Three-dimensional Simulation of Trabecular Bone Remodelling. Nearly 2 million Australians currently suffer from osteoporosis. Statistics indicate that 25% of Australian women and 17% of men will develop an osteoporotic fracture. The cost of osteoporosis is $7.4 billion per annum; the numbers of affected individuals and costs are expected to continue increasing. Clearly, improvements to osteoporosis diagnosis, fracture risk assessment, and effective treatments are still urgently needed. The p ....Three-dimensional Simulation of Trabecular Bone Remodelling. Nearly 2 million Australians currently suffer from osteoporosis. Statistics indicate that 25% of Australian women and 17% of men will develop an osteoporotic fracture. The cost of osteoporosis is $7.4 billion per annum; the numbers of affected individuals and costs are expected to continue increasing. Clearly, improvements to osteoporosis diagnosis, fracture risk assessment, and effective treatments are still urgently needed. The proposed project aims to create a tool for understanding the mechanisms of bone loss and predicting the effects of osteoporosis therapies. It represents a solid contribution to the knowledge base necessary for advancing osteoporosis research and ultimately reducing the incidence of osteoporotic fracture.Read moreRead less
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