Special Research Initiatives - Grant ID: SR0354588
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Integrated Nanoscale Biosystems Network (INBN). The INBN will integrate high-priority research, already identified by the ARC, in materials nanoscience and engineering with nanoscale biology. The INBN will provide the means to consolidate world-class multidisciplinary Australian research groups in existing Centres of Excellence, including several Federation Fellows, into a nanobiotechnology focus. The significant outcomes of INBN are the critical mass of outstanding researchers in the nanobiosci ....Integrated Nanoscale Biosystems Network (INBN). The INBN will integrate high-priority research, already identified by the ARC, in materials nanoscience and engineering with nanoscale biology. The INBN will provide the means to consolidate world-class multidisciplinary Australian research groups in existing Centres of Excellence, including several Federation Fellows, into a nanobiotechnology focus. The significant outcomes of INBN are the critical mass of outstanding researchers in the nanobiosciences, facilitation of innovative research to produce novel intellectual property and provision of pathways into collaborative research with international scientists and industry, and the training and development of the next generation scientists for this emerging discipline.
Read moreRead less
Structures and properties of tissue engineering matrices for cartilage and bone: Imaging, visualising and modelling tissue/scaffold constructs in 3D. Tissue engineering of bone and cartilage has the potential to lower costs and improve outcomes. The first stage requires the design of porous 3D scaffolds. To date they have been found less than ideal for clinical applications. Our ability to design and optimise scaffolds has been ad hoc, as local structure and properties have not been measurable ....Structures and properties of tissue engineering matrices for cartilage and bone: Imaging, visualising and modelling tissue/scaffold constructs in 3D. Tissue engineering of bone and cartilage has the potential to lower costs and improve outcomes. The first stage requires the design of porous 3D scaffolds. To date they have been found less than ideal for clinical applications. Our ability to design and optimise scaffolds has been ad hoc, as local structure and properties have not been measurable during tissue growth and repair. In this proposal, an interdisciplinary group from three universities will utilise microCT imaging, visualisation and numerical modelling to determine these structures and properties. This will provide an invaluable understanding for the further development of tissue engineering scaffolds.Read moreRead less
Tissue Engineering the Meniscus: Combining Novel Biomimetic Hybrid Scaffolds with Adult Stem Cells. Development of a meniscal implant ex vivo will provide significant health and economic benefits, given that worldwide, millions of people annually suffer from meniscus damage or loss. We believe that a tissue engineered meniscus, composed of a novel biomimetic scaffold which guides the differentiation of mesenchymal stem cells in a novel bioreactor will provide a solution to the problem of donor ....Tissue Engineering the Meniscus: Combining Novel Biomimetic Hybrid Scaffolds with Adult Stem Cells. Development of a meniscal implant ex vivo will provide significant health and economic benefits, given that worldwide, millions of people annually suffer from meniscus damage or loss. We believe that a tissue engineered meniscus, composed of a novel biomimetic scaffold which guides the differentiation of mesenchymal stem cells in a novel bioreactor will provide a solution to the problem of donor scarcity in meniscal repair. Success in this project will lead directly to large-animal studies and clinical trials. The training of four early careeer researchers involved in this project will also be of significant benefit to the Australian Tissue Engineering and Biomaterials community.Read moreRead less
Scalable, high throughput microfluidic platforms for tissue specific biomaterials development and tissue genesis. The co-development of novel biomaterial platforms and new generation production methods for tissue analogues will provide the necessary stimulus for improved and more relevant methods of enhanced repair or regeneration of diseased or damaged tissues. These outcomes will result in faster time-to-market new generation therapeutic products for Australia and the world. These advances wil ....Scalable, high throughput microfluidic platforms for tissue specific biomaterials development and tissue genesis. The co-development of novel biomaterial platforms and new generation production methods for tissue analogues will provide the necessary stimulus for improved and more relevant methods of enhanced repair or regeneration of diseased or damaged tissues. These outcomes will result in faster time-to-market new generation therapeutic products for Australia and the world. These advances will have a significant impact on our healthcare costs and the quality of life for all Australians.Read moreRead less
Development of Cathodic Arc Plasma Immersion Ion Implantation (PIII) for biomaterials applications. Medical prostheses have intricate geometries, consisting of shapes such as screws, holes, wedges, cones and textured surfaces. Plasma Immersion Ion Implantation using metal or carbon ions produced by a cathodic arc has been found to be an excellent process for producing surface modification with the properties required in medical applications, such as low stress and excellent adhesion of very thic ....Development of Cathodic Arc Plasma Immersion Ion Implantation (PIII) for biomaterials applications. Medical prostheses have intricate geometries, consisting of shapes such as screws, holes, wedges, cones and textured surfaces. Plasma Immersion Ion Implantation using metal or carbon ions produced by a cathodic arc has been found to be an excellent process for producing surface modification with the properties required in medical applications, such as low stress and excellent adhesion of very thick coatings. To date this process has only been applied to simple, flat substrates. Extending it to shapes of interest for biomaterials applications will require comprehensive understanding and control of the sheath dynamics, which our combined theoretical and experimental approach will provide.Read moreRead less
