Understanding biological nitrogen fixation: an investigation of multi-electron reduction catalysis at novel iron-sulfur clusters. A new class of iron-sulfur clusters held together by a central light atom will be prepared and their reactions thoroughly studied. These clusters are important because they will have the same structure as the iron-molybdenum cluster of the enzyme nitrogenase. This enzyme fixes atmospheric nitrogen as ammonia. It is the primary route of nitrogen entry into all living s ....Understanding biological nitrogen fixation: an investigation of multi-electron reduction catalysis at novel iron-sulfur clusters. A new class of iron-sulfur clusters held together by a central light atom will be prepared and their reactions thoroughly studied. These clusters are important because they will have the same structure as the iron-molybdenum cluster of the enzyme nitrogenase. This enzyme fixes atmospheric nitrogen as ammonia. It is the primary route of nitrogen entry into all living systems. Industrially ammonia is produced in an energy-demanding process on a vast scale. The studies will provide insights into how nitrogenase works and how to design new multi-electron reduction catalysts. The research may lead to new energy-efficient routes to ammonia and to other new alternative fuel sources. Such processes would transform Australian industry and how we live.Read moreRead less
DNA Nanoshuttles: A New Class of DNA-Binding Molecules. The interaction of molecules with DNA, the molecule that controls genetic information, is fundamental to drug design, diagnosis of disease and the environment. DNA-nanoshuttles are ring-shaped molecules that thread onto DNA and shuttle from one end to the other. This threading interaction is without precedent and hence DNA-nanoshuttles have significant potential applications in all areas of medicine, biotechnology and nanotechnology that in ....DNA Nanoshuttles: A New Class of DNA-Binding Molecules. The interaction of molecules with DNA, the molecule that controls genetic information, is fundamental to drug design, diagnosis of disease and the environment. DNA-nanoshuttles are ring-shaped molecules that thread onto DNA and shuttle from one end to the other. This threading interaction is without precedent and hence DNA-nanoshuttles have significant potential applications in all areas of medicine, biotechnology and nanotechnology that involve DNA interactions. This research may lead to the design of new diagnostics and applications that will benefit the Australian community, and will provide excellent training of researchers in skills required for employment in the biotechnology and pharmaceutical fields.Read moreRead less
New photoinitiators and polymers for tack-free LED cured surface coatings. This project aims to develop surface coatings curable by energy from Light Emitting Diodes (LEDS) by overcoming existing hurdles, while improving workplace health and safety.
The project expects to achieve this by developing a new class of photoinitiator molecules, with enhanced reactivity, via a unique understanding of synthesis, photochemistry and commercial coatings formulation.
Outcomes will be new surface coatings ....New photoinitiators and polymers for tack-free LED cured surface coatings. This project aims to develop surface coatings curable by energy from Light Emitting Diodes (LEDS) by overcoming existing hurdles, while improving workplace health and safety.
The project expects to achieve this by developing a new class of photoinitiator molecules, with enhanced reactivity, via a unique understanding of synthesis, photochemistry and commercial coatings formulation.
Outcomes will be new surface coatings for a wide range of end uses, publication in high ranking journals and commercialisation of the technology.
Benefits of this project will include elimination of mercury and reduction in exposure to solvents in the Australian workplace, and a lower energy requirement to produce high-quality surface coated products.Read moreRead less
Dinuclear Ruthenium Complexes as Sequence- and Structure-Selective Binding Agents for DNA. Studies of the interaction of mononuclear metal complexes with DNA have greatly increased our understanding of the ways that small molecules recognise particular sites on DNA. However, in order to design drugs that target specific genes, and hence be potentially capable of controlling gene expression, it is necessary to study the binding of metal complexes that can associate with larger segments of DNA. ....Dinuclear Ruthenium Complexes as Sequence- and Structure-Selective Binding Agents for DNA. Studies of the interaction of mononuclear metal complexes with DNA have greatly increased our understanding of the ways that small molecules recognise particular sites on DNA. However, in order to design drugs that target specific genes, and hence be potentially capable of controlling gene expression, it is necessary to study the binding of metal complexes that can associate with larger segments of DNA. Using the combined expertise of the applicants, it is proposed to stereospecifically synthesise dinuclear complexes and study their DNA binding. This will greatly assist in the development of drugs that can selectively target genes and altered DNA.Read moreRead less
Mechanistic Studies on Biologically Active Iron Chelators. The need for orally effective drugs as alternatives to invasive treatment regimens such as subcutaneous infusion is an ongoing concern in health care. This is particularly true in people suffering iron overload. In many cases this condition is present at birth and thus the administration of vital iron chelation therapy via the oral route is a much preferred option. We have unearthed a novel series of candidates for iron chelation therapy ....Mechanistic Studies on Biologically Active Iron Chelators. The need for orally effective drugs as alternatives to invasive treatment regimens such as subcutaneous infusion is an ongoing concern in health care. This is particularly true in people suffering iron overload. In many cases this condition is present at birth and thus the administration of vital iron chelation therapy via the oral route is a much preferred option. We have unearthed a novel series of candidates for iron chelation therapy (the pyridine-2-carboxaldehyde isonicotinoyl hydrazone [PCIH] analogues) which show oral activity. These chelators undergo some interesting iron catalysed oxidation chemistry and it is vital that the mechanism of this reaction be elucidated to determine whether it will be of biological significance upon administration of these compounds as iron chelators.Read moreRead less
Cation Ordering - A Strategy to Prepare Multiferroic Oxides. This project will produce new families of functional metal oxides with technologically relevant properties, especially multiferroic behavior. Such materials are highly sort-after in the rapidly emerging field of spintronics. Through comprehensive experimental studies of a number of such materials this project will enhance the ability of industry to develop new and improved materials.
Development of metal probes for the selective recognition of DNA. Transition metal complexes with large aromatic ligands have recently been shown to bind DNA by intercalation. However, controversy continues over their base sequence and groove selectivity. We will synthesise a range of chiral metal complexes and screen these against combinatorial oligonucleotide libraries to determine their base sequence selectivity. The information obtained will help us design better intercalators that can be us ....Development of metal probes for the selective recognition of DNA. Transition metal complexes with large aromatic ligands have recently been shown to bind DNA by intercalation. However, controversy continues over their base sequence and groove selectivity. We will synthesise a range of chiral metal complexes and screen these against combinatorial oligonucleotide libraries to determine their base sequence selectivity. The information obtained will help us design better intercalators that can be used as sensitive molecular probes and may find application as antitumour drugs. Binding interaction between the complex and DNA will be studied by NMR spectroscopy.Read moreRead less
Control of the Enantiomeric Self-Resolution Process. The availability of enantiopure molecules is crucial in chemistry and medicine. Enantiomeric self-resolution on crystallisation provides pure left- and right-handed molecules from 1:1 mixtures of the two. It is the simplest and cheapest means of obtaining enantiopure molecules, but its occurrence in any given case cannot normally be
predicted. The understanding and control of the self-resolution process gained through this project will repre ....Control of the Enantiomeric Self-Resolution Process. The availability of enantiopure molecules is crucial in chemistry and medicine. Enantiomeric self-resolution on crystallisation provides pure left- and right-handed molecules from 1:1 mixtures of the two. It is the simplest and cheapest means of obtaining enantiopure molecules, but its occurrence in any given case cannot normally be
predicted. The understanding and control of the self-resolution process gained through this project will represent a major breakthrough in organic and pharmaceutical chemistry. This technological advance will make pure handed molecules available readily and cheaply, thereby allowing chemical, pharmaceutical and biological developments to be made by Australian industry.
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