Understanding how the brain uses sensory information to guide reaching and grasping movements. Reaching, grasping and manipulating objects are crucial aspects of our daily lives, which are performed so effortlessly that they tend to be taken for granted. We know however that these functions take a relatively long time to mature (think of a baby learning how to get an object), and that they can be impaired by brain lesions involving a region called the posterior parietal cortex. We also know that ....Understanding how the brain uses sensory information to guide reaching and grasping movements. Reaching, grasping and manipulating objects are crucial aspects of our daily lives, which are performed so effortlessly that they tend to be taken for granted. We know however that these functions take a relatively long time to mature (think of a baby learning how to get an object), and that they can be impaired by brain lesions involving a region called the posterior parietal cortex. We also know that this region has multiple subdivisions, but how exactly these interact in allowing the sensory information to guide arm and hand muscles is unknown. Discovering how this happens in terms of cellular interaction can have profound implications for the creation of new technologies such as artificial limbs and autonomous robots, and result in health benefits.Read moreRead less
Novel Neural Interfaces and Instrumentation for Stimulation and Monitoring of Retinal Activation in an Epiretinal Vision Prosthesis. Australia's reputation in medical neuroprostheses is second to none with the most notable example being the 'bionic ear' for the deaf. This research compliments that reputation by advancing science and engineering knowledge towards achieving a truly beneficial prosthesis for the blind, a 'bionic eye'. This research will also advance our capacity to address other a ....Novel Neural Interfaces and Instrumentation for Stimulation and Monitoring of Retinal Activation in an Epiretinal Vision Prosthesis. Australia's reputation in medical neuroprostheses is second to none with the most notable example being the 'bionic ear' for the deaf. This research compliments that reputation by advancing science and engineering knowledge towards achieving a truly beneficial prosthesis for the blind, a 'bionic eye'. This research will also advance our capacity to address other areas of therapeutic medical implants including those for limb movement to the paralysed. Benefits to the community include the very real possibility of restoring some visual capacity to the blind thus improving their quality of life through improved mobility, social interaction, and mental health. Read moreRead less
Comparison of Techniques for the Removal of Ocular Artefact from the Electroencephalogram: A Validation Study. Although employed extensively for both research and clinical purposes, the utility of the electroencephalograph (EEG) is hampered by the contaminating effects of eye movements on these 'brain waves'. If it can be validated, the recent Australian development of a solution to this problem will mean that the EEG can be measured more quickly and accurately. This purpose of this research is ....Comparison of Techniques for the Removal of Ocular Artefact from the Electroencephalogram: A Validation Study. Although employed extensively for both research and clinical purposes, the utility of the electroencephalograph (EEG) is hampered by the contaminating effects of eye movements on these 'brain waves'. If it can be validated, the recent Australian development of a solution to this problem will mean that the EEG can be measured more quickly and accurately. This purpose of this research is to perform this validation, and its success would mean both more efficient EEG recording for the country, as well as an enhanced scientific reputation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775747
Funder
Australian Research Council
Funding Amount
$160,000.00
Summary
Distributed Medical Image Analysis and Visualisation Engine (MedVis). Improved understanding of neurological processes is crucial to improving clinical outcomes for patients. MedVis will contribute in three ways: support development of new methods of interpretation and analysis of complex neurological studies, allowing current methods to be applied more efficiently, and enabling distributed simulations and visualisations in real-time from remote sites.
The leading-edge, grid-based, software and ....Distributed Medical Image Analysis and Visualisation Engine (MedVis). Improved understanding of neurological processes is crucial to improving clinical outcomes for patients. MedVis will contribute in three ways: support development of new methods of interpretation and analysis of complex neurological studies, allowing current methods to be applied more efficiently, and enabling distributed simulations and visualisations in real-time from remote sites.
The leading-edge, grid-based, software and computational techniques developed for the project will enable visualization, analysis and modelling of massive volumes of image and other visualisation data. This capability is important in medical research where large visualisation data volumes are being created and studied by experts remote from each other.
