Development of non-iodinated, non ionic, water-soluble metal based compounds for clinical administration as radiographic contrast media. Every year Australia spends more than $50 million on importing radiographic contrast media, in an international market worth more than $1 billion pa. Existing iodine based agents, which currently cause major adverse reactions in 1% of the population, could be replaced by new metal based imaging media which provide both enhanced contrast and greater patient safe ....Development of non-iodinated, non ionic, water-soluble metal based compounds for clinical administration as radiographic contrast media. Every year Australia spends more than $50 million on importing radiographic contrast media, in an international market worth more than $1 billion pa. Existing iodine based agents, which currently cause major adverse reactions in 1% of the population, could be replaced by new metal based imaging media which provide both enhanced contrast and greater patient safety and comfort. Even a small fraction of the international market would generate millions of dollars in overseas income from a range of potential sources, including licensing/royalties to export by a local start-up company, and expansion of rare earth mining in Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560680
Funder
Australian Research Council
Funding Amount
$901,862.00
Summary
Vibrational Spectroscopy Microprobe/FESEM/AFM Imaging of Cells, Tissues and Materials. State-of-the-art vibrational mapping and imaging equipment (integrated with a field-emission scanning electron microscope (FESEM) and an atomic force microscope (AFM)) will provide enabling technologies for cutting-edge research in disease diagnosis, identification of pathogens, mapping of the entry and distribution of pharmaceutics into cells, and materials research. An InVia Renishaw Raman spectrometer (sub ....Vibrational Spectroscopy Microprobe/FESEM/AFM Imaging of Cells, Tissues and Materials. State-of-the-art vibrational mapping and imaging equipment (integrated with a field-emission scanning electron microscope (FESEM) and an atomic force microscope (AFM)) will provide enabling technologies for cutting-edge research in disease diagnosis, identification of pathogens, mapping of the entry and distribution of pharmaceutics into cells, and materials research. An InVia Renishaw Raman spectrometer (sub-micron spatial positioning and micron spatial resolution) will be interfaced to an FEI Quanta FESEM for combined Raman (spectroscopic), EDS and SEM (morphological) imaging/mapping at the sub-cellular level. Complementary new-generation Raman and IR spectrometer upgrades will provide an integrated world-class equipment platform.Read moreRead less
Novel Self Assembled Particle Systems as a Key to Next Generation Biosensor Technology. Development and commercialisation of products utilising nanotechnology is crucial to future wealth creation for Australia. The translational research in this proposal will progress innovative concepts in nanotechnology-based biosensors, with potential for substantial improvements in disease diagnosis, leading to more economical and timely therapy. The products that arise from this research will also provide f ....Novel Self Assembled Particle Systems as a Key to Next Generation Biosensor Technology. Development and commercialisation of products utilising nanotechnology is crucial to future wealth creation for Australia. The translational research in this proposal will progress innovative concepts in nanotechnology-based biosensors, with potential for substantial improvements in disease diagnosis, leading to more economical and timely therapy. The products that arise from this research will also provide further employment for Australians, building on Universal Biosensor’s proven record of commercialization in Australia. The project will lead to training of Australian researchers in nanotechnology and in utilization of key Australian science infrastructure including the Australian Synchrotron and the Melbourne Centre for Nanofabrication.Read moreRead less
Peptide Nucleic Acid Based Sensors and Devices - An Investigation into PNA Versatility for Emerging Gene Technologies. Peptide nucleic acids (PNAs) are analogues of DNA that may have important implications as therapeutic agents for the cure of diseases based on genetic defects. The attributes of PNAs that make them potentially viable as a drug are also well suited to their development as sensors and molecular devices. In this proposal, we wish to develop a series of PNAs containing photoactive ....Peptide Nucleic Acid Based Sensors and Devices - An Investigation into PNA Versatility for Emerging Gene Technologies. Peptide nucleic acids (PNAs) are analogues of DNA that may have important implications as therapeutic agents for the cure of diseases based on genetic defects. The attributes of PNAs that make them potentially viable as a drug are also well suited to their development as sensors and molecular devices. In this proposal, we wish to develop a series of PNAs containing photoactive elements (a) as alternatives to commercially-available fluorophores, (b) for the early detection of neurodegenerative diseases and (c) to contribute to one of Science's most debated issues i.e. "does DNA mediate electron transport?"Read moreRead less
Fabrication and Application of Ion-Sensors Based on the Voltammetry of Nanocrystals Adhered to Electrode Surfaces. A significant need exists for the low cost determination of cations and anions in biologically (blood, urine), industrially (process streams) and environmentally (rivers, lakes) important fluids. In this project, skills in sensor design, scientific instrumentation, materials science, electrochemistry and analytical science provided by a consortium of scientists at Monash University ....Fabrication and Application of Ion-Sensors Based on the Voltammetry of Nanocrystals Adhered to Electrode Surfaces. A significant need exists for the low cost determination of cations and anions in biologically (blood, urine), industrially (process streams) and environmentally (rivers, lakes) important fluids. In this project, skills in sensor design, scientific instrumentation, materials science, electrochemistry and analytical science provided by a consortium of scientists at Monash University, the Victorian Institute for Chemical Sciences, Oxford Biosensors and Oxford University will be integrated to fabricate and develop applications of commercially viable ion-sensing systems. The principles to be utilised are based on novel forms of voltammetry of nanocrystals adhered to electrode surfaces.Read moreRead less
