The fate of dietary selenium in vivo; a direct approach to linking chemical form with biological activity. Dietary selenium supplementation has great potential as a preventative treatment for a range of human health conditions, including cancer, that widely affect the Australian population. However, the adverse effects of such treatments are not fully recognised. This project will increase our knowledge of how selenium compounds are stored and utilised in the body and relate the information to c ....The fate of dietary selenium in vivo; a direct approach to linking chemical form with biological activity. Dietary selenium supplementation has great potential as a preventative treatment for a range of human health conditions, including cancer, that widely affect the Australian population. However, the adverse effects of such treatments are not fully recognised. This project will increase our knowledge of how selenium compounds are stored and utilised in the body and relate the information to clinical observations regarding dietary intake of selenium and other compounds. The new understanding generated will delineate the conditions for safe intake, so that the beneficial effects associated with selenium supplementation may be harnessed more effectively.Read moreRead less
Development of Pyrrolopyrimidines as Inhibitors of ATP-Binding Proteins. This project seeks to generate analogues of natural products that have been found to be active against cancer cells and tropical parasites. The new materials produced by this project will aid in the study of biochemical processes involved in diseases such as cancer and lymphatic filariasis, thus leading the way to development of these compounds as potential treatments for such diseases.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100087
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Regional Facility for Molecular Characterisation and Mapping. Researchers at the Schools of Chemistry at The Australian National University and University of Wollongong are involved in a range of projects where new molecules are synthesised or discovered in natural products such as rainforest plants and marine organisms. Some of the molecules have already shown promise against diseases such as Alzheimer's and cardiovascular disease. In order to fully characterise these molecules, two complementa ....Regional Facility for Molecular Characterisation and Mapping. Researchers at the Schools of Chemistry at The Australian National University and University of Wollongong are involved in a range of projects where new molecules are synthesised or discovered in natural products such as rainforest plants and marine organisms. Some of the molecules have already shown promise against diseases such as Alzheimer's and cardiovascular disease. In order to fully characterise these molecules, two complementary mass spectrometers, replacing ageing instrumentation will be commissioned at each site. In addition, researchers in Wollongong will acquire a MALDI mass spectrometer capable of imaging the distribution of molecules on tissues that may be pathologically important.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560862
Funder
Australian Research Council
Funding Amount
$546,700.00
Summary
South Australian Facility for Advanced Molecular Imaging. The aim of this project is to establish the South Australian Facility for Advanced Molecular Imaging. The Facility builds on existing expertise and cooperation between the collaborating institutions to expand our capability in advanced analytical confocal microscopy of a wide range of materials from living cells to artificial surfaces. New state-of-the-art microscopes will allow the direct quantitative analysis of molecular interactions w ....South Australian Facility for Advanced Molecular Imaging. The aim of this project is to establish the South Australian Facility for Advanced Molecular Imaging. The Facility builds on existing expertise and cooperation between the collaborating institutions to expand our capability in advanced analytical confocal microscopy of a wide range of materials from living cells to artificial surfaces. New state-of-the-art microscopes will allow the direct quantitative analysis of molecular interactions with high temporal and spatial resolutions. This will advance: understanding the regulation of cellular signalling, gene expression and growth in normal and pathological conditions; development of biosensor technology; and the application of new biomaterials in medicine and industry.Read moreRead less
Mathematical and mechanical models in nano-engineering and nanomedicine. The major environmental problems generated from global warming and the major human health problems, like cancer and diabetes, if they are to be solved at all, will most likely be resolved making use of advances in nanobiotechnology. This proposal will position Australia as a leader in the modelling of nanodevices such as gigahertz oscillators, nano-electromagnets, nanosensors, nanosyringes and nanoporous media suitable for ....Mathematical and mechanical models in nano-engineering and nanomedicine. The major environmental problems generated from global warming and the major human health problems, like cancer and diabetes, if they are to be solved at all, will most likely be resolved making use of advances in nanobiotechnology. This proposal will position Australia as a leader in the modelling of nanodevices such as gigahertz oscillators, nano-electromagnets, nanosensors, nanosyringes and nanoporous media suitable for hydrogen storage and gas separation, which will lead to new technologies and commercial spin-offs that will be of major benefit to this country. The applicants will develop a range of topics in nano-engineering and nanomedicine, training a team that will provide the next generation of researchers in these vital areas.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882289
Funder
Australian Research Council
Funding Amount
$520,000.00
Summary
