An innovative manufacturing technology enabling new generations of hip joint prostheses. The success of the present project will revolutionise the way we produce hip joint prostheses, resolve the critical issues caused by the wear of the hip joint bearing surfaces, and dramatically improve patients' life quality. The project will open an entirely new application field for the Australian made materials which have a very limited market so far. With the innovative technology and the new generations ....An innovative manufacturing technology enabling new generations of hip joint prostheses. The success of the present project will revolutionise the way we produce hip joint prostheses, resolve the critical issues caused by the wear of the hip joint bearing surfaces, and dramatically improve patients' life quality. The project will open an entirely new application field for the Australian made materials which have a very limited market so far. With the innovative technology and the new generations of hip joint prostheses, the international competitive edge of the Australian industry will be markedly sharpened. Patients, and the Australian economy, are expected to benefit greatly from successful developments in this project.Read moreRead less
Using 3D printing technology to develop architecturally-controlled synthetic bone substitutes. With the ageing population, there is increasing demand for synthetic materials that can regenerate bone. However, purely synthetic bone-substitute biomaterials cannot regenerate large bone defects in weight-bearing conditions due to their fragility. This project aims to develop a customisable, biodegradable, biocompatible and mechanically strong and tough scaffold that overcomes this long-standing prob ....Using 3D printing technology to develop architecturally-controlled synthetic bone substitutes. With the ageing population, there is increasing demand for synthetic materials that can regenerate bone. However, purely synthetic bone-substitute biomaterials cannot regenerate large bone defects in weight-bearing conditions due to their fragility. This project aims to develop a customisable, biodegradable, biocompatible and mechanically strong and tough scaffold that overcomes this long-standing problem. The project aims to achieve this by applying an innovative combination of cutting-edge 3D printing technology, advanced computational modelling and design techniques to produce a next-generation bioceramic scaffold with optimised architecture. This approach aims also to enable the possibility of producing custom-made implants for individual requirements.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.
Computational Scaffold Optimisation for Tissue Engineering. Due to exceptional potential, tissue engineering has attracted over US$4.5 billion research and development investment and another US$2.6 billion market capital since 1990. It is important to cement Australia's position in such a highly competitive field. This project aims to develop a novel technology for scaffold-based tissue engineering, which would help Australia lead in the relevant area and increase its competitiveness in the futu ....Computational Scaffold Optimisation for Tissue Engineering. Due to exceptional potential, tissue engineering has attracted over US$4.5 billion research and development investment and another US$2.6 billion market capital since 1990. It is important to cement Australia's position in such a highly competitive field. This project aims to develop a novel technology for scaffold-based tissue engineering, which would help Australia lead in the relevant area and increase its competitiveness in the future global market of biomaterials, tissue products, biomedical software and instruments. An enormous socio-economic benefit to Australia would be a significant improvement in the clinical success rate for our ageing population. Read moreRead less
Synthesis of functionalised, biosorbable biopolymers with novel architecture for soft tissue engineering. This project will provide a timely and unique opportunity to develop biodegradable and biocompatible polymeric scaffold materials for use in soft tissue engineering. The project forms an essential part of the strategy set in the University of Melbourne to develop a system for cell transplantation and organ recreation. The success of the project will provide a significant contribution to the ....Synthesis of functionalised, biosorbable biopolymers with novel architecture for soft tissue engineering. This project will provide a timely and unique opportunity to develop biodegradable and biocompatible polymeric scaffold materials for use in soft tissue engineering. The project forms an essential part of the strategy set in the University of Melbourne to develop a system for cell transplantation and organ recreation. The success of the project will provide a significant contribution to the solution of organ shortage in organ transplantation both in Australia and the world. Through the technology developed in this project, a significant contribution in biomaterial science and manufacture in Australia will be achieved.Read moreRead less
Engineering a physiologically-relevant blood vessel in vitro . The project will develop an in vitro blood vessel model which will mimic arterial conditions by incorporating vascular cells and silk conduits as scaffolds, for the first time. This approach will overcome the limitations of simplistic 2D cell cultures, the long maturation times of fully tissue-engineered vessels, and resource intensive animal models. The innovative bioengineered construct proposed builds on the CI’s significant advan ....Engineering a physiologically-relevant blood vessel in vitro . The project will develop an in vitro blood vessel model which will mimic arterial conditions by incorporating vascular cells and silk conduits as scaffolds, for the first time. This approach will overcome the limitations of simplistic 2D cell cultures, the long maturation times of fully tissue-engineered vessels, and resource intensive animal models. The innovative bioengineered construct proposed builds on the CI’s significant advances in materials and surface engineering and the Partner Organisation’s (Codex Research) new bioreactor platform. It will offer a solution for modelling of native vessel processes in vitro that would be more appropriate for pre-clinical drug and device development, and in the long-term, tissue replacement.Read moreRead less
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.