Novel manufacturing methods for tissue engineering scaffolds. Novel methods of manufacturing biodegradable polymer scaffolds around which new tissue can be grown within the human body will be developed. Surfactant - polymer assemblies will be used to produce highly porous scaffolds of tunable pore size and connectivity, shape and strength. The results will create a new avenue for systematic investigations into the effects of scaffold structure on tissue growth. This research will lead to the dev ....Novel manufacturing methods for tissue engineering scaffolds. Novel methods of manufacturing biodegradable polymer scaffolds around which new tissue can be grown within the human body will be developed. Surfactant - polymer assemblies will be used to produce highly porous scaffolds of tunable pore size and connectivity, shape and strength. The results will create a new avenue for systematic investigations into the effects of scaffold structure on tissue growth. This research will lead to the development of reliable, well-controlled manufacturing techniques for tissue engineering scaffolds, revolutionising current scaffold manufacturing practices. It will enhance existing collaborations between the University of Melbourne and the Bernard O'Brien Institute of Microsurgery.Read moreRead less
In situ Raman spectroscopic studies of iron and calcium biomaterials in marine chiton teeth. The future of biomaterial science in Australia depends upon the discovery and refinement of new materials. This project characterizes the biomaterials in the feeding apparatus of Australian marine chitons (Mollusca: Polyplacophora). Like many biological structures, chiton teeth are sophisticated composite materials that have been refined by evolution over millions of years. Initially composed of the poly ....In situ Raman spectroscopic studies of iron and calcium biomaterials in marine chiton teeth. The future of biomaterial science in Australia depends upon the discovery and refinement of new materials. This project characterizes the biomaterials in the feeding apparatus of Australian marine chitons (Mollusca: Polyplacophora). Like many biological structures, chiton teeth are sophisticated composite materials that have been refined by evolution over millions of years. Initially composed of the polysaccharide chitin, these extremely hard teeth are mineralized with calcium and iron compounds and used to excavate the rocks on which they live, as they graze for food. Understanding the mechanism of biomineralization is vital for devising synthetic routes to composite materials for industrial purposes.Read moreRead less
Fracture Mechanics of Functionally Graded Materials: Coupled Thermoelectromechanical Problems. The primary goal of this project is to develop mathematical and computational models and techniques that are capable of novel design of functionally graded materials and structures that can dramatically increase the performance and reliability of artificial structures and devices. The applications areas are broad: from lightweight thermal protective coatings used in high-temperature environments to bio ....Fracture Mechanics of Functionally Graded Materials: Coupled Thermoelectromechanical Problems. The primary goal of this project is to develop mathematical and computational models and techniques that are capable of novel design of functionally graded materials and structures that can dramatically increase the performance and reliability of artificial structures and devices. The applications areas are broad: from lightweight thermal protective coatings used in high-temperature environments to biological hard tissues like bones and teeth. Efficient numerical methods will be developed to overcome difficulties encountered in material properties and loading conditions. The project will provide useful guidelines to design new, intelligent, multi-phase material systems, including biomaterial systems for biomedical applications.Read moreRead less
Engineering of cartilage-based biomaterials under dynamic culture conditions. This work contributes to the development of advanced technologies in the area of biomaterials. The cartilage biomaterials generated in this work will lead to new medical applications in tissue reconstruction and replacement, which is of direct benefit to society by improving the methods used to treat joint disease and injury. As there is a significant commercial market for tissue-engineered cartilage products, this res ....Engineering of cartilage-based biomaterials under dynamic culture conditions. This work contributes to the development of advanced technologies in the area of biomaterials. The cartilage biomaterials generated in this work will lead to new medical applications in tissue reconstruction and replacement, which is of direct benefit to society by improving the methods used to treat joint disease and injury. As there is a significant commercial market for tissue-engineered cartilage products, this research also has implications for enhancing the scope and profitability of the Australian biotechnology industry. The project will be a vehicle for research training in a broad range of interdisciplinary areas. Students involved in the work will be equipped with a versatile and valuable combination of skills.Read moreRead less