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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
Dynamics of Photon-Induced Processes in Engineered Polymer Systems. This project will investigate photo-induced energy and electron transport in innovative polymer systems of well defined structure. New functionalised, aromatic and conjugated polymers will be synthesised and studied by ultrafast laser spectroscopic techniques. Information on the dynamics of light energy dissipation processes in these polymers on time-scales down to the femtosecond regime and at a single molecule level will be ....Dynamics of Photon-Induced Processes in Engineered Polymer Systems. This project will investigate photo-induced energy and electron transport in innovative polymer systems of well defined structure. New functionalised, aromatic and conjugated polymers will be synthesised and studied by ultrafast laser spectroscopic techniques. Information on the dynamics of light energy dissipation processes in these polymers on time-scales down to the femtosecond regime and at a single molecule level will be obtained. The results will provide the basic information required to develop novel photon-active materials and devices.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
Materials World Network Synthesis and Processing Optoelectronic Materials in Supercritical and Condensed Phase Carbon Dioxide. The Australian partner will have leveraged access to the skill base and facilities of the Cornell Center for Materials Research, and the NSF MRSEC that leads the world in frontier technologies in advanced materials. The partnership will deliver to Australia progress in national priority goals "Frontier Technologies" and new manufacturing technologies in environmentally ....Materials World Network Synthesis and Processing Optoelectronic Materials in Supercritical and Condensed Phase Carbon Dioxide. The Australian partner will have leveraged access to the skill base and facilities of the Cornell Center for Materials Research, and the NSF MRSEC that leads the world in frontier technologies in advanced materials. The partnership will deliver to Australia progress in national priority goals "Frontier Technologies" and new manufacturing technologies in environmentally friendly media that will enhance the national research priority "An Environmentally Sustainable Australia". New transferable skills will be acquired by the participants in the project. Technology transfer could result in the formation of spinoff companies to exploite the intellectual property arising in the project.Read moreRead less
Graft copolymers from starch and synthetic monomers. Polymer dispersions, manufactured as latexes in large quantities in Australia and elsewhere, have myriad applications, such as in adhesives, bitumen modifiers, paints and paper coatings. This project will create the enabling science to replace by starch the current synthetic products used to stop these dispersions from coagulating. This will create new uses for renewable resources and will reduce environmental insult by avoiding the leaching o ....Graft copolymers from starch and synthetic monomers. Polymer dispersions, manufactured as latexes in large quantities in Australia and elsewhere, have myriad applications, such as in adhesives, bitumen modifiers, paints and paper coatings. This project will create the enabling science to replace by starch the current synthetic products used to stop these dispersions from coagulating. This will create new uses for renewable resources and will reduce environmental insult by avoiding the leaching of biologically incompatible chemicals. By using starch from crops suited for Australia's arid climate, the new technology will reduce both our dependence on imported products and our greenhouse gas emissions.Read moreRead less
The development of unique cyclic polymers. The project will yield cyclic polymers with a large range of commercial and industrial applications (e.g. drug delivery, contamination clean-up, nano-wires, sensors) that will result in positive economic and social benefits for Australia. The research will lead to increased employment opportunities within the manufacturing industry and R&D, and also underpin and extend Australia's leading position in the development of innovative polymeric and advanced ....The development of unique cyclic polymers. The project will yield cyclic polymers with a large range of commercial and industrial applications (e.g. drug delivery, contamination clean-up, nano-wires, sensors) that will result in positive economic and social benefits for Australia. The research will lead to increased employment opportunities within the manufacturing industry and R&D, and also underpin and extend Australia's leading position in the development of innovative polymeric and advanced materials. The resulting materials will provide new and improved technological innovations for commercial products, delivering benefits direct to the public. Furthermore, there is potential development of spin-off companies - leading to further investment in Australian science and industry.Read moreRead less