New generation mass spectrometers for characterisation of molecular shape and size. The ion mobility mass spectrometer (IMMS at UOW) will be the first of its kind in Australia, and together with the ion trap mass spectrometer (ITMS at ANU) will continue the tradition of this partnership in providing researchers with cutting-edge instrumentation for nationally and internationally important projects including: (i) fundamental understanding of the ways in which biomolecules recognize one another, ( ....New generation mass spectrometers for characterisation of molecular shape and size. The ion mobility mass spectrometer (IMMS at UOW) will be the first of its kind in Australia, and together with the ion trap mass spectrometer (ITMS at ANU) will continue the tradition of this partnership in providing researchers with cutting-edge instrumentation for nationally and internationally important projects including: (i) fundamental understanding of the ways in which biomolecules recognize one another, (ii) investigating the structure(s) of lipids (fats) in cardiovascular disease and cataract, (iii) developing anticancer drugs, and (iv) development of new materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560657
Funder
Australian Research Council
Funding Amount
$740,000.00
Summary
Ultra-High Resolution NMR Imaging System for Nanotechnology including Nanobiotechnology. The ultra-high resolution imaging NMR spectrometer at the centre of this application is a generation ahead of comparable facilities in Australia and will extend the research capacity of numerous research groups comprising in excess of 50 academics and postgraduate students. The aims and significance of this infrastructure lie in it being one of the centrepieces of the partner institutions' aspirations to tak ....Ultra-High Resolution NMR Imaging System for Nanotechnology including Nanobiotechnology. The ultra-high resolution imaging NMR spectrometer at the centre of this application is a generation ahead of comparable facilities in Australia and will extend the research capacity of numerous research groups comprising in excess of 50 academics and postgraduate students. The aims and significance of this infrastructure lie in it being one of the centrepieces of the partner institutions' aspirations to take Australia to the cutting edge of nanotechnology and cognate disciplines many of which are areas of national priority. The expected manifold outcomes include research of the highest rank into fundamental problems of drug development through to applied outcomes such as new nanomaterials and improved horticulture/fruit preservation.Read moreRead less
Novel Mass Spectrometric Approaches to the Study of Protein-Protein Interactions. Protein-protein interactions mediate all fundamental cellular processes, yet the structural complexity of protein assemblies mean they are often difficult to characterise using traditional analytical methods. This project will develop and demonstrate novel mass spectrometric approaches towards a molecular level description of the structure and interactions of biological protein complexes, which in turn may underpi ....Novel Mass Spectrometric Approaches to the Study of Protein-Protein Interactions. Protein-protein interactions mediate all fundamental cellular processes, yet the structural complexity of protein assemblies mean they are often difficult to characterise using traditional analytical methods. This project will develop and demonstrate novel mass spectrometric approaches towards a molecular level description of the structure and interactions of biological protein complexes, which in turn may underpin the rational design of drugs for the treatment of a range of human health conditions. This project will also provide training of young researchers to the highest international standards in mass spectrometry and protein science, for benefit to Australian industry and research.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989336
Funder
Australian Research Council
Funding Amount
$560,000.00
Summary
The South Australian Facility for Small and Large Molecule X-Ray Diffraction Structure Determination. The precise three dimensional arrangement of atoms within molecular and macromolecular structures defines their function. Thus, the discovery, development and application of biological compounds, catalysts, nanodevices and pharmaceuticals require X-ray diffraction structure determination. These endeavours underpin the conversion of academic research into real benefits for the community and are ....The South Australian Facility for Small and Large Molecule X-Ray Diffraction Structure Determination. The precise three dimensional arrangement of atoms within molecular and macromolecular structures defines their function. Thus, the discovery, development and application of biological compounds, catalysts, nanodevices and pharmaceuticals require X-ray diffraction structure determination. These endeavours underpin the conversion of academic research into real benefits for the community and are critical for the competitiveness of Australian industry, national productivity and economic growth. This application seeks to provide a facility for multidisciplinary scientific development that will enhance academic-industrial collaboration. This will position SA research community for scientific breakthroughs that benefit the Australian community.Read moreRead less
Correlation between surface force and morphology of self-assembled monolayer. As a most potential solid support for biological molecules without denaturing their functions, gold thiol self-assembled monolayers (SAMs) have been studied extensively for surface fabrication. In this project we will prepare functional monolayers using newly synthesized thiol derivatives, evaluate correlation between surface force and surface morphology of the SAMs using the surface forces apparatus, and optimize the ....Correlation between surface force and morphology of self-assembled monolayer. As a most potential solid support for biological molecules without denaturing their functions, gold thiol self-assembled monolayers (SAMs) have been studied extensively for surface fabrication. In this project we will prepare functional monolayers using newly synthesized thiol derivatives, evaluate correlation between surface force and surface morphology of the SAMs using the surface forces apparatus, and optimize the condition to fabricate biological devices such as immune sensors.Read moreRead less