Generation of peptidomimetic surfaces for biomaterials applications. Biomedical implants are increasingly being used for the treatment of a variety of ailments. This project will significantly contribute to the development of these bioengineered constructs, by introducing an innovative method for tailoring the nature of the surface of these materials with structures that mimic the response of biological surfaces. This technology has the potential to promote favourable interactions of cells with ....Generation of peptidomimetic surfaces for biomaterials applications. Biomedical implants are increasingly being used for the treatment of a variety of ailments. This project will significantly contribute to the development of these bioengineered constructs, by introducing an innovative method for tailoring the nature of the surface of these materials with structures that mimic the response of biological surfaces. This technology has the potential to promote favourable interactions of cells with biomedical implants, and an initial targeted application will be to use these bioengineered constructs in the treatment of preventable blindness and severe visual impairment, afflictions which affect over 180 million individuals worldwide.Read moreRead less
Characterization and optimisation of Myomatrix: A novel extracellular matrix hydrogel from muscle. This project would have several sources of benefit for the community. Foremost we will have produced a product that will have a strong commercial application in several fields including basic science and bioengineering. If its full potential were achieved, the development of this innovative new hydrogel would strengthen Australia's standing in the biotechnology field and also enrich specific applic ....Characterization and optimisation of Myomatrix: A novel extracellular matrix hydrogel from muscle. This project would have several sources of benefit for the community. Foremost we will have produced a product that will have a strong commercial application in several fields including basic science and bioengineering. If its full potential were achieved, the development of this innovative new hydrogel would strengthen Australia's standing in the biotechnology field and also enrich specific applications. The knowledge gained from the characterization of this product could also be of benefit to several areas including chemical engineering, tissue engineering, tissue repair, polymer chemistry and food manufacture. The expertise generated and the possibility of collaboration, both academic and with industry would also benefit the community. Read moreRead less
Biodegradable Porous HEMA-Based Polymers: Innovative Strategies for the Design and Tuneable Single-Step Production of a Novel Class of Scaffolds for Tissue Engineering. This project will lead to the development of new biocompatible, biodegradable, porous materials ideally suited to many applications in tissue engineering. These new biomaterials will be relatively inexpensive to manufacture, via simple processes using non-toxic reagents. The key properties of the biomaterials will be controllable ....Biodegradable Porous HEMA-Based Polymers: Innovative Strategies for the Design and Tuneable Single-Step Production of a Novel Class of Scaffolds for Tissue Engineering. This project will lead to the development of new biocompatible, biodegradable, porous materials ideally suited to many applications in tissue engineering. These new biomaterials will be relatively inexpensive to manufacture, via simple processes using non-toxic reagents. The key properties of the biomaterials will be controllable by appropriate choice of starting materials. The availability of these new biomaterials will facilitate future developments in tissue engineering, which will ultimately lead to improved medical outcomes in areas as diverse as joint and bone repair and organ regeneration. Local manufacture of these biomaterials would also contribute to the development of the Australian biotechnology industry.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
Tissue Engineering of Human Heart Valve Grown In Vitro. Tissue engineering (TE) of heart valves is a new approach to cultivate a functional heart valve from human autologous cells. This innovative study aims to develop the technology to transplant cells onto a 3D biocompatible valve scaffold that is capable of mimicking native valve. The work proposed is a ground breaking study that will encompass development of a new biomaterial, manufacture of scaffolds using the Fused Deposition Modelling ra ....Tissue Engineering of Human Heart Valve Grown In Vitro. Tissue engineering (TE) of heart valves is a new approach to cultivate a functional heart valve from human autologous cells. This innovative study aims to develop the technology to transplant cells onto a 3D biocompatible valve scaffold that is capable of mimicking native valve. The work proposed is a ground breaking study that will encompass development of a new biomaterial, manufacture of scaffolds using the Fused Deposition Modelling rapid prototyping process, hemodynamic optimisation and in vitro cell culture. This will advance our knowledge in cellular and scaffold technologies and may ultimately lead to the development of a TE heart valve.Read moreRead less