Improving Energy Efficiency through Cool Polymers in Building Materials. The advantages of using cool polymers in industrial applications such as building materials are significant. Cooler buildings are a positive contribution to our global environment with reductions in urban heat and smog through energy efficiency. Moreover, by reducing the overall temperature of the surface coating through inclusion and optimization of IR-reflective pigments, this should lead to polymers which are more durabl ....Improving Energy Efficiency through Cool Polymers in Building Materials. The advantages of using cool polymers in industrial applications such as building materials are significant. Cooler buildings are a positive contribution to our global environment with reductions in urban heat and smog through energy efficiency. Moreover, by reducing the overall temperature of the surface coating through inclusion and optimization of IR-reflective pigments, this should lead to polymers which are more durable when exposed in exterior environments. It is anticipated that the results from this work will have direct impact on the Australian paint market and potentially the commercial and residential building industries of Australia, combined with obvious economic benefits.Read moreRead less
Performance Chemistry of Thermoset Surface Coatings. Surface coatings employed in the COLORBOND® range of pre-painted steel products are remarkable materials that are warranted against fading, peeling and cracking for 25 years. Unfortunately, the desired durability can never be uniform across all applications and performance failures do occur and are costly. Classic durability testing often provides misleading information. This project aims to develop a sound mechanistic model for polyester-is ....Performance Chemistry of Thermoset Surface Coatings. Surface coatings employed in the COLORBOND® range of pre-painted steel products are remarkable materials that are warranted against fading, peeling and cracking for 25 years. Unfortunately, the desired durability can never be uniform across all applications and performance failures do occur and are costly. Classic durability testing often provides misleading information. This project aims to develop a sound mechanistic model for polyester-isocyanate performance chemistry and to develop strategies for 'superdurable polyester' formulations based on these findings. This research will provide recommendations to BHP Coated Steel Australia on adoption of isocyanate based technology in the COLORBOND® range of products.Read moreRead less
New Electron Field Emission Films Based on Aligned Carbon Nanotube Guests in Liquid Crystalline Polymer Hosts. This project seeks to develop a new class of electron field emitting nanocomposite consisting of nanotubes in liquid crystalline polymers. Electron emitting materials are in much demand in x-ray and microwave generation, computer displays and low-energy lighting. We utilise the ready alignability of liquid crystalline units in magnetic fields to cause realignment of incorporated carbon ....New Electron Field Emission Films Based on Aligned Carbon Nanotube Guests in Liquid Crystalline Polymer Hosts. This project seeks to develop a new class of electron field emitting nanocomposite consisting of nanotubes in liquid crystalline polymers. Electron emitting materials are in much demand in x-ray and microwave generation, computer displays and low-energy lighting. We utilise the ready alignability of liquid crystalline units in magnetic fields to cause realignment of incorporated carbon nanotubes, followed by polymer solidification to maintain orientation. It involves low temperature processing, contrasting very favourably with current problematic, high temperature processes. This allows materials to be cast on flexible polymer substrates, potentially enabling construction of cathode tubes to replace existing mercury-containing fluorescent lighting.Read moreRead less
Novel Nanofibre-Templated Nanotubes Prepared by Using ABA Block Copolymers. The aim of this project is to prepare new, highly functional nanomaterials using layer-by-layer assembly of polyelectrolytes on a three-dimensional template. Using this approach, a core-shell fibre is initially prepared by alternate deposition of oppositely charged materials onto an electrospun fibre template. The initial fibre can then be dissolved to give hollow nanotubes. New block copolymers, incorporating both charg ....Novel Nanofibre-Templated Nanotubes Prepared by Using ABA Block Copolymers. The aim of this project is to prepare new, highly functional nanomaterials using layer-by-layer assembly of polyelectrolytes on a three-dimensional template. Using this approach, a core-shell fibre is initially prepared by alternate deposition of oppositely charged materials onto an electrospun fibre template. The initial fibre can then be dissolved to give hollow nanotubes. New block copolymers, incorporating both charged and uncharged domains, will be used in the assembly, in order to design tubes with novel properties. The behaviour of these tubes under a variety of pH and solvent conditions will then be examined, and the tubes characterized using various microscopy techniques.Read moreRead less