Plasmon nanobiosensor for whole blood analysis. The new method will be able to detect specific disease markers or to identify subtle differences in protein content in complex dense analytes such as blood and other body fluids, of practical utility in diagnostic and clinical situations. It will also be relevant in other areas such as medical diagnostics of viral diseases, and for unsolved environmental monitoring problems such as the presence of specific microorganisms in industrial waste. Owing ....Plasmon nanobiosensor for whole blood analysis. The new method will be able to detect specific disease markers or to identify subtle differences in protein content in complex dense analytes such as blood and other body fluids, of practical utility in diagnostic and clinical situations. It will also be relevant in other areas such as medical diagnostics of viral diseases, and for unsolved environmental monitoring problems such as the presence of specific microorganisms in industrial waste. Owing to their design simplicity and low cost of components, the devices developed in this program will lend themselves well to the development of new commercial technologies for Australia.Read moreRead less
Special Research Initiatives - Grant ID: SR0354517
Funder
Australian Research Council
Funding Amount
$20,000.00
Summary
Adaptive Optics for Australian Astronomy, Medicine, Industry, and Defence. Adaptive optics is a technique for correcting wavefront distortions in light beams to improve optical imaging performance. The Research Network for Adaptive Optics aims to draw together isolated Australian and New Zealand research groups working on adaptive optics applications in disparate areas to achieve a critical mass of researchers in this burgeoning field. Adaptive optics has wide application in areas as diverse as ....Adaptive Optics for Australian Astronomy, Medicine, Industry, and Defence. Adaptive optics is a technique for correcting wavefront distortions in light beams to improve optical imaging performance. The Research Network for Adaptive Optics aims to draw together isolated Australian and New Zealand research groups working on adaptive optics applications in disparate areas to achieve a critical mass of researchers in this burgeoning field. Adaptive optics has wide application in areas as diverse as astronomy, vision science, ophthalmology, microscopy, optical communications, laser radar, and laser beam shaping. The Research Network will coordinate and expand Australian involvement in these areas and inform industry, as have similar networks in the USA and Europe.Read moreRead less
Optically-driven micromachines and microtools. The use of optical forces to trap and manipulate microscopic particles has developed from a novelty into a widely used versatile research tool - optical tweezers. New advances, such as the application and optical measurement of optical torque, have been brought to the brink of practical application. We will apply these methods to the development and production of micromachines of unprecedently small size, and the development of new medical diagnosti ....Optically-driven micromachines and microtools. The use of optical forces to trap and manipulate microscopic particles has developed from a novelty into a widely used versatile research tool - optical tweezers. New advances, such as the application and optical measurement of optical torque, have been brought to the brink of practical application. We will apply these methods to the development and production of micromachines of unprecedently small size, and the development of new medical diagnostic techniques, and industrial and research tools.Read moreRead less
Imaging of properties of coherent elastic light scattering from turbid biological media. Imaging with coherent, elastically-scattered light for visualisation of thick-tissue morphology in vivo, or of cells buried deep in a turbid medium, remains a major challenge. We adopt an alternative approach of imaging of properties of light scattering based on regarding cellular tissue as a spatially-varying refractive-index continuum which encodes scattered light. We propose new methodologies to infer t ....Imaging of properties of coherent elastic light scattering from turbid biological media. Imaging with coherent, elastically-scattered light for visualisation of thick-tissue morphology in vivo, or of cells buried deep in a turbid medium, remains a major challenge. We adopt an alternative approach of imaging of properties of light scattering based on regarding cellular tissue as a spatially-varying refractive-index continuum which encodes scattered light. We propose new methodologies to infer tissue state and morphology indirectly based on phase delay, speckle, and angle-resolved scattering. We will break new ground in correlating the structure and function of in situ epithelial tissue and cells to light scattering enabling, e.g., the detection of mitosis and apoptosis in cells buried in thick, turbid media, and of cancers and precancers in vivo.Read moreRead less
Intravital super-resolution imaging via Stimulated Emission Depletion microscopy (STED)-microendoscopy. We will develop a new technology to enable the imaging of sub-cellular structures within a biological specimen, with super-resolution. This intravital super-resolution imaging technology will build off world leading techniques to image objects with super-resolution and to perform this within a specimen, with minimal invasion. The broad ramifications of this technology apply to biology, medical ....Intravital super-resolution imaging via Stimulated Emission Depletion microscopy (STED)-microendoscopy. We will develop a new technology to enable the imaging of sub-cellular structures within a biological specimen, with super-resolution. This intravital super-resolution imaging technology will build off world leading techniques to image objects with super-resolution and to perform this within a specimen, with minimal invasion. The broad ramifications of this technology apply to biology, medical science, imaging and sensing. Important applications include the early detection of debilitating diseases and the advancement of understanding of cellular biology. This research will raise Australia's profile as a world leader in science and technology, building on our emerging presence in the biophysical sciences.Read moreRead less
