Designed Delivery - Novel Hydrogels for Drug Delivery from Precisely-Structured Networks. This project will lead to the development of new biodegradable biomaterials ideally suited to many applications in drug delivery and tissue engineering. The understanding of their properties will be built on comprehensive models for diffusion of molecules through the material. The availability of these new biomaterials will facilitate future developments in drug delivery, and will ultimately lead to improve ....Designed Delivery - Novel Hydrogels for Drug Delivery from Precisely-Structured Networks. This project will lead to the development of new biodegradable biomaterials ideally suited to many applications in drug delivery and tissue engineering. The understanding of their properties will be built on comprehensive models for diffusion of molecules through the material. The availability of these new biomaterials will facilitate future developments in drug delivery, and will ultimately lead to improved medical outcomes in many areas such as tissue and bone regeneration. The materials designed in this project will help position the Australian biotechnology and pharmaceutical industries to take advantage of the more than $100B USD market (US alone; growth ~ 10% p.a.) in drug delivery.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453637
Funder
Australian Research Council
Funding Amount
$256,804.00
Summary
Multi-dimensional polymer characterization facility. The microstructure of polymers dominates their physical properties. This integrated facility will create a world-leading means of characterizing in multiple dimensions the microstructure of complex polymers, eg copolymers and branched polymers. The facility will yield information on the distributions of chain end-groups, monomer microstructure, and branches, as functions of molecular weight. The facility will provide otherwise unobtainable dat ....Multi-dimensional polymer characterization facility. The microstructure of polymers dominates their physical properties. This integrated facility will create a world-leading means of characterizing in multiple dimensions the microstructure of complex polymers, eg copolymers and branched polymers. The facility will yield information on the distributions of chain end-groups, monomer microstructure, and branches, as functions of molecular weight. The facility will provide otherwise unobtainable data for a set of projects exploring questions ranging from how new synthetic materials with tailor-made properties can be created, through to how our understanding of natural polymers can be advanced to improve crop utilization.Read moreRead less
Why is ColorbondR steel greener on the other side of the fence? Designing additives to retard weathering of surface coatings. COLORBONDR steel, the flagship pre-painted steel product of BlueScope Steel Limited, has become an iconic part of both suburban and outback landscapes whether installed as roofing, walling or water conservation accessories (tanks, down-pipes etc). This proposal aims to provide a detailed understanding of molecular level changes in COLORBONDR steel surface coatings brought ....Why is ColorbondR steel greener on the other side of the fence? Designing additives to retard weathering of surface coatings. COLORBONDR steel, the flagship pre-painted steel product of BlueScope Steel Limited, has become an iconic part of both suburban and outback landscapes whether installed as roofing, walling or water conservation accessories (tanks, down-pipes etc). This proposal aims to provide a detailed understanding of molecular level changes in COLORBONDR steel surface coatings brought about by levels of heat and radiation encountered in-service. These insights will lead to further improvements in both lifetime and aesthetic durability of COLORBONDR steel, ensuring continuing economic success of BlueScope in the domestic building market with consequent benefits to manufacturing communities throughout the supply-chain nationwide.Read moreRead less
Switchable interfaces. The discovery project will challenge some of the most demanding issues regarding adhesion and molecular separation: - Surfaces that can release/prevent bio-film formation can provide novel solutions for corrosion-protection, implants, anti-fouling in medical devices as well as in industrial piping and reactors. - Materials for separation on the molecular level, which can bring new possibilities for fast and selective processes to the pharmaceutical industry. The novel comb ....Switchable interfaces. The discovery project will challenge some of the most demanding issues regarding adhesion and molecular separation: - Surfaces that can release/prevent bio-film formation can provide novel solutions for corrosion-protection, implants, anti-fouling in medical devices as well as in industrial piping and reactors. - Materials for separation on the molecular level, which can bring new possibilities for fast and selective processes to the pharmaceutical industry. The novel combination of the two materials research fields - plasma-polymerisation and electroactive materials- will lead to an international capability at the forefront of separation and adhesion research.Read moreRead less
Novel Fuel-Cell Structures based on Electroactive Polymers. The Discovery Project will tackle some of the challenging issues regarding the conversion of our society into a post-petroleum era through: Development and understanding of a new class of organic catalysts for efficient low temperature fuel-cells; Developing cheap and effective, ultra-thin, ion-conducting membranes for fuel-cells based on new plasma-polymers; and Integrating the components into fuel-cells suitable for stationary, portab ....Novel Fuel-Cell Structures based on Electroactive Polymers. The Discovery Project will tackle some of the challenging issues regarding the conversion of our society into a post-petroleum era through: Development and understanding of a new class of organic catalysts for efficient low temperature fuel-cells; Developing cheap and effective, ultra-thin, ion-conducting membranes for fuel-cells based on new plasma-polymers; and Integrating the components into fuel-cells suitable for stationary, portable and automotive applications. These outcomes will contribute to national research priorities: Frontier Technologies for building and transforming Australian Industries, and An Environmentally Sustainable Australia.
