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Molecular analysis of glutathione transferase interactions with drugs and physiological ligands. Proteins called glutathione transferases protect us from toxic molecules that we ingest, breathe in or are by-products of normal metabolism. The same proteins also bind to many types of drugs leading them to be excreted from the body. In this project molecular structures of glutathione transferases bound to anti-cancer drugs will be determined as the basis for devising inhibitors of the protein that ....Molecular analysis of glutathione transferase interactions with drugs and physiological ligands. Proteins called glutathione transferases protect us from toxic molecules that we ingest, breathe in or are by-products of normal metabolism. The same proteins also bind to many types of drugs leading them to be excreted from the body. In this project molecular structures of glutathione transferases bound to anti-cancer drugs will be determined as the basis for devising inhibitors of the protein that will make drugs much more effective.Read moreRead less
Structural studies of glutathione transferases: a model system for functional genomics and drug design. Glutathione S-transferases (GSTs) are a large family of multi-functional proteins that play a vital role in an organism's defence against toxic chemicals. However, they also attack a variety of drugs and hence are a prime target for the development of isoform-specific inhibitors. We will determine the 3D atomic structures of GSTs in complex with a range of substrates and inhibitors as a basis ....Structural studies of glutathione transferases: a model system for functional genomics and drug design. Glutathione S-transferases (GSTs) are a large family of multi-functional proteins that play a vital role in an organism's defence against toxic chemicals. However, they also attack a variety of drugs and hence are a prime target for the development of isoform-specific inhibitors. We will determine the 3D atomic structures of GSTs in complex with a range of substrates and inhibitors as a basis for the design of compounds to improve the efficacy of anti-cancer and other drugs. This is an ambitious, wide-ranging project involving collaborators around the world. We expect the results will not only greatly increase our knowledge of an important enzyme family, but will also have applications in protein folding, catalysis, protein engineering, evolution, drug design and functional genomics. Read moreRead less
TiO2 nanoparticle design and photocatalysis applications. The aim is to design nanosized TiO2 photocatalsysts with superior photoactivity using various synthesis paths. Nanosized TiO2 particles will be prepared using sol-gel, aerosol and plasma processing, their physical and chemical properties will be closely studied and their photocatalytic ability will be assessed. Such tailor-made photocatalysts have significant commercial potential value, as they would be highly suitable for the photooxidat ....TiO2 nanoparticle design and photocatalysis applications. The aim is to design nanosized TiO2 photocatalsysts with superior photoactivity using various synthesis paths. Nanosized TiO2 particles will be prepared using sol-gel, aerosol and plasma processing, their physical and chemical properties will be closely studied and their photocatalytic ability will be assessed. Such tailor-made photocatalysts have significant commercial potential value, as they would be highly suitable for the photooxidation of organic compounds and the photoreduction of metal ions in wastewaters. Findings from this work will pave the way for a "green" technology such as photocatalysis to become more efficient and hence a competitive alternative to conventional water treatment methods.Read moreRead less
Supramolecular Assemblies as Nanoscale Devices to Control Chemical and Physical Processes. The aims of this project are: i) to develop molecular reaction vessels to enhance the rates and control the outcomes of chemical processes; ii) to design and construct supramolecular species with a range of topologies; and iii) to explore the potential use of these supramolecular assemblies as thermal and photochemical switches and molecular tweezers, and as the basis for molecular machines and microelectr ....Supramolecular Assemblies as Nanoscale Devices to Control Chemical and Physical Processes. The aims of this project are: i) to develop molecular reaction vessels to enhance the rates and control the outcomes of chemical processes; ii) to design and construct supramolecular species with a range of topologies; and iii) to explore the potential use of these supramolecular assemblies as thermal and photochemical switches and molecular tweezers, and as the basis for molecular machines and microelectronic devices. The research is expected to provide new and efficient methods for bench-top and industrial scale synthesis of chemicals in water, as well as fundamental advances in nanotechnology to underpin new industries based on advanced materials.Read moreRead less
Synthesis and Production of High Value Pyridines Combining the Concepts of Alternative Reaction Media and Process Intensification. This project aims to develop novel syntheses and process route for substituted pyridines by bringing together expertise in the fields of green chemistry and process intensification. Minimisation of waste, energy efficiency, and improved selectivity and control will be the key process and chemistry targets, which will produce high value compounds. Traditional approach ....Synthesis and Production of High Value Pyridines Combining the Concepts of Alternative Reaction Media and Process Intensification. This project aims to develop novel syntheses and process route for substituted pyridines by bringing together expertise in the fields of green chemistry and process intensification. Minimisation of waste, energy efficiency, and improved selectivity and control will be the key process and chemistry targets, which will produce high value compounds. Traditional approaches use organic solvents and preformed salts which are costly, generate waste and the processes are energy intensive due to poor selectivity, low yield and extensive separation steps. This is a generic investigation which will have wide ranging applications in the pharmaceutical, energy and advanced electronic industries.Read moreRead less
