In-vivo functional imaging of cone photoreceptors and ganglion cell axons. Can we project a movie on a human retina, and measure the response of photoreceptor cells and connected nerve tissue? This project aims to investigate a new method for visualization of the quickest responses in human cone photoreceptors and nerve cells after a visible stimulus. Expected outcomes of this project include a better understanding of the origins of responses to a stimulus and how cells in the retina communicate ....In-vivo functional imaging of cone photoreceptors and ganglion cell axons. Can we project a movie on a human retina, and measure the response of photoreceptor cells and connected nerve tissue? This project aims to investigate a new method for visualization of the quickest responses in human cone photoreceptors and nerve cells after a visible stimulus. Expected outcomes of this project include a better understanding of the origins of responses to a stimulus and how cells in the retina communicate. The scientific results will be helpful in a better understanding of the development of vision in the infant eye, to study peripheral vision in elite athletes and to quantify performance of virtual reality equipment for the military. The IP on the technology can be licensed or used for start-up company.Read moreRead less
Force-mediated dynamic chemistry in hydrogels. This project aims to develop a new class of biomimetic material, where applied force modulates the chemistry and mechanics by incorporating mechanochemical responsive linkages in hydrogel networks. This work intends to generate new knowledge in the chemistry and mechanical properties of soft materials using an interdisciplinary approach involving synthesis, computational modelling, and mechanical analysis. Expected outcomes include novel hydrogel ma ....Force-mediated dynamic chemistry in hydrogels. This project aims to develop a new class of biomimetic material, where applied force modulates the chemistry and mechanics by incorporating mechanochemical responsive linkages in hydrogel networks. This work intends to generate new knowledge in the chemistry and mechanical properties of soft materials using an interdisciplinary approach involving synthesis, computational modelling, and mechanical analysis. Expected outcomes include novel hydrogel materials that are mechanochemically active, tough, and fatigue resistant, along with design criteria for force-activated molecule immobilisation and release expected to provide significant benefit forbiomedical applications, additive manufacturing, soft robotics and flexible electronics.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
Integrin Activation by Fluid Flow Disturbance: Mechanobiology Approaches. Understanding how cells can sense and respond to mechanical environment such as dynamic blood flow represents a fundamental question in the emerging field of mechanobiology. This project develops new biomechanical engineering approaches to determine the critical interrelationships among fluid flow disturbance, platelet clotting and the mechano-sensitive signal transduction mechanisms of integrin receptor – the most importa ....Integrin Activation by Fluid Flow Disturbance: Mechanobiology Approaches. Understanding how cells can sense and respond to mechanical environment such as dynamic blood flow represents a fundamental question in the emerging field of mechanobiology. This project develops new biomechanical engineering approaches to determine the critical interrelationships among fluid flow disturbance, platelet clotting and the mechano-sensitive signal transduction mechanisms of integrin receptor – the most important mechano-sensor implicated in cell adhesion, migration, growth and survival. Specifically, it integrates nationally unique cutting-edge techniques including single-molecule force probe, microparticle image velocimetry, microfluidics and molecular dynamics simulation, super resolution and 3D volumetric imaging modalities.Read moreRead less
Non-invasive and safe human-machine interface (HMI) systems . This project aims to establish novel non-invasive human-machine interface systems based on multi-modal sensing and machine learning to intuitively command and control robotic and autonomous systems safely interacting and cooperating with humans. This will be achieved by harnessing the synergies across design optimisation, multi-modal sensing, additive manufacturing, machine learning, and assistive and cooperative robotic devices. Expe ....Non-invasive and safe human-machine interface (HMI) systems . This project aims to establish novel non-invasive human-machine interface systems based on multi-modal sensing and machine learning to intuitively command and control robotic and autonomous systems safely interacting and cooperating with humans. This will be achieved by harnessing the synergies across design optimisation, multi-modal sensing, additive manufacturing, machine learning, and assistive and cooperative robotic devices. Expected outcomes are a novel human-machine interface methodology, a new multi-purpose wearable data glove, and function and application-specific machine learning methods for cutting-edge applications in assistive robotic devices such as a prosthetic hand, advanced manufacturing, construction and agriculture.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
Carbon Cybernetics: Next generation tools for neuroscience. The scope for technology that communicates directly with the human nervous system, is enormous. For fundamental study, the age of bionics is upon us. Biology has ways of recognising when a foreign body is present, thus implanted devices need to be camouflaged from the body's immune system. Today's bionic devices fail because they are rapidly rejected. We will use the element of biology, carbon, to construct a new class of technology for ....Carbon Cybernetics: Next generation tools for neuroscience. The scope for technology that communicates directly with the human nervous system, is enormous. For fundamental study, the age of bionics is upon us. Biology has ways of recognising when a foreign body is present, thus implanted devices need to be camouflaged from the body's immune system. Today's bionic devices fail because they are rapidly rejected. We will use the element of biology, carbon, to construct a new class of technology for future implants. Using a combination of permanent diamond and flexible carbon fibres we will create materials that are invisible to the immune system and last for decades. Seamlessly connecting our thoughts and actions with the power of human electronics. 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
Redefining tissue-specific endothelial cells through bioengineered matrices. This project aims to improve our understanding of the biological mechanisms that drive blood vessel formation and function. The endothelial cells that make up each blood vessel are inherently unique across different sites within the human body and this project expects to generate new knowledge regarding their organ specificity. Using advanced bioengineering approaches, this project will map human endothelial cell specif ....Redefining tissue-specific endothelial cells through bioengineered matrices. This project aims to improve our understanding of the biological mechanisms that drive blood vessel formation and function. The endothelial cells that make up each blood vessel are inherently unique across different sites within the human body and this project expects to generate new knowledge regarding their organ specificity. Using advanced bioengineering approaches, this project will map human endothelial cell specificity and develop state-of-the-art modelling technologies to improve knowledge of environmental influence on endothelial cell fate and function. This should provide a new framework to modulate the adaptive capacities of endothelial cells and can potentially enable more predictive and targeted drug efficacy and safety testing.Read moreRead less