New high resolution radiation dose mapping of special type polymer-gel dosimeters using mini-MRI scanner of high (4.7 Tesla) magnetic field. Gel dosimeters main advantage is dose determination in 3-dimensions. Their main limitation is low spatial-resolution. We propose fabrication of special-type gels and for the first time use the 4.7 Tesla mini-scanner for dose mapping. Increased magnetic field combined with a small aperture for field dissipation will greatly improve spatial resolution down t ....New high resolution radiation dose mapping of special type polymer-gel dosimeters using mini-MRI scanner of high (4.7 Tesla) magnetic field. Gel dosimeters main advantage is dose determination in 3-dimensions. Their main limitation is low spatial-resolution. We propose fabrication of special-type gels and for the first time use the 4.7 Tesla mini-scanner for dose mapping. Increased magnetic field combined with a small aperture for field dissipation will greatly improve spatial resolution down to micrometers (micro-dosimetry). This new technique will render gel-dosimeters suitable for applications in radiotherapy, industrial and all other radiation fields. Moreover, we will employ new parameter for dose mapping, which is expected to be more sensitive to radiation than the currently used relaxation timesRead moreRead less
Biomolecular activity modulated by interaction with nanostructures. Nanotechnological methods are able to reliably fabricate artificial nanostructures with dimensions similar to those of large biomolecules (a few to tens of nanometers). This study focuses on the interaction of artificial nanostructures with biomolecules such as proteins and DNA, and will enable scientists to better understand biomolecular recognition and binding events, which are central to all biological processes. The underst ....Biomolecular activity modulated by interaction with nanostructures. Nanotechnological methods are able to reliably fabricate artificial nanostructures with dimensions similar to those of large biomolecules (a few to tens of nanometers). This study focuses on the interaction of artificial nanostructures with biomolecules such as proteins and DNA, and will enable scientists to better understand biomolecular recognition and binding events, which are central to all biological processes. The understanding gained can then be used to design biomimetic surfaces for use in health monitoring and medical diagnostic devices with improved sensitivity, robustness and portability, thereby providing significant benefits to the health sector.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775660
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
A National Biomedical Electron Paramagnetic Resonance and Molecular Imaging Centre. Multifrequency continuous wave and pulsed electron paramagnetic resonance spectroscopy and molecular imaging instrumentation will provide forefront technologies in identifying, characterising, quantifying, visualising and manipulating fundamental chemical and biologically relevant processes involving free radicals, metalloproteins and metal ions. This technology is crucial in validating these functional processes ....A National Biomedical Electron Paramagnetic Resonance and Molecular Imaging Centre. Multifrequency continuous wave and pulsed electron paramagnetic resonance spectroscopy and molecular imaging instrumentation will provide forefront technologies in identifying, characterising, quantifying, visualising and manipulating fundamental chemical and biologically relevant processes involving free radicals, metalloproteins and metal ions. This technology is crucial in validating these functional processes at the cellular and tissue level and for providing invaluable and unique biomedical information under physiological conditions. This synergistic and highly integrative approach will make available new techniques for identifying major disease mechanisms such as cardiovascular disease with a potential to improve and maintain health. Read moreRead less
Probing the function of protein molecular motors on nano-fabricated structures. The function of protein linear molecular motors, which are natural dynamic bio-nano-devices with a ubiquitous importance in multicellular organisms, will be 'probed' with purposefully designed nano-structures fabricated via photo- or Scanning Probe Microscopy Lithography, that is, flat polymeric surfaces with combinatorial combinations of physico-chemistries; and micro/nano-channels and nano-wells with critical dimen ....Probing the function of protein molecular motors on nano-fabricated structures. The function of protein linear molecular motors, which are natural dynamic bio-nano-devices with a ubiquitous importance in multicellular organisms, will be 'probed' with purposefully designed nano-structures fabricated via photo- or Scanning Probe Microscopy Lithography, that is, flat polymeric surfaces with combinatorial combinations of physico-chemistries; and micro/nano-channels and nano-wells with critical dimensions similar to the scale of the probed biomolecules. The project turns 'up-side down' the challenge of invasive nano-probing of biomolecules using it in an engineered manner. The fundamental understanding of linear molecular motors will impact on biomedical science and on the assessment of hybrid natural-artificial dynamic nano-devices.Read moreRead less
