Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453743
Funder
Australian Research Council
Funding Amount
$237,654.00
Summary
Advanced Materials Laser Characterisation Facility. A networked laser facility spanning the University of Melbourne, Monash University, the University of Adelaide, and Flinders University, will be created by integrating new laser instrumentation with existing specialised infrastructure. The facility will provide chemists at the four institutions with the necessary equipment to collaboratively investigate and optimise the properties of a diverse array of advanced materials, including nanoparticle ....Advanced Materials Laser Characterisation Facility. A networked laser facility spanning the University of Melbourne, Monash University, the University of Adelaide, and Flinders University, will be created by integrating new laser instrumentation with existing specialised infrastructure. The facility will provide chemists at the four institutions with the necessary equipment to collaboratively investigate and optimise the properties of a diverse array of advanced materials, including nanoparticles, polymers, biomaterials, and artificial photosynthetic systems. The outcome will be a world-class research network, outfitted with a suite of sophisticated techniques that are not currently available at any single university, or through any other Australian institution or consortium.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
Energetics and dynamics of solvated biologically relevant molecules using liquid microjet and ion imaging technologies. The shape of many biomolecules in solution plays a critical role in determining their biological activity and function. It is known that the bonds that form between the biomolecules and the water solvent control this shape. However, very little is known about the strength and structure of these bonds at different sites around the biomolecule. Many experiments have informed u ....Energetics and dynamics of solvated biologically relevant molecules using liquid microjet and ion imaging technologies. The shape of many biomolecules in solution plays a critical role in determining their biological activity and function. It is known that the bonds that form between the biomolecules and the water solvent control this shape. However, very little is known about the strength and structure of these bonds at different sites around the biomolecule. Many experiments have informed us about the strength of the bonds, others have told us where the bonds occur. This project will provide both pieces of information for the first time, allowing us to better understand, and therefore control, biological function. This work will assist in the development of new biotechnology processes, especially in the emerging area of proteomics.Read moreRead less
Laser Spectroscopic Studies of Non-Covalent Solute-Solvent Interactions Involving Non-Volatile Biomolecules in the Gas Phase. Solute-solvent interactions play a critical role in determining whether or not many biomolecules display biological activity in solution. Making use of our novel liquid microjet injection technology, we will generate micro-solvated gas phase biomolecules by rapid laser desorption from the surface of a liquid jet (here, micro-solvation describes up to ~10 solvent molecule ....Laser Spectroscopic Studies of Non-Covalent Solute-Solvent Interactions Involving Non-Volatile Biomolecules in the Gas Phase. Solute-solvent interactions play a critical role in determining whether or not many biomolecules display biological activity in solution. Making use of our novel liquid microjet injection technology, we will generate micro-solvated gas phase biomolecules by rapid laser desorption from the surface of a liquid jet (here, micro-solvation describes up to ~10 solvent molecules attached to a solute). Following desorption, laser spectroscopy will be used to directly characterise the non-volatile biomolecular solute-solvent topography. This project will create a new application of laser science to study biophysical and biochemical processes that remain difficult, if not impossible, to explore using traditional techniques.Read moreRead less
Negative ion mass spectrometry: fundamentals and applied applications. 1. We seek to establish negative ion mass spectrometry as a major technological tool for the sequencing of peptides and proteins. In this context, we will investigate the structures and modes of action of peptide complexes which may be of importance for the treatment and control of heart disease and stroke.
2. Negative ions of known structure will be converted (in the mass spectrometer) into transient (and reactive) molecule ....Negative ion mass spectrometry: fundamentals and applied applications. 1. We seek to establish negative ion mass spectrometry as a major technological tool for the sequencing of peptides and proteins. In this context, we will investigate the structures and modes of action of peptide complexes which may be of importance for the treatment and control of heart disease and stroke.
