Microfluidic Separation Science: Innovative Technology for Characterising Complex Chemical Systems. At present there is a need for fast and detailed chemical analysis of complex samples, such as those important to biomedical diagnostics and forensic science. Innovative technology will be developed here in order to reduce analysis time whilst maintaining the integrity of the chemical information contained within the sample. This step change in separation science will directly aid biomedical diagn ....Microfluidic Separation Science: Innovative Technology for Characterising Complex Chemical Systems. At present there is a need for fast and detailed chemical analysis of complex samples, such as those important to biomedical diagnostics and forensic science. Innovative technology will be developed here in order to reduce analysis time whilst maintaining the integrity of the chemical information contained within the sample. This step change in separation science will directly aid biomedical diagnostics, forensic sample determination and industrial process monitoring through decreased analysis time with an increase in the chemical information gained. By performing chemical separations on a microfluidic scale a reduction in both the cost of analysis and impact of solvent waste on the environment will be achieved.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100467
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Unravelling the intrinsic structure and stability of multiply charged anions in the gas-phase using photoelectron spectroscopy and mass spectrometry. Molecules possessing multiple negative charges are common constituents in chemistry, influencing a range of processes ranging from photochemical smog formation to protein structure in vivo. This project will develop new technologies to probe their molecular structure in the gas-phase, leading to a more rigorous understanding of these species.
Development of ozone-induced dissociation for lipidomics workflows. An Australian invention (ozone induced dissociation) will be developed in collaboration with a major instrument manufacturer. This project will provide Australian researchers with unique capabilities to investigate the role of lipids (fats) in human disease and will place them at the forefront of lipid research internationally.
New laser and mass spectrometry-based tools for comprehensive structural elucidation of lipids and their biomolecular interactions. Lipid-related disorders such as obesity, diabetes and heart disease are reaching epidemic proportions. We propose the development of specialised instrumentation to identify and quantify lipids (fats) in tissue and culture samples thus providing Australian scientists with unique capabilities to investigate the mechanisms of disease.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100059
Funder
Australian Research Council
Funding Amount
$220,000.00
Summary
Multiplexed capabilities for surface analysis and imaging by mass spectrometry. This facility will support research aimed at developing rapid and reliable analytical methods for the detection of chemicals directly from biological and man-made materials. The mass spectroscopy methods used at the facility will reveal molecular-level changes in systems ranging from the lens of the human eye to Colorbond steel® and have applications in the detection of chemical and biological hazards.
The photons take charge: Elucidating the structure and stability of distonic radical anions by mass spectrometry and photoelectron spectroscopy. Recent work has discovered that certain radical anions have electronic configurations that defy chemical convention and exhibit exceptional radical stability. Exploitation of this breakthrough first requires experimental elucidation of the intrinsic electronic structure of these compounds and how it relates to their remarkable properties. This project w ....The photons take charge: Elucidating the structure and stability of distonic radical anions by mass spectrometry and photoelectron spectroscopy. Recent work has discovered that certain radical anions have electronic configurations that defy chemical convention and exhibit exceptional radical stability. Exploitation of this breakthrough first requires experimental elucidation of the intrinsic electronic structure of these compounds and how it relates to their remarkable properties. This project will probe the fundamental structure and energetics of radical anions by modifying instrumentation to enable multi-step gas-phase ion synthesis to be efficiently coupled with anion photoelectron spectroscopy. These investigations are essential to revealing the scope of this phenomenon in free radical chemistry and biology and could inform future development of new catalysts for polymerisation.Read moreRead less
Iron, ferroptosis and the biology of ageing. This project aims to determine how and when regulation of iron is lost. Failing iron metabolism during life may dictate the rate of ageing by driving a newly discovered cell death program. Combining biology, chemistry and physics, this collaborative project aims to transform the understanding of the fundamental mechanisms of biological ageing. Anticipated outcomes include new assays for measuring iron in biology and identification of potential pathway ....Iron, ferroptosis and the biology of ageing. This project aims to determine how and when regulation of iron is lost. Failing iron metabolism during life may dictate the rate of ageing by driving a newly discovered cell death program. Combining biology, chemistry and physics, this collaborative project aims to transform the understanding of the fundamental mechanisms of biological ageing. Anticipated outcomes include new assays for measuring iron in biology and identification of potential pathways that regulate death signaling and lifespan. Outcomes will benefit life sciences and biotechnology industries.Read moreRead less
ARC Centre of Excellence for Nanoscale BioPhotonics. The CNBP brings together physicists, chemists and biologists focused on a grand challenge controlling nanoscale interactions between light and matter to probe the complex and dynamic nanoenvironments within living organisms. The emerging convergence of nanoscience and photonics offers the opportunity of using light to interrogate nanoscale domains, providing unprecedentedly localised measurements. This will allow biological scientists to unde ....ARC Centre of Excellence for Nanoscale BioPhotonics. The CNBP brings together physicists, chemists and biologists focused on a grand challenge controlling nanoscale interactions between light and matter to probe the complex and dynamic nanoenvironments within living organisms. The emerging convergence of nanoscience and photonics offers the opportunity of using light to interrogate nanoscale domains, providing unprecedentedly localised measurements. This will allow biological scientists to understand how single cells react to and communicate with their surroundings. This science will underpin a new generation of devices capable of probing the response of cells within individuals to environmental conditions or treatment, creating innovative and powerful new sensing platforms.Read moreRead less
ARC Centre of Excellence in Advanced Molecular Imaging. The Centre of Excellence in Advanced Molecular Imaging will innovatively integrate physics, chemistry and biology to unravel the complex molecular interactions that define immunity. The Centre will develop new imaging methods to visualize atomic, molecular and cellular details of how immune proteins interact and
effect immune responses. Outcomes: (i) new technological innovations leading to new imaging methods and products; and (ii) fundame ....ARC Centre of Excellence in Advanced Molecular Imaging. The Centre of Excellence in Advanced Molecular Imaging will innovatively integrate physics, chemistry and biology to unravel the complex molecular interactions that define immunity. The Centre will develop new imaging methods to visualize atomic, molecular and cellular details of how immune proteins interact and
effect immune responses. Outcomes: (i) new technological innovations leading to new imaging methods and products; and (ii) fundamental advances in understanding details of immune responses in health and disease. The Centre will enable Australia to be an international leader in biological imaging, to train next
generation interdisciplinary scientists, and to provide new insights for combating common diseases that afflict society.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100179
Funder
Australian Research Council
Funding Amount
$3,189,000.00
Summary
Automated high resolution and high contrast cryo -TEM for three-dimensional structural biology. This project aims to establish a facility in automated, single-particle cryo-TEM and cryo-TEM tomography (Titan Krios) that will enable atomic and molecular structure research and three-dimensional subcellular and cellular imaging. The project will span all multiscale cryo-TEM modalities from the visualisation of cells, membranes and macromolecular complexes, through to near-atomic-resolution protein ....Automated high resolution and high contrast cryo -TEM for three-dimensional structural biology. This project aims to establish a facility in automated, single-particle cryo-TEM and cryo-TEM tomography (Titan Krios) that will enable atomic and molecular structure research and three-dimensional subcellular and cellular imaging. The project will span all multiscale cryo-TEM modalities from the visualisation of cells, membranes and macromolecular complexes, through to near-atomic-resolution protein structure determination. Cryo-single particle analysis and tomography are recognised as revolutionary technologies in molecular structural biology and powerful enablers of future ground-breaking discovery. The project will deliver significant competitive advantage for Australia in leading-edge structure-based research, drug discovery, new opportunities for applied research and development, and showcasing science to the public.Read moreRead less