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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883021
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
Advanced Surface Characterisation Facility. This proposal underpins a major expansion of surface characterisation resources at La Trobe University, one of Australia's leading providers in this field, and builds associated research programs and collaborations, in particular, with Monash University and Deakin University. New opportunities will be provided for hands-on training in state-of-the-art surface characterisation for postgraduates in fields such as physics, chemistry, nanotechnology, mater ....Advanced Surface Characterisation Facility. This proposal underpins a major expansion of surface characterisation resources at La Trobe University, one of Australia's leading providers in this field, and builds associated research programs and collaborations, in particular, with Monash University and Deakin University. New opportunities will be provided for hands-on training in state-of-the-art surface characterisation for postgraduates in fields such as physics, chemistry, nanotechnology, materials science and engineering. The Australian community will benefit through internationally significant research outcomes leading to, for example, enhanced medical testing technologies, biocompatible medical appliances, better waste water treatment processes, and new battery technologies.Read moreRead less
Novel biomaterials from improved understanding of the structure of starch. The microstructure of starch, comprising two polymers of glucose: amylose (linear, except for a few long branches) and amylopectin (with a complex tree-like architecture), is described by a high-dimensional function. This project examines simplified measures of the full microstructure, such as the distribution of lengths if all links were cut, and also properties which depend on the full architecture, such as viscoelastic ....Novel biomaterials from improved understanding of the structure of starch. The microstructure of starch, comprising two polymers of glucose: amylose (linear, except for a few long branches) and amylopectin (with a complex tree-like architecture), is described by a high-dimensional function. This project examines simplified measures of the full microstructure, such as the distribution of lengths if all links were cut, and also properties which depend on the full architecture, such as viscoelastic response and adhesion. Theory, simulation and neural networks will be used to guide experiments to elucidate which partial structure measures control which property. Outcomes will include means of helping biotechnology create improved biomaterials, and plant breeders to improve food quality.Read moreRead less
Highly ordered and tunable extracellular DNA micro- and nanopatterns for investigating the attachment mechanisms of pseudomonas aeruginosa to surfaces. Preventing infectious bacteria from colonising artificial surfaces is a major scientific challenge. New engineered surfaces will be designed to better understand how the important pathogen Pseudomonas aeruginosa sticks to surfaces, facilitating new ways of reducing infections acquired from the surface of, for example, medical devices.
Single molecule actuators. The study of actuation processes in single molecules will lead to the development of improved advanced materials for Australian industry and, ultimately, to the more futuristic and exciting nanotechnologies. The research will improve our understanding of how polymer artificial muscles function, so that these materials can be further developed to meet the demand from industry. Applications include biomedical devices, robotic applicators and various machine parts. In ....Single molecule actuators. The study of actuation processes in single molecules will lead to the development of improved advanced materials for Australian industry and, ultimately, to the more futuristic and exciting nanotechnologies. The research will improve our understanding of how polymer artificial muscles function, so that these materials can be further developed to meet the demand from industry. Applications include biomedical devices, robotic applicators and various machine parts. In addition, the research will also contribute to one of the greatest promises of nanotechnology: the development of molecular machines. We will demonstrate the mechanical forces and movements possible from single molecules so that the design of useful nano-machines can begin.Read moreRead less
Self-assembly of gelling biopolymer particles. Biopolymers provide a renewable source of structuring agents for a variety of potential uses in food, pharmaceutical and other applications that require bio-compatibility. Swollen biopolymer particles of sub-millimetre size are particularly useful as they combine macroscopic structure formation with an ability to flow and a desirable soft solid texture. Two limitations to the current utilisation of biopolymer particles are that they either cannot be ....Self-assembly of gelling biopolymer particles. Biopolymers provide a renewable source of structuring agents for a variety of potential uses in food, pharmaceutical and other applications that require bio-compatibility. Swollen biopolymer particles of sub-millimetre size are particularly useful as they combine macroscopic structure formation with an ability to flow and a desirable soft solid texture. Two limitations to the current utilisation of biopolymer particles are that they either cannot be predictably produced direct from a dried form, or if they are (e.g. cooked starch granules), there is a lack of scientific understanding that limits use of natural sources without subsequent chemical modification. This project will provide the science & technology to overcome these limitations.Read moreRead less