Nanoscale Coating and Biomodification of Colloids for Biological Applications. The research entails the preparation of novel biofunctional colloids of nanometer to micrometer dimensions and their utilisation in biological applications. Self-assembly processes will be exploited to achieve nanoscale biomodification of technologically important colloid particles, including latex beads and rare earth and semiconductor nanoparticles. The studies conducted will generate fundamental knowledge pertainin ....Nanoscale Coating and Biomodification of Colloids for Biological Applications. The research entails the preparation of novel biofunctional colloids of nanometer to micrometer dimensions and their utilisation in biological applications. Self-assembly processes will be exploited to achieve nanoscale biomodification of technologically important colloid particles, including latex beads and rare earth and semiconductor nanoparticles. The studies conducted will generate fundamental knowledge pertaining to the underlying factors that govern the formation of biofunctional colloid particles through self-assembly. This is essential for the development of tailored colloids that will meet the demands placed on nanomaterials synthesis and performance by nanotechnology. The colloids prepared will find new applications in medicine, biocatalysis and bioassays.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989567
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
State of the Art Surface Characterisation Facility for the Sydney Basin. Many of the grand challenges of our time, including finding alternative sources of energy, maximizing our current supply of natural resources, identifying and treating pollution in general, and in water in particular, and developing therapies and biomaterials that enable the personalisation of therapies to each individual are being solved using developments in the molecular sciences. Pivotal to the success of such research ....State of the Art Surface Characterisation Facility for the Sydney Basin. Many of the grand challenges of our time, including finding alternative sources of energy, maximizing our current supply of natural resources, identifying and treating pollution in general, and in water in particular, and developing therapies and biomaterials that enable the personalisation of therapies to each individual are being solved using developments in the molecular sciences. Pivotal to the success of such research is to understand materials and surfaces at the molecular level. The request is to purchase surface analysis instrumentation which will dramatically enhance the ability of scientists around Australia understand how to develop solutions to these grand challenges.Read moreRead less
Three Dimensional Anti-biofouling Conducting Polymer Hydrogel Electrodes for Biosensor and Biofuel cell Applications. Exploitation of advances in nanotechnology, electrochemical technology, biosensor, biofuel cell and material science are important to Australia's prosperity from a societal industrial perspective. Currently, research in this field is being actively conducted around the world due to their huge potential for commercial applications. Therefore, through the development of new princi ....Three Dimensional Anti-biofouling Conducting Polymer Hydrogel Electrodes for Biosensor and Biofuel cell Applications. Exploitation of advances in nanotechnology, electrochemical technology, biosensor, biofuel cell and material science are important to Australia's prosperity from a societal industrial perspective. Currently, research in this field is being actively conducted around the world due to their huge potential for commercial applications. Therefore, through the development of new principles and concepts, and the synthesis of newly designed materials, this project will bring significant benefits in improving the efficiency of these devices and to promote Australian leadership in the field of medical devices and alternative energy generation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668403
Funder
Australian Research Council
Funding Amount
$570,000.00
Summary
Enhanced micro-Raman and Fluorescence spectroscopy and imaging facility for biosystems and materials. The state-of-the-art spectroscopic and fluorescence imaging equipment will provide cutting-edge capabilities for fundamental and applied research with the potential to impact on improved health outcomes, pharmaceutics, biotechnology and nanomaterials research. Chemical probes based on molecular vibrations and fluorescence will allow changes in biomolecular composition within cells and tissues to ....Enhanced micro-Raman and Fluorescence spectroscopy and imaging facility for biosystems and materials. The state-of-the-art spectroscopic and fluorescence imaging equipment will provide cutting-edge capabilities for fundamental and applied research with the potential to impact on improved health outcomes, pharmaceutics, biotechnology and nanomaterials research. Chemical probes based on molecular vibrations and fluorescence will allow changes in biomolecular composition within cells and tissues to be mapped/imaged down to nanometre spatial resolution. This will provide new techniques for the diagnosis of diseases, e.g. cancer, the rapid identification of pathogens, the understanding and design of new drugs, and a range of biotechnology, nanomaterials and nanotechnology applications.Read moreRead less
Synchrotron developments of new techniques in X-ray interactions with matter, resolving major discrepancies in Quantum Physics and Chemistry. Synchrotron science is a priority area for Australia, the USA, and most first world countries. Development of new ideas and tools for X-ray investigations is the key to future opportunities and is the subject of this proposal. We will develop new techniques for crystallographic electron-density studies, X-ray Anomalous Fine Structure (XAFS) and Multiple-wa ....Synchrotron developments of new techniques in X-ray interactions with matter, resolving major discrepancies in Quantum Physics and Chemistry. Synchrotron science is a priority area for Australia, the USA, and most first world countries. Development of new ideas and tools for X-ray investigations is the key to future opportunities and is the subject of this proposal. We will develop new techniques for crystallographic electron-density studies, X-ray Anomalous Fine Structure (XAFS) and Multiple-wavelength Anomalous Dispersion (MAD), and provide useful advances for X-ray lithography and radiography. Simultaneous investigation of form factors, absorption coefficients, anomalous dispersion and X-ray scattering will provide new experimental tests of relativistic atomic wavefunction calculations, molecular bonding and solid state coupled cluster theory. Major discrepancies will be resolved.Read moreRead less