In-situ Scanning Probe Microscopy of biological redox processes: nanoscale structure and morphology. The science behind this project underpins the development of nanobiotechnology. Immediate applications foreseen, are the development of biosensors and diagnostic devices based on our intimate knowledge of the nature of the protein attachment to a surface. Use of synthetic membranes to create biomimetic surfaces will impact significantly on our understanding of the role and contribution membranes ....In-situ Scanning Probe Microscopy of biological redox processes: nanoscale structure and morphology. The science behind this project underpins the development of nanobiotechnology. Immediate applications foreseen, are the development of biosensors and diagnostic devices based on our intimate knowledge of the nature of the protein attachment to a surface. Use of synthetic membranes to create biomimetic surfaces will impact significantly on our understanding of the role and contribution membranes have on protein structure, function hence disease.Read moreRead less
Advanced high resolution atomic force microscopy of biomolecules in physiological environments. The proposed research is intended to explain high resolution bioimaging problems addressed only phenomenologically before. A correct physical model would help the scientific community to optimise imaging of dynamic biological systems, extending our knowledge about the way living organisms function. With dynamic bioimaging, the mechanism of certain diseases such as Alzheimer's - where biomolecule fiber ....Advanced high resolution atomic force microscopy of biomolecules in physiological environments. The proposed research is intended to explain high resolution bioimaging problems addressed only phenomenologically before. A correct physical model would help the scientific community to optimise imaging of dynamic biological systems, extending our knowledge about the way living organisms function. With dynamic bioimaging, the mechanism of certain diseases such as Alzheimer's - where biomolecule fiber formation plays a key role - can also be addressed, thus the project has even therapeutical relevance. Furthermore, adequate description of liquid phase imaging can help engineers in the design of better hardware and software solutions, for the benefit of the bio-nanotechnological industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347970
Funder
Australian Research Council
Funding Amount
$186,000.00
Summary
Integrated Bio-nano-fabrication Facility. The project proposes the upgrade of a joint facility for the probing, fabrication and operation of hybrid bio-nano-devices. The facility will enhance the proposers' capabilities in the area of the fundamental and prototype-type research on biomolecular/cellular devices. The ultimate goal of these projects is to thrust Australian science in the era when the essential functions of cells can be replicated and controlled on devices that are smaller than livi ....Integrated Bio-nano-fabrication Facility. The project proposes the upgrade of a joint facility for the probing, fabrication and operation of hybrid bio-nano-devices. The facility will enhance the proposers' capabilities in the area of the fundamental and prototype-type research on biomolecular/cellular devices. The ultimate goal of these projects is to thrust Australian science in the era when the essential functions of cells can be replicated and controlled on devices that are smaller than living cells. The proposed facility has a modular structure consisting of additional nano-positioning, confocal microscope and zeta potential modules built on the existent laser tweezers/scissors, picoliter pipette and Atomic Force Microscope modules.Read moreRead less
Coherent X-ray Science and Biophysics. The twenty first century is said to be the century of biology. And there is no doubt that the development of our understanding of biological system is continuing at a massive rate. However, as our understanding deepens, we need to draw on the whole range of scientific disciplines to proceed. This program draws together a multidisciplinary team of world-leading scientists to address one the key questions in modern biology, the structure of a membrane protein ....Coherent X-ray Science and Biophysics. The twenty first century is said to be the century of biology. And there is no doubt that the development of our understanding of biological system is continuing at a massive rate. However, as our understanding deepens, we need to draw on the whole range of scientific disciplines to proceed. This program draws together a multidisciplinary team of world-leading scientists to address one the key questions in modern biology, the structure of a membrane protein. We will develop techniques based on the latest developments in theoretical physics & chemistry, imaging, biology and technology - including the new Australian Synchrotron - to create new approaches to structural biology.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