Degradable hollow microspheres for liver cancer treatment. The expected outcome of this multidisciplinary approach is a controlled drug delivery system for the treatment of liver cancer. We aim to increase the understanding of drug release using polymeric microspheres and the influence of the polymer properties on the release kinetics resulting in the tailored drug release for liver cancer treatment. An indepth knowledge in drug delivery can lead to optimised release kinetics leding to an increa ....Degradable hollow microspheres for liver cancer treatment. The expected outcome of this multidisciplinary approach is a controlled drug delivery system for the treatment of liver cancer. We aim to increase the understanding of drug release using polymeric microspheres and the influence of the polymer properties on the release kinetics resulting in the tailored drug release for liver cancer treatment. An indepth knowledge in drug delivery can lead to optimised release kinetics leding to an increased patient convenience and life prolonging treatments.Read moreRead less
In situ Raman spectroscopic studies of iron and calcium biomaterials in marine chiton teeth. The future of biomaterial science in Australia depends upon the discovery and refinement of new materials. This project characterizes the biomaterials in the feeding apparatus of Australian marine chitons (Mollusca: Polyplacophora). Like many biological structures, chiton teeth are sophisticated composite materials that have been refined by evolution over millions of years. Initially composed of the poly ....In situ Raman spectroscopic studies of iron and calcium biomaterials in marine chiton teeth. The future of biomaterial science in Australia depends upon the discovery and refinement of new materials. This project characterizes the biomaterials in the feeding apparatus of Australian marine chitons (Mollusca: Polyplacophora). Like many biological structures, chiton teeth are sophisticated composite materials that have been refined by evolution over millions of years. Initially composed of the polysaccharide chitin, these extremely hard teeth are mineralized with calcium and iron compounds and used to excavate the rocks on which they live, as they graze for food. Understanding the mechanism of biomineralization is vital for devising synthetic routes to composite materials for industrial purposes.Read moreRead less
Nanostructured materials by controlled photopolymerization. Photo-polymerization is an important and flexible means of converting a crosslinkable monomer into a solid and has application ranging from lens production to photo-lithography. This project aims at developing the technology of producing multi-phase structures of controllable morphology by selective and independent dual photo-polymerization of blends of crosslinkable monomers at controlled rates. These morphologies may have applicatio ....Nanostructured materials by controlled photopolymerization. Photo-polymerization is an important and flexible means of converting a crosslinkable monomer into a solid and has application ranging from lens production to photo-lithography. This project aims at developing the technology of producing multi-phase structures of controllable morphology by selective and independent dual photo-polymerization of blends of crosslinkable monomers at controlled rates. These morphologies may have applications in toughening polymers with minimum loss in strength and optical transparency, abrasion resistant coatings, tissue engineering (where the phases have differing biodegradability), in microfluidics, and microelectro-mechanical systems (where sub-micron channels/domains are required) or in membrane separation.Read moreRead less
Drug Delivery Devices : Hydrogels manufactured utilising Dense Gas Technologies. Many drugs are rapidly eliminated from the human body, and would benefit from being released over a long period of time. In this study, formulations to deliver drugs will be developed, using hydrogels: highly cross-linked, water saturated polymers. The polymers to be investigated are based on ingredients suitable for ingestion. Hydrogels are in common use as external therapeutic devices, such as contact lenses or wo ....Drug Delivery Devices : Hydrogels manufactured utilising Dense Gas Technologies. Many drugs are rapidly eliminated from the human body, and would benefit from being released over a long period of time. In this study, formulations to deliver drugs will be developed, using hydrogels: highly cross-linked, water saturated polymers. The polymers to be investigated are based on ingredients suitable for ingestion. Hydrogels are in common use as external therapeutic devices, such as contact lenses or wound dressings. However, hydrogels are not commonly in use as ingested drug delivery devices due to problems with the existing technologies, such as toxicity of ingredients. These problems will be addressed in this study.Read moreRead less
Carbon Dioxide: Solvent, Carrier and Reagent, for novel polymer networks with controlled nano-architectures. The proposed environmentally friendly technology has broad applications for improving properties of various polymeric matrices used for biomedical applications. The process developed would value-add for manufacturing biomedical polymeric devices in Australia with licensing of existing fabrication methods as a best option. Moreover, the leading-edge polymer technology developed would mini ....Carbon Dioxide: Solvent, Carrier and Reagent, for novel polymer networks with controlled nano-architectures. The proposed environmentally friendly technology has broad applications for improving properties of various polymeric matrices used for biomedical applications. The process developed would value-add for manufacturing biomedical polymeric devices in Australia with licensing of existing fabrication methods as a best option. Moreover, the leading-edge polymer technology developed would minimise the organic solvent consumption and will attract business from international polymer and biotechnology companies for production of implant and drug delivery devices. The development of world-class research provides Australia with recognition as a world leader in the field and broadens the knowledge based of Australian scientist and engineers.Read moreRead less