Industrial Transformation Training Centres - Grant ID: IC180100024
Funder
Australian Research Council
Funding Amount
$4,000,000.00
Summary
ARC Training Centre for Medical Implant Technologies. The ARC Training Centre for Medical Implant Technologies aims to train a new generation of interdisciplinary engineers and to transform the orthopaedic and maxillofacial implant industry in Australia. In collaboration with industry, universities and hospitals, the Centre will build a dynamic training environment for interdisciplinary engineers to develop and evaluate personalised implants and surgeries. It will create new networks, internatio ....ARC Training Centre for Medical Implant Technologies. The ARC Training Centre for Medical Implant Technologies aims to train a new generation of interdisciplinary engineers and to transform the orthopaedic and maxillofacial implant industry in Australia. In collaboration with industry, universities and hospitals, the Centre will build a dynamic training environment for interdisciplinary engineers to develop and evaluate personalised implants and surgeries. It will create new networks, international collaborations and a generation of industry-ready researchers critical for growing Australia’s industry. The advances in materials and savings in time for procedures will reduce costs.
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Functional Strontium Phosphate Coated Magnesium Alloys For ?Orthopaedic Use. This project aims to develop a functional strontium-release surface on magnesium-based orthopaedic implants to suppress the rapid degradation rate of magnesium, facilitate new bone formation and ultimately shorten the healing process. The development of practical, bone-favourable and degradation-inhibiting surfaces for magnesium implants are in demand and can bring significant patient benefits. The project seeks to esta ....Functional Strontium Phosphate Coated Magnesium Alloys For ?Orthopaedic Use. This project aims to develop a functional strontium-release surface on magnesium-based orthopaedic implants to suppress the rapid degradation rate of magnesium, facilitate new bone formation and ultimately shorten the healing process. The development of practical, bone-favourable and degradation-inhibiting surfaces for magnesium implants are in demand and can bring significant patient benefits. The project seeks to establish an understanding of the formation mechanisms of strontium-releasing coatings and determine the critical release rate of strontium to activate bone cell responses.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
Bioelectronics: addressing the biointerface challenge. This project aims to develop bioelectronic materials with long operational stability in physiological conditions and enhanced electronic performance that will effectively interface with electroresponsive tissue. These new materials will be integrated into bioadhesives from which simple bioelectronics devices will be fabricated and assessed for their capability to modulate biosignals and to interact with tissue. Disruption in biosignals cause ....Bioelectronics: addressing the biointerface challenge. This project aims to develop bioelectronic materials with long operational stability in physiological conditions and enhanced electronic performance that will effectively interface with electroresponsive tissue. These new materials will be integrated into bioadhesives from which simple bioelectronics devices will be fabricated and assessed for their capability to modulate biosignals and to interact with tissue. Disruption in biosignals causes numerous medical conditions such as epilepsy and heart failure and the development of flexible and biocompatible medical electronics devices that interface with tissue is essential for regaining and modulating these signals.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100302
Funder
Australian Research Council
Funding Amount
$461,300.00
Summary
A long-lasting interface for communicating with the brain. This project aims to address the most urgent challenges in developing the next generation of implantable devices for communicating with the brain. Using a new type of carbon-based electrode, along with light therapy, this project expects to build innovative technologies that can greatly enhance the functionality and longevity of these devices. Expected outcomes include a novel tool that can be implemented to obtain detailed insights into ....A long-lasting interface for communicating with the brain. This project aims to address the most urgent challenges in developing the next generation of implantable devices for communicating with the brain. Using a new type of carbon-based electrode, along with light therapy, this project expects to build innovative technologies that can greatly enhance the functionality and longevity of these devices. Expected outcomes include a novel tool that can be implemented to obtain detailed insights into neural circuits, advancing our understanding of neural function and pioneering feedback and closed-loop neuroscience. This project should provide significant benefits in neuroscience research and the neural interface industry, both of which have the ultimate goal to unlock the mysteries of the brain.Read moreRead less
