Interplay between mechanical and biological microenvironments in chondrocyte function: towards an understanding of cartilage pathology. This project will develop state-of-the-art laboratory models of healthy and diseased joints. These models will assist in answering questions about the causes of osteoarthritis, and provide information on how best to treat diseased joints.
X-Ray Activation of Photocatalytic Titania-Coated Biomedical Implants in Situ. The main causes of biomedical implant failure are loosening and infection, which may require revision surgery. The project has the potential to solve these widespread and expensive problems by formation of a coating of strongly (chemically) bonded and photocatalytically active titania on the titanium implant surface and short-term low-dose X-irradiation. This work has the potential to provide the biomedical industry w ....X-Ray Activation of Photocatalytic Titania-Coated Biomedical Implants in Situ. The main causes of biomedical implant failure are loosening and infection, which may require revision surgery. The project has the potential to solve these widespread and expensive problems by formation of a coating of strongly (chemically) bonded and photocatalytically active titania on the titanium implant surface and short-term low-dose X-irradiation. This work has the potential to provide the biomedical industry with a revolutionary development in both implant coating design and quality with self-disinfection capacity after implantation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100057
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
A high-resolution X-ray microtomography system. This project aims to establish a Scanco microCT 50 high resolution X-Ray microtomography system, to non-destructively visualise and quantitatively characterise complex samples, including advanced composites, tissue engineering constructs, biological tissues, minerals and fossils. The non-destructive characterisation of these samples is critical to advance research. The versatile system offers high spatial resolution (down to 500 nm voxel size) and ....A high-resolution X-ray microtomography system. This project aims to establish a Scanco microCT 50 high resolution X-Ray microtomography system, to non-destructively visualise and quantitatively characterise complex samples, including advanced composites, tissue engineering constructs, biological tissues, minerals and fossils. The non-destructive characterisation of these samples is critical to advance research. The versatile system offers high spatial resolution (down to 500 nm voxel size) and large sample size (up to 100 mm diameter). The project will enable progress in advanced composites, additive bio-manufacturing, physiology of biological tissues and palaeontology which will benefit Australian science. Additionally, through commercialisation and the formation of new companies, the project could potentially result in economic and health benefits to the wider Australian population and economy.Read moreRead less
Frontiers in bone and joint regeneration. Key outcomes of this project will deliver innovative strategies for scaffold-based bone and cartilage engineering whilst contributing to the education of a new generation of bioengineers, biomaterial scientists and tissue engineers with a strong international profile.
Switching the light on cartilage repair. Osteoarthritis is a leading cause of pain and disability in adults and affects 15 per cent of the Australian population. This project will develop a revolutionary new approach to treat joint disorders using smart materials and stem cells. The novel materials and techniques developed will help Australia maintain its leading edge in biotechnology.
Structural design of third generation biomaterials. This project will design third generation biomaterials for heart valves, cartilage and bones that guide the formation of new tissue whilst being dissolved inside the human body. As a result, it is anticipated that painful and costly revision surgery will become obsolete. Major benefits will be achieved in paediatric health as implants will have the ability to grow with the child.
Industrial Transformation Training Centres - Grant ID: IC170100022
Funder
Australian Research Council
Funding Amount
$4,420,408.00
Summary
ARC Training Centre for Innovative BioEngineering. The ARC Training Centre for Musculoskeletal Biomedical Technologies will provide the next-generation of skilled graduates to overcome industry-focused challenges in musculoskeletal regeneration. The Centre expects to engineer a set of integrated technologies to personalise implants for the unique biological, physical and lifestyle characteristics of the recipient. Expected outcomes of the Centre include embedded bioelectronic sensors to assess a ....ARC Training Centre for Innovative BioEngineering. The ARC Training Centre for Musculoskeletal Biomedical Technologies will provide the next-generation of skilled graduates to overcome industry-focused challenges in musculoskeletal regeneration. The Centre expects to engineer a set of integrated technologies to personalise implants for the unique biological, physical and lifestyle characteristics of the recipient. Expected outcomes of the Centre include embedded bioelectronic sensors to assess and optimise the healing process. In addition, the Centre will produce data for use in deriving the next-generation of implants, giving rise to improved health outcomes, economic benefits, and a skilled workforce able to advance and perpetuate this important field.Read moreRead less
A novel electrospraying technology platform for controlled and targeted growth factor delivery. This project will develop a new growth factor delivery strategy to stimulate bone regeneration. The project will utilise the technique of electrospraying to create small dissolving polymer microspheres containing bone-relevant growth factors, which are released gradually as the polymer degrades after implantation into a bone defect site to promote healing.
Multifunctional surfaces for implantable biomedical devices. This project aims to improve the quality of life of patients receiving biomedical implants. The project will develop new plasma processing methods to create surfaces for implants that will give control over the response of human tissues. Tissue integration with the device will be achieved where required and infection suppressed.
Discovery Early Career Researcher Award - Grant ID: DE140101530
Funder
Australian Research Council
Funding Amount
$372,744.00
Summary
Synchrotron-based modelling of the deformation and fracture mechanism in normal and osteoporotic femurs under multiaxial loading cycles. The femur is a light-weight structure designed to best perform in life. However, the complex tissue architecture, microstructural organisation and its complex loading regimens make it difficult to understand how the femur can deform and fracture. This project studies femoral fractures by modelling the proximal femur with a micrometric level of detail. Synchrotr ....Synchrotron-based modelling of the deformation and fracture mechanism in normal and osteoporotic femurs under multiaxial loading cycles. The femur is a light-weight structure designed to best perform in life. However, the complex tissue architecture, microstructural organisation and its complex loading regimens make it difficult to understand how the femur can deform and fracture. This project studies femoral fractures by modelling the proximal femur with a micrometric level of detail. Synchrotron femur images are taken in loaded and unloaded conditions. Cortical strain and fracture are measured, replicating possible multiaxial loads. Micro finite-element models will be used to study the contribution that the bone tissue architecture, tissue structure and activity types make to the fracture. The resulting knowledge will have future orthopaedic applications.Read moreRead less