Microfluidic technology to help understand physical damage to brain cells. Understanding the organisation, structure and mechanisms of the human brain and nervous system remains one of the biggest challenges of science. This project aims to develop a new cell culture platform to form defined molecular networks of brain cells and to monitor changes throughout the network in response to a small localised injury within the network. This innovative platform will be used to help understand changes wi ....Microfluidic technology to help understand physical damage to brain cells. Understanding the organisation, structure and mechanisms of the human brain and nervous system remains one of the biggest challenges of science. This project aims to develop a new cell culture platform to form defined molecular networks of brain cells and to monitor changes throughout the network in response to a small localised injury within the network. This innovative platform will be used to help understand changes within cells in response to physical damage to networks of brain cells. This is one of the major causes of death and disability in developed nations, and is identified as a risk factor for a range of neurodegenerative diseases including Alzheimer's, Parkinson's and motor neuron disease.Read moreRead less
Platform technology to decode motor control through ultra high-field MRI. This project aims to advance our understanding of the poorly understood neural circuits that enable fine motor control in humans. To obtain this knowledge, new platform technology will be developed to capture the full kinematics of the hand during concurrent functional magnetic resonance imaging at ultra high-field. This device will allow testing of fundamental theories describing the canonical microcircuits involved in ha ....Platform technology to decode motor control through ultra high-field MRI. This project aims to advance our understanding of the poorly understood neural circuits that enable fine motor control in humans. To obtain this knowledge, new platform technology will be developed to capture the full kinematics of the hand during concurrent functional magnetic resonance imaging at ultra high-field. This device will allow testing of fundamental theories describing the canonical microcircuits involved in hand motion. Expected outcomes include new evidence of mirror neurons and observation of predictive error signals in the motor cortex. This new knowledge paves the way towards improved computer-brain interface technology which is likely to create benefits through translation to applications such as artificial limb control.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
Tissue Engineering the Meniscus: Combining Novel Biomimetic Hybrid Scaffolds with Adult Stem Cells. Development of a meniscal implant ex vivo will provide significant health and economic benefits, given that worldwide, millions of people annually suffer from meniscus damage or loss. We believe that a tissue engineered meniscus, composed of a novel biomimetic scaffold which guides the differentiation of mesenchymal stem cells in a novel bioreactor will provide a solution to the problem of donor ....Tissue Engineering the Meniscus: Combining Novel Biomimetic Hybrid Scaffolds with Adult Stem Cells. Development of a meniscal implant ex vivo will provide significant health and economic benefits, given that worldwide, millions of people annually suffer from meniscus damage or loss. We believe that a tissue engineered meniscus, composed of a novel biomimetic scaffold which guides the differentiation of mesenchymal stem cells in a novel bioreactor will provide a solution to the problem of donor scarcity in meniscal repair. Success in this project will lead directly to large-animal studies and clinical trials. The training of four early careeer researchers involved in this project will also be of significant benefit to the Australian Tissue Engineering and Biomaterials community.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100001
Funder
Australian Research Council
Funding Amount
$875,000.00
Summary
A 3-photon imaging system for deep live imaging. This project aims to establish Australia’s first 3-photon microscope system with adaptive optics for deep intravital imaging. This advanced imaging system will enable researchers to investigate the biology of cells and tissue structures in a wide range of organs and engineered tissues, to a degree not possible with existing technology. This project will capitalise on advanced laser, microscope and adaptive optics technologies with the expected out ....A 3-photon imaging system for deep live imaging. This project aims to establish Australia’s first 3-photon microscope system with adaptive optics for deep intravital imaging. This advanced imaging system will enable researchers to investigate the biology of cells and tissue structures in a wide range of organs and engineered tissues, to a degree not possible with existing technology. This project will capitalise on advanced laser, microscope and adaptive optics technologies with the expected outcomes to include the generation of new knowledge of major biological systems, including the immune system and the nervous system. This will provide significant benefits to fundamental interdisciplinary research into immunology, infectious disease, neuroscience, mechanobiology and engineering.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101302
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Lab-on-a-chip platforms for hemodynamics research: new approaches for the study of blood diseases. This project will use advanced microfluidic technologies to study how and why blood clotting occurs. New devices will be created that can precisely analyse the ability of blood to form clots and these will become powerful tools for the diagnosis of blood disorders and the research and validation of drugs for the treatment of these disorders.
Tissue-like, nonlinearly elastic nanobiomaterials for soft tissue regeneration. The purpose of this project is to advance the discipline of soft tissue engineering and regeneration with novel biomaterials, nanotechnology and novel clinical treatment concepts. The key outcomes include new elastic tissue-like nanobiomaterials, new varieties of medical implants and innovative treatment methodology.
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
Drug particle characterisation. The understanding of drug particle characterizations is one of the key issues in the development of novel nasal sprayers for targeted drug delivery. A comprehensive study is proposed for characterising drug formation in sprayers and particle deposition in nasal cavity using the latest experimental and numerical techniques. A computer-aided design technology will be developed to optimise drug delivery systems. The new technology has great potentials leading to the ....Drug particle characterisation. The understanding of drug particle characterizations is one of the key issues in the development of novel nasal sprayers for targeted drug delivery. A comprehensive study is proposed for characterising drug formation in sprayers and particle deposition in nasal cavity using the latest experimental and numerical techniques. A computer-aided design technology will be developed to optimise drug delivery systems. The new technology has great potentials leading to therapeutic and economic benefits in developing advanced/innovative drug delivery systems and in evaluating the potential biological effects by the drugs to be introduced through the nose.Read moreRead less