Three dimensional polymer structures for bionic applications. The polymer based three dimensional (3D) structures targeted for production in this project will bring unique capabilities to the field of bionics research. A multi-modal 3D scaffold capable of delivering biofactors, supporting cell growth and providing power for stimulation will significantly advance the efforts being made in bionic research. This will have profound effects on the quality of life for those suffering from a range of m ....Three dimensional polymer structures for bionic applications. The polymer based three dimensional (3D) structures targeted for production in this project will bring unique capabilities to the field of bionics research. A multi-modal 3D scaffold capable of delivering biofactors, supporting cell growth and providing power for stimulation will significantly advance the efforts being made in bionic research. This will have profound effects on the quality of life for those suffering from a range of medical conditions, from spinal cord injury through to epilepsy. Here we will demonstrate the capabilities of these novel polymer structures both in-vitro and in-vivo.Read moreRead less
Disruptive approaches to biological sensing. Optical fibre-based biosensors have the potential to transform our ability to monitor our environment, protect our nation's assets and safeguard our citizens, and to offer improved clinical diagnostics and food quality control by creating tools that can detect biomolecules in real-time within complex samples. To fulfil this mission, we propose to develop new fibre-based sensing architectures for sensing biomolecules that have the potential to be sensi ....Disruptive approaches to biological sensing. Optical fibre-based biosensors have the potential to transform our ability to monitor our environment, protect our nation's assets and safeguard our citizens, and to offer improved clinical diagnostics and food quality control by creating tools that can detect biomolecules in real-time within complex samples. To fulfil this mission, we propose to develop new fibre-based sensing architectures for sensing biomolecules that have the potential to be sensitive, selective, fast and compact.Read moreRead less
Nanoengineered Polymeric Materials for Environmental and Biological Applications. The development of advanced materials with nanoengineered properties promises to revolutionise future industries, including the energy and healthcare sectors. This research program will involve the design, synthesis and assembly of tailored polymers to prepare next-generation, engineered materials. The research will deliver advanced polymeric membranes, tissue engineering scaffolds and vaccine delivery systems. The ....Nanoengineered Polymeric Materials for Environmental and Biological Applications. The development of advanced materials with nanoengineered properties promises to revolutionise future industries, including the energy and healthcare sectors. This research program will involve the design, synthesis and assembly of tailored polymers to prepare next-generation, engineered materials. The research will deliver advanced polymeric membranes, tissue engineering scaffolds and vaccine delivery systems. These materials are expected to provide benefits for Australian citizens in the energy and health sectors and contribute to the development of a robust Australian nanotechnology industry. The projects will also provide opportunities for the development of outstanding young scientists and will foster multidisciplinary collaborations.Read moreRead less