Quantitative polarisation phase microscopy: A new tool for advances in structural analysis and biophotonics. Innovation in biomedical research is driven by technology in optical imaging. Optical imaging methods including polarisation microscopy are widely accepted and are at the forefront of biomedical scientific discoveries. This project undertakes fundamental and applied research innovatively combining polarisation imaging and quantitative phase imaging microscopy to uniquely quantify the phys ....Quantitative polarisation phase microscopy: A new tool for advances in structural analysis and biophotonics. Innovation in biomedical research is driven by technology in optical imaging. Optical imaging methods including polarisation microscopy are widely accepted and are at the forefront of biomedical scientific discoveries. This project undertakes fundamental and applied research innovatively combining polarisation imaging and quantitative phase imaging microscopy to uniquely quantify the physical thickness and morphology of birefringent specimens such as the cardiac muscle cell. This project, while of substantial intellectual merit in its own right, could also have the potential to lead to the detection of the mechanisms related to heart failure. Read moreRead less
Scaling-up microstructured fibres for terahertz radiation. Terahertz radiation is the last region of the electromagnetic spectrum to be fully utilised. Many applications have been identified but their practicality has been limited by a lack of low-loss flexible waveguides. The waveguides to be developed in this project will build on Australia's existing international lead and investments in photonics as well as extend the dynamic field of microstructured optical fibres, indentified as the 'futur ....Scaling-up microstructured fibres for terahertz radiation. Terahertz radiation is the last region of the electromagnetic spectrum to be fully utilised. Many applications have been identified but their practicality has been limited by a lack of low-loss flexible waveguides. The waveguides to be developed in this project will build on Australia's existing international lead and investments in photonics as well as extend the dynamic field of microstructured optical fibres, indentified as the 'future' of optical fibres. Low-loss flexible waveguides will enable imaging and spectroscopy applications that can reveal and object's internal structure and composition. This will have immediate applications in security, quality control, medical imaging and other safety or industrial applications.Read moreRead less
Cytorefractometry - a new technique for refractive index tomography of living cells. An ultrahigh-resolution bifocal optical coherence refractometry is proposed, and will result to micron-scale-resolution refractive index tomography of living cells, termed cytorefractometry. This technique represents an extension from bifocal optical coherence refractometry that has recently shown a remarkable promise for direct, several-frames-per-second, motion-artifact-free determination of refractive index ....Cytorefractometry - a new technique for refractive index tomography of living cells. An ultrahigh-resolution bifocal optical coherence refractometry is proposed, and will result to micron-scale-resolution refractive index tomography of living cells, termed cytorefractometry. This technique represents an extension from bifocal optical coherence refractometry that has recently shown a remarkable promise for direct, several-frames-per-second, motion-artifact-free determination of refractive index in turbid media, including biological tissue in vivo. We propose to apply our novel technique to study tissue calcification, a serious problem in cardiology, by making use of the refractive index contrast mechanism. Calcification of smooth muscle cells and aorta subdermal implant models will be studied aiming for prevention of calcification-associated pathologies.Read moreRead less
Raman conversion in diamond: Next generation long and far infrared and terahertz lasers. Through the creation of practical and powerful long wave infrared and terahertz lasers, this project will enable more rapid progress in many fields of science and technology, and in important medical, environmental and safeguarding applications of national priority. Australia also stands to benefit economically via commercialization of diamond-based Raman lasers and instruments into the market. The project w ....Raman conversion in diamond: Next generation long and far infrared and terahertz lasers. Through the creation of practical and powerful long wave infrared and terahertz lasers, this project will enable more rapid progress in many fields of science and technology, and in important medical, environmental and safeguarding applications of national priority. Australia also stands to benefit economically via commercialization of diamond-based Raman lasers and instruments into the market. The project will produce highly-trained researchers and students in the theory, design and development of diamond sources, enhance Australia's existing strengths in waveguide optics and photonics, and place Australia at the forefront of research in long-wave infrared and terahertz science.Read moreRead less
The creation and opimisation of new optical fibres and novel diode-pumped fibre lasers for applications in medicine, defence and the environment. The project will widen Australian laser research and contains the important steps required to progress beyond the recent demonstrations of super high power and ultra-compact mode-locked operation. The proposed fibre lasers are internationally significant, will address many applications and will keep Australia at the leading edge of laser and optical fi ....The creation and opimisation of new optical fibres and novel diode-pumped fibre lasers for applications in medicine, defence and the environment. The project will widen Australian laser research and contains the important steps required to progress beyond the recent demonstrations of super high power and ultra-compact mode-locked operation. The proposed fibre lasers are internationally significant, will address many applications and will keep Australia at the leading edge of laser and optical fibre research. The array of new technologies necessary for the development of the proposed lasers will be vitally important to Australia's high technology industries.Read moreRead less