A new molecular platform for catalytic synthesis of heterocycles. This project aims to address the lack of efficient methods to prepare cyclic molecules of biological relevance by utilising novel molecular platforms developed in our laboratories. This project expects to generate new cyclic molecules using these innovative molecular platforms by employing catalysts to reduce raw material and energy cost. The expected outcomes of this project include enhanced chemical technology to prepare cyclic ....A new molecular platform for catalytic synthesis of heterocycles. This project aims to address the lack of efficient methods to prepare cyclic molecules of biological relevance by utilising novel molecular platforms developed in our laboratories. This project expects to generate new cyclic molecules using these innovative molecular platforms by employing catalysts to reduce raw material and energy cost. The expected outcomes of this project include enhanced chemical technology to prepare cyclic molecules of pharmaceutical importance and the training of highly skilled PhD students. This should provide significant benefits, such as increased capacity for the development of new pharmaceuticals and advanced materials.Read moreRead less
New Discoveries in Organic Synthesis Inspired by the Efficiency of Nature. Nature can assemble complex organic molecules from simple starting materials with apparent ease, but the laboratory synthesis of these natural products is very difficult. This project aims to mimic the way in which Nature constructs organic compounds and thus develop more efficient, greener synthetic processes in which there is a rapid build up of molecular complexity via “biomimetic” reactions. We will integrate this app ....New Discoveries in Organic Synthesis Inspired by the Efficiency of Nature. Nature can assemble complex organic molecules from simple starting materials with apparent ease, but the laboratory synthesis of these natural products is very difficult. This project aims to mimic the way in which Nature constructs organic compounds and thus develop more efficient, greener synthetic processes in which there is a rapid build up of molecular complexity via “biomimetic” reactions. We will integrate this approach with modern methods of catalysis, including electrochemistry, photochemistry and biocatalysis. As a result, this work will expand the chemical space available to synthetic chemists working in the pharmaceutical industry. A further benefit is the training of the next generation of Australian synthetic chemists. Read moreRead less
Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipi ....Precision-engineered hybrid core-shell materials . This project aims to develop new platform technologies for making nanostructured hybrid core-shell materials with exceptionally high drug loading and programmed release. Building on this research team's recent breakthrough in the precision engineering of core-shell materials, this research will revolutionise current approaches for making drug-loaded polymer and inorganic particles. Significant outcomes will include a novel sequential nanoprecipitation platform technology for making drug-core polymer-shell nanoparticles, and a new bio-inspired approach for making hybrid drug-core silica-shell nanocomposites, and new materials for applications in programmed release and delivery systems.Read moreRead less
New Horizons in Quinonedimethide Chemistry. Quinonedimethides (QDMs) are organic molecules with a notorious reputation for instability, hence they are poorly understood and an underexploited resource. This project will unite the ideally suited computational and experimental skills of the CIs to perform the first thorough investigation into fundamental QDM chemistry. It aims to map structure-reactivity in QDMs, investigate their ability to rapidly generate complex structures, and demonstrate thei ....New Horizons in Quinonedimethide Chemistry. Quinonedimethides (QDMs) are organic molecules with a notorious reputation for instability, hence they are poorly understood and an underexploited resource. This project will unite the ideally suited computational and experimental skills of the CIs to perform the first thorough investigation into fundamental QDM chemistry. It aims to map structure-reactivity in QDMs, investigate their ability to rapidly generate complex structures, and demonstrate their potential in spintronics and other applications. Anticipated outcomes include powerful and general new synthetic concepts, methods, strategies and tactics. This should provide significant benefits, such as better ways to manufacture important medicines and other materials.Read moreRead less
Correlative Imaging of Brain Lipids. This project aims to develop imaging tools and protocols for the detection of lipids in brain tissue and cells. This project expects to generate advanced methodologies to display specific lipid classes and their corresponding structures within tissues and cells, with the ability to be detected and correlated with multiple techniques, which represent a currently unavailable capacity. The expected outcomes of this project are improved opportunities to study lip ....Correlative Imaging of Brain Lipids. This project aims to develop imaging tools and protocols for the detection of lipids in brain tissue and cells. This project expects to generate advanced methodologies to display specific lipid classes and their corresponding structures within tissues and cells, with the ability to be detected and correlated with multiple techniques, which represent a currently unavailable capacity. The expected outcomes of this project are improved opportunities to study lipid biology at the cellular and sub-cellular level across a wide range of in vitro and in vivo models. The outcomes of this project should provide significant knowledge to tackle modern societal challenges in healthy ageing, brain pathologies and neurodegenerative diseases.Read moreRead less
Switchable and stereocontrolled photoredox catalysis. This project aims to develop new catalytic synthetic reactions for the rapid and more direct functionalisation of organic compounds under mild conditions with the use of visible light. An integrated experimental and computational approach will be used to design potent visible-light photocatalysts that retain the advantages of standard photoredox catalysis but with the added ability to intercept and, thus control, reactive intermediates in sit ....Switchable and stereocontrolled photoredox catalysis. This project aims to develop new catalytic synthetic reactions for the rapid and more direct functionalisation of organic compounds under mild conditions with the use of visible light. An integrated experimental and computational approach will be used to design potent visible-light photocatalysts that retain the advantages of standard photoredox catalysis but with the added ability to intercept and, thus control, reactive intermediates in situ. This will enable the control of stereochemistry in photoredox reactions – not possible with standard catalysts - and establish other useful synthetic transformations. These strategies will make it easier to prepare valuable classes of organic molecules – efficiently, safely, and cost-effectively.