Final frontier in computational modelling of movement. This project aims to create the computational models and methods needed to advance current understanding of musculoskeletal function during movement. Humans must maintain their capacity to move in order to maintain quality-of-life. Predictive modelling is potentially the most powerful approach for understanding musculoskeletal function during movement. Current computational methods are too slow and unreliable to deliver predictive simulation ....Final frontier in computational modelling of movement. This project aims to create the computational models and methods needed to advance current understanding of musculoskeletal function during movement. Humans must maintain their capacity to move in order to maintain quality-of-life. Predictive modelling is potentially the most powerful approach for understanding musculoskeletal function during movement. Current computational methods are too slow and unreliable to deliver predictive simulations of movement using realistic models of muscle and joint anatomy. This project expects to create the next generation of methods and algorithms needed to enable predictive modelling of movement. Predictive simulations will provide new insights into how muscles stabilise and control movements of the spine, pelvis and lower limbs during daily activities such as walking.Read moreRead less
Measuring large deformation tissue mechanical behaviour in living humans. This project aims to develop new in vivo imaging methods to characterise the nonlinear mechanical behaviour of soft biological tissues, and use them to measure the properties of muscle, liver and adipose tissue in human subjects. Comprehensively characterising the mechanical properties of an individual person’s body tissues in vivo is a long-standing challenge in biomechanics and biomedical engineering. These new methods a ....Measuring large deformation tissue mechanical behaviour in living humans. This project aims to develop new in vivo imaging methods to characterise the nonlinear mechanical behaviour of soft biological tissues, and use them to measure the properties of muscle, liver and adipose tissue in human subjects. Comprehensively characterising the mechanical properties of an individual person’s body tissues in vivo is a long-standing challenge in biomechanics and biomedical engineering. These new methods aim to overcome major imitations of current biomechanical imaging methods, and make new measurements of the nonlinear mechanical properties of muscle, liver and adipose tissues. These techniques may be useful for future diagnostic, biomechanics and mechanobiology applications.Read moreRead less
Fundamental theoretical and experimental investigation of cartilage mechanics. Arthritis and chronic joint symptoms are one of the leading causes of disability in the community, yet a fundamental understanding of joint mechanics has yet to be realised. The aim of this project is to develop a new state-of-the-art mathematical model describing cartilage behaviour in humans. The model will explain how activities like walking maintain healthy cartilage by transferring growth factors through the tiss ....Fundamental theoretical and experimental investigation of cartilage mechanics. Arthritis and chronic joint symptoms are one of the leading causes of disability in the community, yet a fundamental understanding of joint mechanics has yet to be realised. The aim of this project is to develop a new state-of-the-art mathematical model describing cartilage behaviour in humans. The model will explain how activities like walking maintain healthy cartilage by transferring growth factors through the tissue, and quantitatively explain how wear is minimised in cartilage through weeping lubrication. This model will progress our understanding of cartilage mechanics in health and disease, and so help Australians age well and productively.Read moreRead less