Biomimetic Insights from Enamel: A Nano-mechanical and Nano-structural Investigation of a Natural Ceramic-like Biocomposite. Enamel is a naturally developed example of an optimised material structure that constitutes the hardest tissue in the human body. In addition it is exposed to severe mechanical and environmental challenges and must last the lifetime of the individual and unlike other tissue is unable to heal or repair itself. Understanding the factors controlling the amazing mechanical pr ....Biomimetic Insights from Enamel: A Nano-mechanical and Nano-structural Investigation of a Natural Ceramic-like Biocomposite. Enamel is a naturally developed example of an optimised material structure that constitutes the hardest tissue in the human body. In addition it is exposed to severe mechanical and environmental challenges and must last the lifetime of the individual and unlike other tissue is unable to heal or repair itself. Understanding the factors controlling the amazing mechanical properties of this tissue will be of great benefit for the design of bio-inspired materials and be important for the development of advanced materials for which Australia already has an enviable reputation.Read moreRead less
Fluid dynamics and mechanical stress of tissue heart valves. Major problems with thrombo-embolic complications and leaflet failure and calcification still exist with bioprosthetic valves. Valves fabricated from polyether urethanes are efficient and can offer more resistance to calcification. No complete study on the haemodynamics and structure interactions is found in literature. Moreover, todate the effect of aortic wall motion on the blood flow has never been examined. A complete holistic ap ....Fluid dynamics and mechanical stress of tissue heart valves. Major problems with thrombo-embolic complications and leaflet failure and calcification still exist with bioprosthetic valves. Valves fabricated from polyether urethanes are efficient and can offer more resistance to calcification. No complete study on the haemodynamics and structure interactions is found in literature. Moreover, todate the effect of aortic wall motion on the blood flow has never been examined. A complete holistic approach to simulataneuosly simulating the fluid dynamics, the valve motion and the stress in a synthetic Polyether urethane valve is proposed. Cell adhesion study will also be carried out. The findings may yield to new insights into valve research.Read moreRead less
Designs of Periodic Microstructure Materials with Prescribed Multiphysical Properties. The evolutionary structural optimization (ESO) is an Australian initiative, which has made a significant impact on modern structural optimization. In advanced materials areas, Australia has well-established infrastructure and world-class expertise. Exploitation of ESO to advanced materials design will be of "exclusive significance" to Australia. More importantly, the new material design technology will present ....Designs of Periodic Microstructure Materials with Prescribed Multiphysical Properties. The evolutionary structural optimization (ESO) is an Australian initiative, which has made a significant impact on modern structural optimization. In advanced materials areas, Australia has well-established infrastructure and world-class expertise. Exploitation of ESO to advanced materials design will be of "exclusive significance" to Australia. More importantly, the new material design technology will present to Australia an opportunity to lead in this rapidly-growing area, which will definitely underpin Australia's standing as a major contributor and developer in a global materials market. It is expected that fresh classes of futuristic materials can be developed in a cost-effective fashion and add great economic benefits to Australia.Read moreRead less
LIPID AND LIPOPROTEIN ADSORPTION AT BIOMATERIALS AND BIO-DIAGNOSTICS INTERFACES. This project aims to investigate molecular mechanisms involved in the formation of undesired biological deposits on synthetic materials and thereby help establish the scientific basis for the rational design of materials with improved compatibility with biological fluids and the engineering of a new generation of biomedical implant devices and bio-diagnostic devices. It is well known that proteins accumulate on synt ....LIPID AND LIPOPROTEIN ADSORPTION AT BIOMATERIALS AND BIO-DIAGNOSTICS INTERFACES. This project aims to investigate molecular mechanisms involved in the formation of undesired biological deposits on synthetic materials and thereby help establish the scientific basis for the rational design of materials with improved compatibility with biological fluids and the engineering of a new generation of biomedical implant devices and bio-diagnostic devices. It is well known that proteins accumulate on synthetic solid surfaces. This project proposes to investigate whether lipids and lipoproteins also play key roles in the initiation of biological adsorption processes. Combined with the study of the interfacial forces responsible, this information will guide the design of preventative strategies.Read moreRead less
Theoretical and experimental studies on magnetoelectroelastic bone remodelling process. The project combines biotechnology and material science which will have national economic, social and environment impact. It can benefit industry by providing knowledge that help scientists understand remodeling under coupled fields and is used to develop bone replacement. By better understanding remodeling due to multi-field loading, we can assist scientists in aeronautical industry in developing countermeas ....Theoretical and experimental studies on magnetoelectroelastic bone remodelling process. The project combines biotechnology and material science which will have national economic, social and environment impact. It can benefit industry by providing knowledge that help scientists understand remodeling under coupled fields and is used to develop bone replacement. By better understanding remodeling due to multi-field loading, we can assist scientists in aeronautical industry in developing countermeasures that reduce or eliminate bone loss resulting from long-duration space flight. It can provide knowledge that can be used to explore underlying mechanisms controlling bone remodeling and self-repair in gaining insight into debilitating diseases such as osteoporosis, to develop high-performance prosthetics for medical injury healing.Read moreRead less