Protein chips for the high-throughput study of immune complexes by mass spectrometry. Mass spectrometry is a core enabling technology for proteomics with proteins identified by molecular weight, mass maps and sequencing within the confines of a mass spectrometer. We have found conditions under which it is possible to preserve and detect protein complexes by matrix-assisted laser desorption ionization (MALDI) mass spectrometry that has promising implications for the high-throughput screening of p ....Protein chips for the high-throughput study of immune complexes by mass spectrometry. Mass spectrometry is a core enabling technology for proteomics with proteins identified by molecular weight, mass maps and sequencing within the confines of a mass spectrometer. We have found conditions under which it is possible to preserve and detect protein complexes by matrix-assisted laser desorption ionization (MALDI) mass spectrometry that has promising implications for the high-throughput screening of protein-protein interactions. Technologies pioneered by the applicant will be advanced to achieve the high-throughput analysis of antibody complexes with native gel recovered protein antigens across emerging strains of the influenza virus by means of miniature protein chips.Read moreRead less
New Membrane Chips For Protein Interaction Analysis. This proposal is based on a strategic partnership between Monash University and Farfield Sensors. We will create a series of new biosensors that will be used to establish a new approach to the structural analysis of membrane protein function. In particular, this technology may lead to the identification of new proteins and drug targets for therapeutic development. The long-term outcome would be the development of improved therapeutics which wo ....New Membrane Chips For Protein Interaction Analysis. This proposal is based on a strategic partnership between Monash University and Farfield Sensors. We will create a series of new biosensors that will be used to establish a new approach to the structural analysis of membrane protein function. In particular, this technology may lead to the identification of new proteins and drug targets for therapeutic development. The long-term outcome would be the development of improved therapeutics which would be coupled to potential economic returns when further commercialisation is achieved. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237527
Funder
Australian Research Council
Funding Amount
$170,000.00
Summary
Bioscope IV : Advanced Scanned Probe Microscopy. The Atomic Force Microscope presents a unique view of the microscopic and molecular world, for it is sensitive to force alone. This instrument can accurately map force over a surface at the molecular scale; picoNewtons at nanometre resolution. The host of intermolecular forces which cause phenomena such as self-assembly, colloid stability, cell interactions and friction are only directly measurable with this technique. In this field of force meas ....Bioscope IV : Advanced Scanned Probe Microscopy. The Atomic Force Microscope presents a unique view of the microscopic and molecular world, for it is sensitive to force alone. This instrument can accurately map force over a surface at the molecular scale; picoNewtons at nanometre resolution. The host of intermolecular forces which cause phenomena such as self-assembly, colloid stability, cell interactions and friction are only directly measurable with this technique. In this field of force measurement Australian researchers are leaders. The proposed instrument expands the capabilities of this effort, and develops exciting new directions including the direct manipulation of molecules through a novel feedback and control (haptic) interface.Read moreRead less
Diffractive Imaging using Soft X-rays and Electrons. Optical, electron and x-ray microscopy has yielded enormous biological insights and medical benefits to society. Optical microscopy is able to image live tissue, but at relatively low resolution. Electron microscopy can yield high resolution images, but only of highly prepared material. X-ray microscopy yields images of live tissue with a resolution that is intermediate between optical and electron microscopy. This project will provide Austral ....Diffractive Imaging using Soft X-rays and Electrons. Optical, electron and x-ray microscopy has yielded enormous biological insights and medical benefits to society. Optical microscopy is able to image live tissue, but at relatively low resolution. Electron microscopy can yield high resolution images, but only of highly prepared material. X-ray microscopy yields images of live tissue with a resolution that is intermediate between optical and electron microscopy. This project will provide Australian scientists with their first access to x-ray microscopy at its optimum wavelength; and secondly it will provide a superb testbed for x-ray microscopy to be enhanced using unique methods being developed in Australia.Read moreRead less
Optical manipulation of single molecules in nanocontainers and nanotubes. Modern medicine has benefited greatly from technological advances in instrumentation. The ability to probe and manipulate new aspects of biological function often provides unique information that can be used as the basis of new medical treatments. Recent advances in optical instrumentation and biochemical labelling has enabled the study of biological function at the single molecule level. This project proposes to develop n ....Optical manipulation of single molecules in nanocontainers and nanotubes. Modern medicine has benefited greatly from technological advances in instrumentation. The ability to probe and manipulate new aspects of biological function often provides unique information that can be used as the basis of new medical treatments. Recent advances in optical instrumentation and biochemical labelling has enabled the study of biological function at the single molecule level. This project proposes to develop new techniques in single molecule manipulation, to perform studies not easily addressable using current techniques. The proposed research will form the basis of an enabling technology for Australian researchers to make breakthroughs in biomedical research, potentially leading to improvements in healthcare.Read moreRead less