Application of process intensification on rotating surfaces (PIRS) in organic synthesis. Process intensification technologies in the form of SDP and RTP are new to Australia and present many opportunities for carrying out the synthesis of organic compounds. They have remarkable versatility in being able to control chemical reactions with greater selectivity than using classical batch technology, at the same time allowing access to new compounds. Moreover, the technologies embrace the principles ....Application of process intensification on rotating surfaces (PIRS) in organic synthesis. Process intensification technologies in the form of SDP and RTP are new to Australia and present many opportunities for carrying out the synthesis of organic compounds. They have remarkable versatility in being able to control chemical reactions with greater selectivity than using classical batch technology, at the same time allowing access to new compounds. Moreover, the technologies embrace the principles of green chemistry in minimising the generation of waste, while operating under continuous flow which is destined to be more attractive to industry. This is likely in the fine chemicals sector, and in drug discovery. The project will provide first-rate research training and promote Australian science. Read moreRead less
Process for treatment of fluorine-containing synthetic greenhouse gases. It is generally agreed that increasing levels of greenhouse gases in the atmosphere are leading to higher average atmospheric temperatures. This research pursues the development of an energy-efficient, non-destructive process for transforming fluorine-containing greenhouse gases (GHGs) into valuable and environmentally benign products. The application of research will lead to the development of a new non-destructive proce ....Process for treatment of fluorine-containing synthetic greenhouse gases. It is generally agreed that increasing levels of greenhouse gases in the atmosphere are leading to higher average atmospheric temperatures. This research pursues the development of an energy-efficient, non-destructive process for transforming fluorine-containing greenhouse gases (GHGs) into valuable and environmentally benign products. The application of research will lead to the development of a new non-destructive process and will benefit Australia, socially by reducing emission of GHGs and thus protecting the environment, and economically through licensing of the technology for treatment of the growing stockpiles of synthetic GHGs.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882634
Funder
Australian Research Council
Funding Amount
$220,000.00
Summary
Integrated Process Intensification Facility. The new equipment will provide a unique facility for process intensification (PI). No other techniques are capable of controlling features of nano-particles (size, shape, agglomeration, phases and defects) under continuous flow, which is essential for applications in nano-technology. There are unique capabilities of PI in chemical synthesis, including drug development and drug discovery. Overall, applications of PI cover health care products, device t ....Integrated Process Intensification Facility. The new equipment will provide a unique facility for process intensification (PI). No other techniques are capable of controlling features of nano-particles (size, shape, agglomeration, phases and defects) under continuous flow, which is essential for applications in nano-technology. There are unique capabilities of PI in chemical synthesis, including drug development and drug discovery. Overall, applications of PI cover health care products, device technology, and more, for the benefit of the community at large. The facility will foster a more innovative research culture and provide excellent research training at the highest international level, and will provide a platform to foster greater links with industry.Read moreRead less
From Nanostructured Catalysts to Process Innovation. The results of this research will help to advance the fundamental scientific understanding of industrially important chemical reactions and give clear leads as to how to improve them. In particular, new catalysts (i.e. agents that increase the speed and selectivity of chemical reactions) will be generated and the first steps towards process innovation will be taken, using high-throughput equipment unique in the Southern Hemisphere. These new c ....From Nanostructured Catalysts to Process Innovation. The results of this research will help to advance the fundamental scientific understanding of industrially important chemical reactions and give clear leads as to how to improve them. In particular, new catalysts (i.e. agents that increase the speed and selectivity of chemical reactions) will be generated and the first steps towards process innovation will be taken, using high-throughput equipment unique in the Southern Hemisphere. These new catalysts will be the basis for the design of new and/or improved industrial processes that will be ?greener?, safer, use fewer resources, produce less waste and are generally more efficient and effective. As a result the Australian chemicals industry will be more competitive.Read moreRead less
Molecular Recognition in Chiral Ionic Liquids as Basis for the Design and Synthesis of New Enantioselective Heterogeneous Catalysts and Membranes. Molecules that can exist as mirror images, each with different, e.g., beneficial vs. toxic properties, underpin the pharmaceutical industry and increasingly new highly selective pesticides, and flavours/fragrances.
Current commercial pathways often make mixtures of the mirror images that then need to be separated laboriously. These routes are ineffic ....Molecular Recognition in Chiral Ionic Liquids as Basis for the Design and Synthesis of New Enantioselective Heterogeneous Catalysts and Membranes. Molecules that can exist as mirror images, each with different, e.g., beneficial vs. toxic properties, underpin the pharmaceutical industry and increasingly new highly selective pesticides, and flavours/fragrances.
Current commercial pathways often make mixtures of the mirror images that then need to be separated laboriously. These routes are inefficient, creating waste and use resources poorly.
We aim to create solutions for these problems, using supported thin films of special, new types of salts that are liquid at room temperature, and which have other unusual chemical properties that make them ideally suited to enable efficient conversions.Read moreRead less