Image-guided skin microbiopsy technology development. There is a need for targeted biopsies in dermatology. This novel technology enables minimally invasive biopsies to be taken from suspicious skin lesions by integrating micromedical and imaging devices.
Patient-specific biomechanical modelling for improved treatment of spinal deformity. Spinal deformities negatively affect social acceptance, physical and mental wellbeing in children and adolescents. The direct costs of spinal deformity surgery are approximately $30 million per year in Australia, yet poor treatment outcomes due to post-operative complications incur a much higher cost as patients with persistent pain and disability face a lifetime of dependency and reduced ability to work. The pa ....Patient-specific biomechanical modelling for improved treatment of spinal deformity. Spinal deformities negatively affect social acceptance, physical and mental wellbeing in children and adolescents. The direct costs of spinal deformity surgery are approximately $30 million per year in Australia, yet poor treatment outcomes due to post-operative complications incur a much higher cost as patients with persistent pain and disability face a lifetime of dependency and reduced ability to work. The patient-specific biomechanical modelling techniques developed in this project will reduce complications and improve correction for Australian children who undergo spinal deformity surgery. Better treatment outcomes will ensure quality of life, health and productivity for spinal deformity patients throughout their entire lives.Read moreRead less
The virtual human knee. This project aims to investigate the Virtual Human Knee (VHK) which provides a baseline knowledge about knee mechanics in healthy individuals and a tool for studying knee mechanics in silico. The new knowledge can be used for identifying individuals most at risk for injury, developing solutions for preventing injury and for assessing knee reconstruction and implantation methods. As such, VHK will mitigate the burden of knee injury to Australia and worldwide by progressing ....The virtual human knee. This project aims to investigate the Virtual Human Knee (VHK) which provides a baseline knowledge about knee mechanics in healthy individuals and a tool for studying knee mechanics in silico. The new knowledge can be used for identifying individuals most at risk for injury, developing solutions for preventing injury and for assessing knee reconstruction and implantation methods. As such, VHK will mitigate the burden of knee injury to Australia and worldwide by progressing disciplines including anatomy, bio-mechanics, sport science, rehabilitation, surgery and medical devices.Read moreRead less
Biomechanics of the human spine measured using magnetic resonance imaging. Statistics show that 80% of the population suffer back pain at some time. However, because the spine is very complex our understanding of its mechanics and the causes of back pain are still limited. This project will investigate the anatomy and activity of the spinal muscles and the behaviour of the intervertebral disc in living subjects using innovative Magnetic Resonance Imaging techniques. Significant outcomes will be ....Biomechanics of the human spine measured using magnetic resonance imaging. Statistics show that 80% of the population suffer back pain at some time. However, because the spine is very complex our understanding of its mechanics and the causes of back pain are still limited. This project will investigate the anatomy and activity of the spinal muscles and the behaviour of the intervertebral disc in living subjects using innovative Magnetic Resonance Imaging techniques. Significant outcomes will be new definitive descriptions of the detailed anatomy of the spine and its mechanisms. This will enhance the accuracy and detail of models under development for predicting spinal function following disease, injury or surgical procedures.Read moreRead less
Bilayered and growth factor-loaded composite scaffolds for the guided bi-differentiation of bone marrow stem cells. The project will regenerate bone-cartilage (osteochondral) tissues using scaffolds, growth factors, and stem cells in order to repair osteochondral defects. The project will improve the quality of life for ~1.4 million Australians suffering from joint pain and disability due to damage or disease of cartilage and subchondral bone. The project will promote Australia research strength ....Bilayered and growth factor-loaded composite scaffolds for the guided bi-differentiation of bone marrow stem cells. The project will regenerate bone-cartilage (osteochondral) tissues using scaffolds, growth factors, and stem cells in order to repair osteochondral defects. The project will improve the quality of life for ~1.4 million Australians suffering from joint pain and disability due to damage or disease of cartilage and subchondral bone. The project will promote Australia research strength in biomaterials, tissue engineering, and drug delivery. The project will also create research opportunities for PhD students, who will be equipped with interdisciplinary skills.Read moreRead less
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
A kinetic measuring system for assistive devices used in paediatric gait. Each year, a proportion of children are born who suffer from disabilities, which limits their ability to walk efficiently. Gait analysis can identify limiting factors in walking ability, and can assess the clinical outcome of treatments. Children who use assistive devices, such as walking frames, are denied the full benefits of gait analysis due to limitations in current equipment. This project addresses this need through ....A kinetic measuring system for assistive devices used in paediatric gait. Each year, a proportion of children are born who suffer from disabilities, which limits their ability to walk efficiently. Gait analysis can identify limiting factors in walking ability, and can assess the clinical outcome of treatments. Children who use assistive devices, such as walking frames, are denied the full benefits of gait analysis due to limitations in current equipment. This project addresses this need through the development of a portable, load-measuring instrument. When integrated with existing equipment, a comprehensive description of assisted walking gait will be possible. This will lead to greater understanding and improved treatment outcomes for such children.Read moreRead less
Understanding the biomechanical effects of fixation strategies to improve the technology of fracture management. Severe limb trauma is the leading cause of disability to people of wage-earning age, and 150,000 Australians are hospitalised with fractures each year. Beyond the direct costs to the nation of $1000 million annually, temporary and permanent loss of limb functionality have a significant impact on productivity and quality of life. The computational models developed in this project will ....Understanding the biomechanical effects of fixation strategies to improve the technology of fracture management. Severe limb trauma is the leading cause of disability to people of wage-earning age, and 150,000 Australians are hospitalised with fractures each year. Beyond the direct costs to the nation of $1000 million annually, temporary and permanent loss of limb functionality have a significant impact on productivity and quality of life. The computational models developed in this project will address critical gaps in the knowledge of fracture healing and the influence of different fixation devices. The project outcomes will provide a basis for tailoring fixation technologies for more reliable outcomes and minimised risk of non-union and complications, and thereby reducing physical impairment and the socio-economic burden of fractures.Read moreRead less
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
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.