High-fidelity, long lasting, single-neuron brain machine interfaces. The ability to conduct stable, high resolution recording and stimulation within the brain is critically important to the development of technologies that interface electronics with the human body. Devices that interface directly with the brain are increasingly important in brain research, medical monitoring, treatment of neurological diseases or the enormous increase in brain-machine interface technologies. Carbon Cybernetics h ....High-fidelity, long lasting, single-neuron brain machine interfaces. The ability to conduct stable, high resolution recording and stimulation within the brain is critically important to the development of technologies that interface electronics with the human body. Devices that interface directly with the brain are increasingly important in brain research, medical monitoring, treatment of neurological diseases or the enormous increase in brain-machine interface technologies. Carbon Cybernetics have developed a high-density neural recording and stimulation array that employs fine carbon fibres as the electrode material. We aim to show that this array can record from the brain indefinitely, without loosing signal quality, and the same array can be used to stimulate the brain to recreate memories or sensations.Read moreRead less
Bridging the gap between global mechanics and regional imaging in the lungs. The detailed mechanics of breathing are not well understood, due to a lack of regional lung measurement techniques. This project aims to develop a powerful analysis tool to image in vivo mechanical properties of the lungs. The expected outcome of this project is a novel platform for investigation and understanding of lung function, enabling information previously only available for the whole lung to be calculated for lo ....Bridging the gap between global mechanics and regional imaging in the lungs. The detailed mechanics of breathing are not well understood, due to a lack of regional lung measurement techniques. This project aims to develop a powerful analysis tool to image in vivo mechanical properties of the lungs. The expected outcome of this project is a novel platform for investigation and understanding of lung function, enabling information previously only available for the whole lung to be calculated for local lung regions within the body. The image analysis methods developed are intended to enable respiratory researchers to investigate lung function in unprecedented detail, leading to new insights into the workings of this complicated and vital organ. Read moreRead less
Ultra-low fouling active surfaces. This project aims to develop chemistries and fabrication approaches through innovative materials evaluation to develop ultra-low fouling active electrode surfaces. Development of ultra-low fouling surfaces will have significant impact in a range of applications where system or device failure is attributed to fouling. The growing field of bionics, where implantable electronic devices interface directly with the nervous system, is one such device. The expected ou ....Ultra-low fouling active surfaces. This project aims to develop chemistries and fabrication approaches through innovative materials evaluation to develop ultra-low fouling active electrode surfaces. Development of ultra-low fouling surfaces will have significant impact in a range of applications where system or device failure is attributed to fouling. The growing field of bionics, where implantable electronic devices interface directly with the nervous system, is one such device. The expected outcomes will be an understanding of the material requirements that lead to the elimination of protein and cell accumulation at surfaces that degrades the performance and lifetime of these implants. The findings will benefit any application where fouling is a problem.Read moreRead less
Multiplexed surface signals to inhibit mixed bacterial biofilm formation. This project aims to investigate a novel class of multifunctional surfaces that can be used to coat biomaterials with antimicrobial properties. This combines advanced polymer synthesis with a new colloidal particle self-assembly technique to modify surfaces. Expected project outcomes are generation of new knowledge of the molecular mechanisms of biofilm formation in complex microbial communities, which may facilitate futur ....Multiplexed surface signals to inhibit mixed bacterial biofilm formation. This project aims to investigate a novel class of multifunctional surfaces that can be used to coat biomaterials with antimicrobial properties. This combines advanced polymer synthesis with a new colloidal particle self-assembly technique to modify surfaces. Expected project outcomes are generation of new knowledge of the molecular mechanisms of biofilm formation in complex microbial communities, which may facilitate future research exploring the development of biomaterials that resist attachment of infectious microbes, which is desperately needed in many biomedical application areas. This can assist entrepreneurs and researchers in the medical technologies sector, allowing them to explore how to reduce infection rates on medical devices.Read moreRead less
Oscillations as a mechanism for neural communication. The project aims to answer how billions of cells in the brain can work together to allow us to perceive the world. By using novel electrophysiological and engineering techniques, the project tests if a brain signal called the local field potential provides a way for different areas in the brain to communicate. The hypothesis is that the local field potential is used by cells to synchronise their activity to be most effective. This project wou ....Oscillations as a mechanism for neural communication. The project aims to answer how billions of cells in the brain can work together to allow us to perceive the world. By using novel electrophysiological and engineering techniques, the project tests if a brain signal called the local field potential provides a way for different areas in the brain to communicate. The hypothesis is that the local field potential is used by cells to synchronise their activity to be most effective. This project would be a paradigm shift in how we currently understand how the brain works. Expected outcomes include answering long held questions about how we see and perceive the world. This should provide significant benefit to fields such as computer vision and the development of neural engineering devices.Read moreRead less