaboration with Sun Pharma, it will tackle the challenge of replacing expensive and toxic chemicals in industrial reactions, to lower cost of manufacturing and improve its sustainability profile. Central to the realisation of this ambition is the use of electrocatalysis, machine learning and implementation of advanced continuous flow methods. These electricity- and technology-driven reactions will develop new strategies for the generation of important classes of molecules relevant to the Australia’s pharmaceutical sector, as well as their manufacture at industrially relevant scales.Read moreRead less
Next Generation Polymeric Scaffolds For Dual Agent Delivery. This project aims to provide a novel suite of degradable polymeric scaffolds for releasing multiple active agents with tailored release profiles by utilising both polymer and small molecule synthesis techniques. The project expects to generate new copolymers and polymer networks that exploit molecular architecture to regulate the release profile of the active agents incorporated. The expected outcome is the establishment of design crit ....Next Generation Polymeric Scaffolds For Dual Agent Delivery. This project aims to provide a novel suite of degradable polymeric scaffolds for releasing multiple active agents with tailored release profiles by utilising both polymer and small molecule synthesis techniques. The project expects to generate new copolymers and polymer networks that exploit molecular architecture to regulate the release profile of the active agents incorporated. The expected outcome is the establishment of design criteria for tailoring the release of active agent from the polymer scaffold. This should provide significant benefits by developing a new technology platform that could be readily adapted to applications in agriculture, pharmaceutical science and veterinary medicine where controlled release is required.
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Emulsion Stability and Solvent Extraction Equipment Design in the Pharmaceutical Industry. The project aims at developing reliable prediction of large scale performance of liquid extraction columns. This will be done through a study of the columns in operation at GlaxoSmithKline's operation at Port Fairy alkaloids plant. In addition a detailed study of the influence of impurities on the coalescence rate of liquid dispersions will be undertaken as this is an important rate limiting step in colu ....Emulsion Stability and Solvent Extraction Equipment Design in the Pharmaceutical Industry. The project aims at developing reliable prediction of large scale performance of liquid extraction columns. This will be done through a study of the columns in operation at GlaxoSmithKline's operation at Port Fairy alkaloids plant. In addition a detailed study of the influence of impurities on the coalescence rate of liquid dispersions will be undertaken as this is an important rate limiting step in column performance. The benefit to GlaxoSmithKline will be a more efficient and optimised plant. The benefit to Australian processing industries is a reliable method of relating small scale trials to full size column performance which is a significent problem in the minerals industry at present.Read moreRead less
Next Generation of Separation Equipment for Natural Product Extraction. The benefit to GlaxoSmithKline will be the potential to upgrade to a more efficient plant which is important for maintaining their competitive position in this global business. The benefit to other Australian processing industries will be an improved understanding of the performance of membrane contactors when used for natural product separation and more specifically a reliable method for controlling fouling in this type of ....Next Generation of Separation Equipment for Natural Product Extraction. The benefit to GlaxoSmithKline will be the potential to upgrade to a more efficient plant which is important for maintaining their competitive position in this global business. The benefit to other Australian processing industries will be an improved understanding of the performance of membrane contactors when used for natural product separation and more specifically a reliable method for controlling fouling in this type of equipment which is a currently a significant industry problem.Read moreRead less
Design, Evaluation, and Selection of Novel Pt(IV) Complexes as Anticancer Agents. Platinum anticancer drugs are arguably the most widely used anticancer agents in the world but serious problems remain with toxicity and resistance. Platinum(IV) compounds have numerous advantages in terms of stability and thereby, lower toxicity. In this project we will exploit these advantages along with others that we have discovered recently and our understanding of the chemistry and biology of platinum(IV) to ....Design, Evaluation, and Selection of Novel Pt(IV) Complexes as Anticancer Agents. Platinum anticancer drugs are arguably the most widely used anticancer agents in the world but serious problems remain with toxicity and resistance. Platinum(IV) compounds have numerous advantages in terms of stability and thereby, lower toxicity. In this project we will exploit these advantages along with others that we have discovered recently and our understanding of the chemistry and biology of platinum(IV) to develop novel platinum(IV) compounds to the point where the industry partner can commercialise them.Read moreRead less
Characterisation of insulin-independent glucose uptake mediated by guanine nucleotide-binding proteins (G-proteins) coupled receptors. This project will provide first class postdoctoral training for Dr Sato in the laboratory of A/Prof Bengtsson one of the pioneers in the field of cell metabolism. He will learn new approaches to the study of cell signalling including the use of ribonucleic acid interference (RNAi) technologies and of a series of functionally altered mutants of phosphatidylinosito ....Characterisation of insulin-independent glucose uptake mediated by guanine nucleotide-binding proteins (G-proteins) coupled receptors. This project will provide first class postdoctoral training for Dr Sato in the laboratory of A/Prof Bengtsson one of the pioneers in the field of cell metabolism. He will learn new approaches to the study of cell signalling including the use of ribonucleic acid interference (RNAi) technologies and of a series of functionally altered mutants of phosphatidylinositol (PI) 3-kinase that he will bring back to Monash University. A better understanding of the cell signalling mechanisms involved in glucose transport will be of enormous benefit in developing new approaches to the treatment of diseases such as type II diabetes.Read moreRead less
The Properties of Enteric Reflexes Recorded in Vivo. The benefit of the work will be a clear understanding of how a key body system, the digestive system is controlled. This will bring a new understanding of how intestinal function is influenced by the food that we eat and also by medicinal compounds. In the longer term, it may lead to development of dietary programs that improve digestive health and to ways to test for adverse or beneficial effects of drugs on the intestine.
Antibacterial Material Design via Mechanism-Based Mathematical Modelling. This Project aims to provide new rules for the design of novel polymer materials with antibacterial properties by employing mechanism-based mathematical modelling.
This Project expects to generate new understanding of those mechanisms which underpin the antibacterial activity of these materials, how bacteria respond to these through metabolic changes and emergence of resistance.These rules will govern material design to yi ....Antibacterial Material Design via Mechanism-Based Mathematical Modelling. This Project aims to provide new rules for the design of novel polymer materials with antibacterial properties by employing mechanism-based mathematical modelling.
This Project expects to generate new understanding of those mechanisms which underpin the antibacterial activity of these materials, how bacteria respond to these through metabolic changes and emergence of resistance.These rules will govern material design to yield new antibacterial materials with improved properties.
Expected outcomes of this project may be a novel mechanism-based mathematical model that will enable the next-generation of antibacterial materials.
This outcome will help address the increasing economic and social burden of antibiotic drug resistance in Australia.
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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