Enabling Technologies for Motion Corrected Positron Emission Tomography (PET) of Unanaesthetized Laboratory Animals. Small animal molecular imaging is a powerful tool in biological research and drug discovery. Anaesthesia is routinely used to avoid motion distortion, but can profoundly alter the biological process studied. This research will enable quantitative imaging of neurobiological phenomena in awake laboratory animals. It will create new opportunities for Australian basic researchers to ....Enabling Technologies for Motion Corrected Positron Emission Tomography (PET) of Unanaesthetized Laboratory Animals. Small animal molecular imaging is a powerful tool in biological research and drug discovery. Anaesthesia is routinely used to avoid motion distortion, but can profoundly alter the biological process studied. This research will enable quantitative imaging of neurobiological phenomena in awake laboratory animals. It will create new opportunities for Australian basic researchers to use innovative technology with expected high economic potential, and benefit small biotech companies by facilitating pre-clinical and clinical development of new pharmaceuticals. The new motion tracking and image reconstruction technologies developed will strengthen Australia's leading position in engineering and biomedical systems development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989915
Funder
Australian Research Council
Funding Amount
$127,000.00
Summary
X-ray Nano-scale Coherence Facility. Australia is rapidly developing into a world leader for x-ray imaging. This position has been supported by leading research groups and more recently by the development of the Australian Synchrotron. This project will fill a vital missing link in the experimental capability of Australian researchers - a flexible facility that can provide a nanoscale x-ray source. This enhanced capability will lead to new developments in coherent imaging methods. These new meth ....X-ray Nano-scale Coherence Facility. Australia is rapidly developing into a world leader for x-ray imaging. This position has been supported by leading research groups and more recently by the development of the Australian Synchrotron. This project will fill a vital missing link in the experimental capability of Australian researchers - a flexible facility that can provide a nanoscale x-ray source. This enhanced capability will lead to new developments in coherent imaging methods. These new methods will be used in the study of biological systems, leading to better drug design as well as in the study of materials, leading to stronger and lighter components. Read moreRead less
Elucidating the mechanisms by which Scribble, Discs Large and Lethal Giant Larvae regulate epithelial polarity. Discs Large (Dlg) and Scribble are proteins that regulate cell shape by concentrating at particular regions within the cell and recruiting other proteins to that region. It is thought that the two proteins interact with each other, and with other proteins involved in protein trafficking and cell architecture, but it is not known how these events coordinate to produce a net outcome on ....Elucidating the mechanisms by which Scribble, Discs Large and Lethal Giant Larvae regulate epithelial polarity. Discs Large (Dlg) and Scribble are proteins that regulate cell shape by concentrating at particular regions within the cell and recruiting other proteins to that region. It is thought that the two proteins interact with each other, and with other proteins involved in protein trafficking and cell architecture, but it is not known how these events coordinate to produce a net outcome on cell shape. To answer these questions, the dynamic events involved in localization of Dlg, Scribble, and associated proteins will be determined, in mammalian cells and in whole organs of the vinegar fly.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
Nanometric optical sensing for characterisation of microbioreactors. Microfabrication of microfluidic based microbioreactors is a novel technology that is creating advanced tools in the fields of biology and medicine. A critically important step in the development of a microbioreactor is the ability to characterise fluid shear stress of the microenvironment without impacting on the biological system. The development of a microbioreactor in which individual or multiple cells can be cultured and ....Nanometric optical sensing for characterisation of microbioreactors. Microfabrication of microfluidic based microbioreactors is a novel technology that is creating advanced tools in the fields of biology and medicine. A critically important step in the development of a microbioreactor is the ability to characterise fluid shear stress of the microenvironment without impacting on the biological system. The development of a microbioreactor in which individual or multiple cells can be cultured and manipulated will have a significant impact on study of biological systems in cancer research and stem cell research. Read moreRead less