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Site-specific protein functionalisation at diselenides via photocatalysis . This project aims to develop a new photocatalytic reaction for the on demand functionalisation of proteins. The synthetic methodology will solve a major technological gap in the field by enabling efficient access to proteins with defined modifications at specific locations. Functionalised proteins generated in the project will underpin a detailed understanding of how specific modifications influence the structure and fun ....Site-specific protein functionalisation at diselenides via photocatalysis . This project aims to develop a new photocatalytic reaction for the on demand functionalisation of proteins. The synthetic methodology will solve a major technological gap in the field by enabling efficient access to proteins with defined modifications at specific locations. Functionalised proteins generated in the project will underpin a detailed understanding of how specific modifications influence the structure and function of several important proteins. The project will generate significant new knowledge in the fields of chemistry and biology and will foster interdisciplinary collaboration, nationally and internationally. The breakthrough technology also has the potential to benefit Australia’s biotechnology sector.Read moreRead less
Multi-energy driven photothermal evaporators for all-weather desalination. This project aims to develop advanced Interfacial solar evaporation (ISE) technology to stably deliver clean water. This project expects to facilitate desalination practices by generating new ISE systems that use multiple energy sources from the environment and can operate under different weather conditions. Expected outcomes of this project include new knowledge in the area of renewable energy, improved ISE technique and ....Multi-energy driven photothermal evaporators for all-weather desalination. This project aims to develop advanced Interfacial solar evaporation (ISE) technology to stably deliver clean water. This project expects to facilitate desalination practices by generating new ISE systems that use multiple energy sources from the environment and can operate under different weather conditions. Expected outcomes of this project include new knowledge in the area of renewable energy, improved ISE technique and enhanced capacity for desalination and industrial wastewater treatment. This should provide significant benefits to remote communities who suffer from severe freshwater shortages and enhance research capabilities to position Australia as a global leader in developing green and affordable desalination technologies.Read moreRead less
Unusual trisulfide chemistry. This project aims to investigate the mechanism of an unexpected reaction of trisulfides with common amide-containing solvents. Specifically, these solvents (such as dimethylformamide) were discovered to cleave S-S bonds in trisulfides and related polysulfides. This project expects to generate new knowledge in the understanding of the reaction mechanism and then use that understanding for useful chemistry. Expected outcomes of this project include a mechanistic under ....Unusual trisulfide chemistry. This project aims to investigate the mechanism of an unexpected reaction of trisulfides with common amide-containing solvents. Specifically, these solvents (such as dimethylformamide) were discovered to cleave S-S bonds in trisulfides and related polysulfides. This project expects to generate new knowledge in the understanding of the reaction mechanism and then use that understanding for useful chemistry. Expected outcomes of this project include a mechanistic understanding of a new reaction, and the use of this chemistry in polymer synthesis and polymer recycling. This project should provide significant benefits in new knowledge, as well as support new strategies in polymer synthesis and recycling to benefit the environment.Read moreRead less
Mycobacterial Cholesterol Degradation: A Unique Metabolic Weakness? This project aims to understand the use of the steroid cholesterol as a source of essential metabolic building blocks by bacteria. Cholesterol utilisation is a key feature of many bacterial pathogens which have evolved to survive in niche environments. By understanding the initial step in cholesterol degradation and the bioinorganic and bioorganic chemistry of the metalloenzymes that catalyse it, this work aims to develop strate ....Mycobacterial Cholesterol Degradation: A Unique Metabolic Weakness? This project aims to understand the use of the steroid cholesterol as a source of essential metabolic building blocks by bacteria. Cholesterol utilisation is a key feature of many bacterial pathogens which have evolved to survive in niche environments. By understanding the initial step in cholesterol degradation and the bioinorganic and bioorganic chemistry of the metalloenzymes that catalyse it, this work aims to develop strategies to block this activity. This will turn a key strength of these bacteria into a potent weakness and will generate the proof of principle and knowledge required for the future development of effective strategies to combat pathogenic bacteria.Read moreRead less