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Nanogels: Next Generation Polymeric Particles. The existing knowledge in the formation of polymeric networks limits the technological development of polymer materials. This project will introduce new polymeric particles, called nanogels to open a new area in new polymeric architecture research. A number of new structures based on the nanogels will be developed. These new macromolecules will not only bring the polymer science into a new field, it will provide a great opportunity to discover the ....Nanogels: Next Generation Polymeric Particles. The existing knowledge in the formation of polymeric networks limits the technological development of polymer materials. This project will introduce new polymeric particles, called nanogels to open a new area in new polymeric architecture research. A number of new structures based on the nanogels will be developed. These new macromolecules will not only bring the polymer science into a new field, it will provide a great opportunity to discover the next generation of the polymeric products, particularly for application in automotive paint, drug delivery and bio-molecular separations.Read moreRead less
Calcification of acrylic hydrogels in abiotic media: mechanism and control. Poly(2-hydroxyethyl methacrylate (PHEMA) and other acrylic hydrogels are extensively used as biomaterials, yet conclusive evidence exists that they have a propensity to calcify following implantation. This process has undesirable consequences on the functionality of various prostheses. Based on preliminary observations that PHEMA can promote the deposition of calcium minerals from media devoid of biological factors, whic ....Calcification of acrylic hydrogels in abiotic media: mechanism and control. Poly(2-hydroxyethyl methacrylate (PHEMA) and other acrylic hydrogels are extensively used as biomaterials, yet conclusive evidence exists that they have a propensity to calcify following implantation. This process has undesirable consequences on the functionality of various prostheses. Based on preliminary observations that PHEMA can promote the deposition of calcium minerals from media devoid of biological factors, which appears thus to be an inherent property of the polymer, the project aims at formulating new hypotheses to explain this phenomenon, and to confirm them experimentally. The "chelation" hypothesis will be validated by modifying the structure of polymers, and the "spontaneous precipitation" hypothesis by assessing the effect of solutes on the equilibrium water content of polymers. NMR and FTIR spectrometric techniques will be used to gain further insight into the mechanism of calcification. Methods to prevent the calcification will potentially result from these experiments, however, anticalcification agents will also be incorporated into hydrogels and their effect evaluated in calcification assays.Read moreRead less
Biodegradable Porous HEMA-Based Polymers: Innovative Strategies for the Design and Tuneable Single-Step Production of a Novel Class of Scaffolds for Tissue Engineering. This project will lead to the development of new biocompatible, biodegradable, porous materials ideally suited to many applications in tissue engineering. These new biomaterials will be relatively inexpensive to manufacture, via simple processes using non-toxic reagents. The key properties of the biomaterials will be controllable ....Biodegradable Porous HEMA-Based Polymers: Innovative Strategies for the Design and Tuneable Single-Step Production of a Novel Class of Scaffolds for Tissue Engineering. This project will lead to the development of new biocompatible, biodegradable, porous materials ideally suited to many applications in tissue engineering. These new biomaterials will be relatively inexpensive to manufacture, via simple processes using non-toxic reagents. The key properties of the biomaterials will be controllable by appropriate choice of starting materials. The availability of these new biomaterials will facilitate future developments in tissue engineering, which will ultimately lead to improved medical outcomes in areas as diverse as joint and bone repair and organ regeneration. Local manufacture of these biomaterials would also contribute to the development of the Australian biotechnology industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882576
Funder
Australian Research Council
Funding Amount
$588,000.00
Summary
Polymer Characterization Facility (PCF). Future development of macromolecular and biotechnologies have the potential to revolutionize everyday life. Current applications include plastics for engineering, diagnostic devices for biochemical analysis, polymer therapeutics for drug delivery and prosthesis with specific functions. The proposed facility will provide the analytical tools required to probe and develop advanced materials with application in medicine, agriculture, composites, cosmetics, ....Polymer Characterization Facility (PCF). Future development of macromolecular and biotechnologies have the potential to revolutionize everyday life. Current applications include plastics for engineering, diagnostic devices for biochemical analysis, polymer therapeutics for drug delivery and prosthesis with specific functions. The proposed facility will provide the analytical tools required to probe and develop advanced materials with application in medicine, agriculture, composites, cosmetics, communications and electronics.Read moreRead less
Towards Nano-Assembled Light Emitting Polymer Films. Advanced materials constructed with molecular level architecture through controlled nano-assembly will benefit medical science, biotechnology and nanotechnology, communications and the electronics fields. The national research priorities of nanotechnology and advanced materials through nano-assembly will be promoted by this work. This research will assist Australian industries to further advance these processes and devices leading to better qu ....Towards Nano-Assembled Light Emitting Polymer Films. Advanced materials constructed with molecular level architecture through controlled nano-assembly will benefit medical science, biotechnology and nanotechnology, communications and the electronics fields. The national research priorities of nanotechnology and advanced materials through nano-assembly will be promoted by this work. This research will assist Australian industries to further advance these processes and devices leading to better quality, cheaper, more efficient products. The Australian community will benefit through economic and technological advances. These advanced materials will promote health and environmental wellbeing.Read moreRead less