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Robust Control Design using Micro-Actuators. Recent advances in micro-actuators have enabled many new applications in complex systems. Examples include ultra-high density disk drives, low-cost vibration tables, and micro-robotic systems. However, control design for these systems is very challenging because the micro-actuators have severely limited dynamic ranges and strong couplings. The proposed project aims to study new control design approaches for these complex systems. The work will focus o ....Robust Control Design using Micro-Actuators. Recent advances in micro-actuators have enabled many new applications in complex systems. Examples include ultra-high density disk drives, low-cost vibration tables, and micro-robotic systems. However, control design for these systems is very challenging because the micro-actuators have severely limited dynamic ranges and strong couplings. The proposed project aims to study new control design approaches for these complex systems. The work will focus on both theoretical studies and experimental applications of such systems. The outcome of the project will help put Australia in a more advanced position in this niche area of leading age technology.Read moreRead less
Holographic Videography for Spatial Communication. This project is aimed at developing a true colour holographic video display in which a user or users may interact with completely synthetic objects.
This will be the first system of its kind, giving a user the illusion of real physical interaction with a completely holographic object. The illusion may be shared by many participants without the use of external aids. The project has the potential to improve productivity in many applications suc ....Holographic Videography for Spatial Communication. This project is aimed at developing a true colour holographic video display in which a user or users may interact with completely synthetic objects.
This will be the first system of its kind, giving a user the illusion of real physical interaction with a completely holographic object. The illusion may be shared by many participants without the use of external aids. The project has the potential to improve productivity in many applications such as geospatial information systems, x-ray inspection, and medical imaging, by giving a user a much more natural way of interacting with three dimensional data.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454017
Funder
Australian Research Council
Funding Amount
$582,598.00
Summary
A unique Western Australian multi-photon confocal microscope facility to support nationally prioritised biomedical, biological and materials research. Core national priority research will utilise the low dose and penetrative nature of multi-photon confocal microscopy in current research into nerve regeneration after neurotrauma, the histopathological treatment of diabetic retinopathology, and hair cell information transfer processes in auditory physiology. Other programs will study biomineralisa ....A unique Western Australian multi-photon confocal microscope facility to support nationally prioritised biomedical, biological and materials research. Core national priority research will utilise the low dose and penetrative nature of multi-photon confocal microscopy in current research into nerve regeneration after neurotrauma, the histopathological treatment of diabetic retinopathology, and hair cell information transfer processes in auditory physiology. Other programs will study biomineralisation in the superior epithelium of chiton and limpet teeth and a variety of salinity-related plant processes. In parallel, an optical development program will investigate contrast modes in other non-linear interactions. The instrument complements and will be managed with field emission SEM, TEM and a unique high-resolution scanning ion probe in a well-established regional Centre.Read moreRead less
A Laser Guide Star using a High Power, Synchronously Pumped Optical Parametric Oscillators. We will develop a novel high power source of 589nm coherent (laser) light to be used to create a laser guide star by exciting sodium atoms in the earth's upper atmosphere (the mesosphere). This is needed to determine the distortion caused by the atmosphere on an optical beam propagating through it and generate the information needed to correct those distortions using an adaptive optics telescope. This pr ....A Laser Guide Star using a High Power, Synchronously Pumped Optical Parametric Oscillators. We will develop a novel high power source of 589nm coherent (laser) light to be used to create a laser guide star by exciting sodium atoms in the earth's upper atmosphere (the mesosphere). This is needed to determine the distortion caused by the atmosphere on an optical beam propagating through it and generate the information needed to correct those distortions using an adaptive optics telescope. This project focuses on the development of a novel high power 589nm source based on a synchronously pumped optical parametric oscillator.Read moreRead less
Analysis, Optimization, and Control of Scanning Atomic Force Microscope Micro-Cantilever Probes. Atomic Force Microscopes (AFM's) are widely used for the examination of samples smaller than can be observed with an optical microscope. A tiny 'finger', only a few atoms wide at its sharpest point, is used to 'feel' the surface of a sample. This project aims to increase the resolution of AFM images by actively controlling the sensor probe dynamics.
Better quality AFM images would allow scientists ....Analysis, Optimization, and Control of Scanning Atomic Force Microscope Micro-Cantilever Probes. Atomic Force Microscopes (AFM's) are widely used for the examination of samples smaller than can be observed with an optical microscope. A tiny 'finger', only a few atoms wide at its sharpest point, is used to 'feel' the surface of a sample. This project aims to increase the resolution of AFM images by actively controlling the sensor probe dynamics.
Better quality AFM images would allow scientists to further investigate the atomic and molecular structure of such samples as: metals, polymers, cells, and proteins.
This research will contribute to the design of an Australian made Scanning Probe Microscope. Development of local expertise will provide a valuable resource for Australian scientific and industrial research.
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Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be ....Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be developed that will add to the nation's skill base. The outcomes of the project will enhance Australia's knowledge capacity, research capability and will contribute significantly to each of the National Research Priorities.Read moreRead less