Hermetic bonding of biomedical polymers for cardiac-assist devices. The use of a polymeric ventricular assist device will bring a much better quality of life to patients with end-stage heart failure. The project will address the remaining challenge, the creation of a hermetic polymer seal, enabling the development of a small, light and highly efficient heart pump. The project has the potential to improve the lives of many Australians as our demographic profile shifts towards older people. Patie ....Hermetic bonding of biomedical polymers for cardiac-assist devices. The use of a polymeric ventricular assist device will bring a much better quality of life to patients with end-stage heart failure. The project will address the remaining challenge, the creation of a hermetic polymer seal, enabling the development of a small, light and highly efficient heart pump. The project has the potential to improve the lives of many Australians as our demographic profile shifts towards older people. Patients with advanced heart failure will live longer, with a higher quality of life. It will assist heart failure sufferers to remain productive members of our community, because many people who use the device will be fit to return to work.Read moreRead less
Synthesis of Novel Biomaterials for Drug delivery. A new UV radiation polymerisation technique utilising charge-transfer complexes is adopted for synthesising novel hydrogels, a group of biomaterials for drug delivery. This work is significant as charge-transfer complexes, pertinent to the formation of hydrogels, form copolymers within the hydrogel matrices. This eliminates using costly, yet undesirable photo-initiators (PI), thus rendering the hydrogels as cleaner (PI-free) and more economical ....Synthesis of Novel Biomaterials for Drug delivery. A new UV radiation polymerisation technique utilising charge-transfer complexes is adopted for synthesising novel hydrogels, a group of biomaterials for drug delivery. This work is significant as charge-transfer complexes, pertinent to the formation of hydrogels, form copolymers within the hydrogel matrices. This eliminates using costly, yet undesirable photo-initiators (PI), thus rendering the hydrogels as cleaner (PI-free) and more economical in production; the products present themselves as ideal treatment methods in the controlled-release of drugs, specifically targeting localised pathological sites of interest. The research findings will be invaluable to medical practices, leading to the creation of new industries in Australia.
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Development and characterisation of novel hydrogel systems for drug delivery. The aims of this project are to develop and characterise hydrogel formulations for delivery of active agents, such as protein drugs, and to examine the biological responses to drug loaded hydrogels. In many medical and industrial fields, it is advantageous to control the release of active agents. Controlled release can decrease the dose of active that must be administered, sustain a more constant level of the agent ....Development and characterisation of novel hydrogel systems for drug delivery. The aims of this project are to develop and characterise hydrogel formulations for delivery of active agents, such as protein drugs, and to examine the biological responses to drug loaded hydrogels. In many medical and industrial fields, it is advantageous to control the release of active agents. Controlled release can decrease the dose of active that must be administered, sustain a more constant level of the agent in the environment and can localise the agent at the site where it is needed. This project will advance the theoretical knowledge of polymer degradation combined with protein release, will develop controlled release hydrogel technology that can be applied to medical devices and will train a postgraduate student in biomaterials and drug delivery.Read moreRead less
Computational Scaffold Optimisation for Tissue Engineering. Due to exceptional potential, tissue engineering has attracted over US$4.5 billion research and development investment and another US$2.6 billion market capital since 1990. It is important to cement Australia's position in such a highly competitive field. This project aims to develop a novel technology for scaffold-based tissue engineering, which would help Australia lead in the relevant area and increase its competitiveness in the futu ....Computational Scaffold Optimisation for Tissue Engineering. Due to exceptional potential, tissue engineering has attracted over US$4.5 billion research and development investment and another US$2.6 billion market capital since 1990. It is important to cement Australia's position in such a highly competitive field. This project aims to develop a novel technology for scaffold-based tissue engineering, which would help Australia lead in the relevant area and increase its competitiveness in the future global market of biomaterials, tissue products, biomedical software and instruments. An enormous socio-economic benefit to Australia would be a significant improvement in the clinical success rate for our ageing population. Read moreRead less