Synthesis and Functionalisation of Advanced Polymer Films and Particles. Scientific and technological advances at the frontiers of nano- and biotechnology are poised to revolutionise the scope of treatment and healthcare options. This project will involve the synthesis of engineered polymer building blocks with the capability for multifunctional and intelligent response. These smart polymers will then be assembled into responsive nanostructured materials for drug delivery and biosensing applica ....Synthesis and Functionalisation of Advanced Polymer Films and Particles. Scientific and technological advances at the frontiers of nano- and biotechnology are poised to revolutionise the scope of treatment and healthcare options. This project will involve the synthesis of engineered polymer building blocks with the capability for multifunctional and intelligent response. These smart polymers will then be assembled into responsive nanostructured materials for drug delivery and biosensing applications. These materials are expected to have health benefits for Australian citizens and will contribute to a world-leading nanobiotechnology industry. The project will also provide development opportunities for young scientists and will also foster multidisciplinary collaborations within both Australia and abroad.Read moreRead less
Switching the light on cartilage repair. Osteoarthritis is a leading cause of pain and disability in adults and affects 15 per cent of the Australian population. This project will develop a revolutionary new approach to treat joint disorders using smart materials and stem cells. The novel materials and techniques developed will help Australia maintain its leading edge in biotechnology.
Engineering drug transportation behaviour in polymeric gel systems. In collaboration with Seagull Technologies, this project aims to engineer, study and mathematically model ultrasound-assisted biomacromolecule transport behaviour within polymeric gel systems, which may be useful in new drug delivery methods. The intended outcome is a novel set of polymeric gel systems, which can reversibly bind a wide variety of drugs (small molecules, nucleic acid based drugs, proteins), in which drug release ....Engineering drug transportation behaviour in polymeric gel systems. In collaboration with Seagull Technologies, this project aims to engineer, study and mathematically model ultrasound-assisted biomacromolecule transport behaviour within polymeric gel systems, which may be useful in new drug delivery methods. The intended outcome is a novel set of polymeric gel systems, which can reversibly bind a wide variety of drugs (small molecules, nucleic acid based drugs, proteins), in which drug release is triggered by an electric potential and drug transport is controlled by means of sonophoresis. The main advantage of drug delivery via sonophoresis is elimination of risks associated with injections such as infection and damage to local tissue, and elimination of patient discomfort, pain and fear.Read moreRead less
Precision porous polymer microparticles via integrated flow processes. This project aims at a step-change in functional, porous microparticle manufacture. To achieve this, the project will use precision flow chemistry techniques that will integrate emulsion preparation, microparticle production and chemical functionalisation in one continuous process. The expected outcome of the project is a process for the manufacture of a suite of designer porous polymer microparticles. Expected benefits are d ....Precision porous polymer microparticles via integrated flow processes. This project aims at a step-change in functional, porous microparticle manufacture. To achieve this, the project will use precision flow chemistry techniques that will integrate emulsion preparation, microparticle production and chemical functionalisation in one continuous process. The expected outcome of the project is a process for the manufacture of a suite of designer porous polymer microparticles. Expected benefits are disruptive advances in a number of key technological sectors, including biomedicine, pharmacy, energy and bioprocessing. Platform technology for cartilage tissue engineering has been chosen as an exemplar of the power of precision microparticles.Read moreRead less