Effects of prosthesis design on bone remodelling and longevity of dental restorations. The project targets both the 'Promoting and Maintaining Good Health' and 'Advanced Materials' designated research priority areas. The research will underpin Australia's leading role on some emerging interdisciplinary frontiers of biomechanics, biomaterials, health sciences and biomedical software. The development of computer aided clinical plan will help optimise dental restorations for 'long-term success'. Th ....Effects of prosthesis design on bone remodelling and longevity of dental restorations. The project targets both the 'Promoting and Maintaining Good Health' and 'Advanced Materials' designated research priority areas. The research will underpin Australia's leading role on some emerging interdisciplinary frontiers of biomechanics, biomaterials, health sciences and biomedical software. The development of computer aided clinical plan will help optimise dental restorations for 'long-term success'. The benefit will be to improve the ongoing performance and longevity of dental restoration, which complies with the highly demanding national goal of 'ageing well'. The study will also provide a new means to improve the therapy effect for many young Australians' effort towards a 'healthy start to their life'.Read moreRead less
Topography Optimisation of Implants for Enhancing Osseointegration. With recent increased life expectancy, the ratio of implant recipients to total population has dramatically increased. The project will address a critical issue in ensuring long-term success of prosthetic treatment. The proposed computational multiscale modelling will provide a sound scientific alternative means to optimisation of overall implant design including surface topography. The anticipated outcomes of this research will ....Topography Optimisation of Implants for Enhancing Osseointegration. With recent increased life expectancy, the ratio of implant recipients to total population has dramatically increased. The project will address a critical issue in ensuring long-term success of prosthetic treatment. The proposed computational multiscale modelling will provide a sound scientific alternative means to optimisation of overall implant design including surface topography. The anticipated outcomes of this research will help improve the quality of prosthetic therapy, and benefit our prosthodontic and orthopaedic professionals and their patients. The study clearly aligns with the national research goals of frontier technologies and maintaining good health.Read moreRead less
Failure of Complex Biomechanical Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate dental crown structures. We are now at a critical point in the understanding of how these structures fail, and are beginning to make substantive predictions to improve des ....Failure of Complex Biomechanical Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate dental crown structures. We are now at a critical point in the understanding of how these structures fail, and are beginning to make substantive predictions to improve designs for prolonged life. The project is connected to the dental community and international crown material manufacturers through a broader NIH project in the USA. The improved materials and crown designs resulting from this project will have impact worldwide, including Australia.Read moreRead less
Failure of Worn Tooth Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate natural teeth and dental crown structures that have been subject to wear. The project is connected to the dental community and international crown material manufacturers through a bro ....Failure of Worn Tooth Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate natural teeth and dental crown structures that have been subject to wear. The project is connected to the dental community and international crown material manufacturers through a broader National Institutes of Health project in the USA. The improved understanding of damage mechanisms in natural teeth and crown designs resulting from this project will have impact worldwide, including Australia.Read moreRead less
Nano-mechanical and nano-structural investigation of dentine: unravelling a novel nano-scale regulator of high durability of mineralised tissues. This project proposes that proteoglycans (PG) are key regulators of the high durability of dentine. PGs are primarily responsible for the structural organization of collagen in all vertebrates, however virtually nothing is known about their role on the biomechanics of mineralized tissues. This study aims to thoroughly address this question.
Meso- and Macro-porous Bioactive Glasses for Bone-repairing. This project aims to use self-assembly and pore engineering at different length scales to fabricate novel bioactive glasses of highly ordered mesoporous structure. By precisely controlling the composition, size and volume of both mesopores and macropores, bioactive glasses with improved bone forming activities will be obtained. The successful synthesis of such bioactive glasses is expected to lead to the fundamental understanding of st ....Meso- and Macro-porous Bioactive Glasses for Bone-repairing. This project aims to use self-assembly and pore engineering at different length scales to fabricate novel bioactive glasses of highly ordered mesoporous structure. By precisely controlling the composition, size and volume of both mesopores and macropores, bioactive glasses with improved bone forming activities will be obtained. The successful synthesis of such bioactive glasses is expected to lead to the fundamental understanding of structure-bioactivity relationship, and new materials effective for tissue engineering. This will also open up new opportunities for other applications such as drug delivery, implanting.Read moreRead less
Design Optimisation for Fabrication of Ceramic Prosthetic Devices. The project aims to develop computer aided design and fabrication for ceramic prosthesis. It will help establish a world-class biomedical instrumentation company having part of its research and development in Australia. The study will not only foster domestic research expertise, but also provide the local prosthetic community and biomedical industry with an opportunity to participate in further innovation of biomaterials, biomedi ....Design Optimisation for Fabrication of Ceramic Prosthetic Devices. The project aims to develop computer aided design and fabrication for ceramic prosthesis. It will help establish a world-class biomedical instrumentation company having part of its research and development in Australia. The study will not only foster domestic research expertise, but also provide the local prosthetic community and biomedical industry with an opportunity to participate in further innovation of biomaterials, biomedical software and equipment. The outcomes will directly benefit the Australian prosthetic profession. Improvement in prosthesis restorative longevity for our increasing ageing population will support the national research goal of ageing well, ageing productively.Read moreRead less
Microstructural-Functional Effect of Silver Diammine Fluoride on Apatites. This project aims to develop a fundamental understanding at the nanostructural level of the factors that contribute to the enhanced mineralisation and mechanical properties of dentine and enamel following the treatment with silver diammine fluoride (SDF). A variety of advanced nanomechanical, tomographic and microscopic techniques will be used to characterise sound, carious and SDF treated tissue. The new biomechanical ev ....Microstructural-Functional Effect of Silver Diammine Fluoride on Apatites. This project aims to develop a fundamental understanding at the nanostructural level of the factors that contribute to the enhanced mineralisation and mechanical properties of dentine and enamel following the treatment with silver diammine fluoride (SDF). A variety of advanced nanomechanical, tomographic and microscopic techniques will be used to characterise sound, carious and SDF treated tissue. The new biomechanical evidence on the underlying mechanisms, alternative protocols, delivery systems enable to optimise the treatment. The scientific insights into arresting/repairing damage processes will provide critical data for developing minimal intervention protocols for pediatric and geriatric populations.Read moreRead less
Advanced micro-architecture and nanotopography for enhanced tissue growth in scaffolds. Tissue engineering scaffolds offer an urgently needed synthetic biomaterials solution to overcome disease transmission from donor transplants. This work will combine biomaterial chemistry and designed surface topography to trigger bone formation within a scaffold for the first time in the world. Collaboration with national research leaders on stem cell and animal testing of the new scaffolds will provide the ....Advanced micro-architecture and nanotopography for enhanced tissue growth in scaffolds. Tissue engineering scaffolds offer an urgently needed synthetic biomaterials solution to overcome disease transmission from donor transplants. This work will combine biomaterial chemistry and designed surface topography to trigger bone formation within a scaffold for the first time in the world. Collaboration with national research leaders on stem cell and animal testing of the new scaffolds will provide the necessary interdisciplinary approach to generate a new product for patients in need of bone regeneration. Australia will benefit from the contribution to medical science, the development of a new device for rapid prototyping tissue engineering scaffolds, retain biomaterials research expertise, and generate new biomedical products.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