Understanding the interaction between wool fibre surface and ionic liquids. This project will advance the knowledge on wool surface/ionic liquid interaction, which has the potential to revolutionize the traditional and environmentally unfriendly wool shrinkage-proof treatment technology. This will have significant industry wide benefit for the multi-billion dollar animal fibre industry.
Advanced three-dimensional fibrous structures for vascular graft applications. This project will combine advanced three-dimensional fabric structures, surface functionalisation and haemodynamic modelling to tackle critical issues in the design and manufacture of vascular graft materials. It will lead to the next generation of vascular grafts with much enhanced structural and biomedical performance.
Fibrous fabrics with differential transplanar transport properties for moisture and water. The project develops a framework for the development of fibrous fabrics with desired differential transplanar transport properties for moisture and water, integrating various transport mechanisms with hierarchical microstructures of the fabrics. The results will lead to the development of new fabrics for the local and overseas apparel industry.
Fibre-sized energy generators and storage in multi-functional fabrics. This project proposes to do away with conventional batteries for powering portable or wearable devices by developing wearable fabrics capable of energy generation. The outcome will be a robust fabric with the capability of powering wearable or portable devices in the communications, health-care, sports and defence industries.
Engineering a silk fibroin based ear drum with optimum acoustic properties. This project will use new silk fibroin materials to develop ear drums with improved acoustic properties. This will lead to significant improvement in the quality of life of nearly 2.5 million people in Australia who are affected by hearing loss and further strengthen Australia's leading position in this area.
Short silk nanofibre based 3D scaffolds with enhanced biomimicry. This project aims to understand the behaviour of haematopoietic stem cells (HSC) in novel 3D scaffolds based on short silk nanofibres. This will lead to highly functional 3D scaffolding materials that support efficient HSC renewal in vitro. This project aims to overcome the key problem with existing in vitro systems, which lack the morphological and biochemical complexities of native HSC-niche. Since haematopoietic stem cells are ....Short silk nanofibre based 3D scaffolds with enhanced biomimicry. This project aims to understand the behaviour of haematopoietic stem cells (HSC) in novel 3D scaffolds based on short silk nanofibres. This will lead to highly functional 3D scaffolding materials that support efficient HSC renewal in vitro. This project aims to overcome the key problem with existing in vitro systems, which lack the morphological and biochemical complexities of native HSC-niche. Since haematopoietic stem cells are the precursors to all blood cells, this project has the potential of engineering a high yield artificial ‘blood factory’, which will help save the lives of many thousands of people who rely on bone marrow transplants to treat life-threatening illness such as leukaemia.Read moreRead less
Directional fluid-transfer in thin porous materials with gradient wettability through thickness. This project will further strengthen Australia's world leading position in advanced fibrous materials research. It will provide a new platform technology to develop self-driven unidirectional fluid-transfer fabrics and porous membranes for diverse applications in daily life, healthcare, defence and a number of industrial processes.
Mechanical advantage: biomimetic artificial muscles for micro-machines. This project will develop better ways to operate miniature machines by copying the way that muscle operates in Nature. The outcome will be important for portable devices like digital cameras that need small, efficient motors. The artificial muscles developed in this project may also be used in medical prosthetics and more agile robots.