2. Negative ions of known structure will be converted (in the mass spectrometer) into transient (and reactive) molecules which are present in interstellar ice and dust clouds. The structures and chemistry of such molecules are of importance in understanding the origins of life on this planet.Read moreRead less
The formation of negative ions and neutrals in the gas phase. Structure, reactivity and mechanism. Mass spectrometry is an analytical technique used to provide information concerning the structure of a chemical compound: it is particularly useful when dealing with small amounts of biologically important molecules. It is also a facility in which charged species can be converted into transient neutrals. This project will (i) produce information about negative ion fragmentations in order to extend ....The formation of negative ions and neutrals in the gas phase. Structure, reactivity and mechanism. Mass spectrometry is an analytical technique used to provide information concerning the structure of a chemical compound: it is particularly useful when dealing with small amounts of biologically important molecules. It is also a facility in which charged species can be converted into transient neutrals. This project will (i) produce information about negative ion fragmentations in order to extend the applicability of analytical negative-ion mass spectrometry, (ii) form neutral molecules and related species which are found in stellar dust clouds and investigate their chemistry, and (iii) train graduates in ion chemistry to the highest international standards.Read moreRead less
Cumulenes and Heterocumulenes - Stellar Molecules and New Materials. This project involves the formation and characterisation of transient neutrals (formed in the mass spectrometer by neutralisation of charged precursor ions) which are either found in stellar dust clouds, or related molecules which may be either potential stellar molecules or have importance in the development of new materials. This work may lead to a better understanding of how biomolecules are formed in interstellar environs. ....Cumulenes and Heterocumulenes - Stellar Molecules and New Materials. This project involves the formation and characterisation of transient neutrals (formed in the mass spectrometer by neutralisation of charged precursor ions) which are either found in stellar dust clouds, or related molecules which may be either potential stellar molecules or have importance in the development of new materials. This work may lead to a better understanding of how biomolecules are formed in interstellar environs. The Adelaide and Berlin groups are internationally known, already with ongoing collaboration. This application seeks to extend the scope of this world-class research, and to train the premier graduate students in astrochemistry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989747
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Ultrafast Dynamics Measurement Facility for the Physical, Biochemical, and Materials Sciences. The term "ultrafast revolution" describes the transformations in science due to ultrafast laser technology. Today, ultrafast lasers are used in surgery, nanomaterial fabrication, biomedical imaging, spectroscopic investigations, and new applications are still emerging. This facility will draw together leading chemists, physicists, and engineers to investigate key ultrafast processes and phenomena in th ....Ultrafast Dynamics Measurement Facility for the Physical, Biochemical, and Materials Sciences. The term "ultrafast revolution" describes the transformations in science due to ultrafast laser technology. Today, ultrafast lasers are used in surgery, nanomaterial fabrication, biomedical imaging, spectroscopic investigations, and new applications are still emerging. This facility will draw together leading chemists, physicists, and engineers to investigate key ultrafast processes and phenomena in the physical, biochemical and material sciences. This is of strategic importance to keep Australia at the global forefront for scientific endeavours, supporting new research and commercial opportunities. This facility will also produce highly trained graduates, who will find employment in industry throughout Australia and globally.Read moreRead less
Negative ion mass spectrometry: fundamental studies and applied applications. We seek to:
(i) establish negative ion mass spectrometry as an analytical tool for the sequencing of proteins and to probe the structures of active peptide Ca2+ calmodulin complexes which, for example, inhibit the formation of NO from nitric oxide synthases. Controlling the concentration of nitric oxide may assist with the treatment of inflammatory and cardiac diseases, stroke and diseases of the central nervous syst ....Negative ion mass spectrometry: fundamental studies and applied applications. We seek to:
(i) establish negative ion mass spectrometry as an analytical tool for the sequencing of proteins and to probe the structures of active peptide Ca2+ calmodulin complexes which, for example, inhibit the formation of NO from nitric oxide synthases. Controlling the concentration of nitric oxide may assist with the treatment of inflammatory and cardiac diseases, stroke and diseases of the central nervous system.
(ii) to study the possibility of the formation of biological molecules of life in interstellar regions
(iii) to train graduate students to international standards in the chemistry of proteomics.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560658
Funder
Australian Research Council
Funding Amount
$481,533.00
Summary
Shared Laser Facility. The Australian Shared Laser Facility (ASLF) has been providing lasers for physical chemistry research for a decade. ASLF lasers are portable and are transported between participating laboratories according to need and research priorities. Funds are sought to expand the ASLF by 3 laser systems and 2 research groups. The requested lasers provide mid-IR and deep UV wavelengths, spectral regions inaccessible with existing ASLF lasers. Access to these wavelengths is essenti ....Shared Laser Facility. The Australian Shared Laser Facility (ASLF) has been providing lasers for physical chemistry research for a decade. ASLF lasers are portable and are transported between participating laboratories according to need and research priorities. Funds are sought to expand the ASLF by 3 laser systems and 2 research groups. The requested lasers provide mid-IR and deep UV wavelengths, spectral regions inaccessible with existing ASLF lasers. Access to these wavelengths is essential for Australian research to remain at the forefront of international physical chemistry research. ASLF laboratories support a wide range of chemical research including spectroscopy, environmental chemistry, astrochemistry, and exploration of nanostructured materials.Read moreRead less