Domino Approaches to Polycyclic Natural Products. Organic molecules are the basis of all known life forms. The majority of our medicinal agents are organic molecules. Organic molecules are made up of atoms, connected together by bonds. Usually, these molecules are constructed by making one bond at a time. We are trying to make this laborious job quicker and more efficient by forming lots of bonds at once. Research of this kind is the basis for the development of new pharmaceuticals. Australia do ....Domino Approaches to Polycyclic Natural Products. Organic molecules are the basis of all known life forms. The majority of our medicinal agents are organic molecules. Organic molecules are made up of atoms, connected together by bonds. Usually, these molecules are constructed by making one bond at a time. We are trying to make this laborious job quicker and more efficient by forming lots of bonds at once. Research of this kind is the basis for the development of new pharmaceuticals. Australia doesn't have many people who are able to do this kind of thing. We will train four to six people in this area of research.Read moreRead less
New Cascade Routes to Biologically Important Molecules. This research involves the development of short and efficient syntheses of several different classes of biologically active molecules using cascade reactions: spectacular events in which many chemical bonds are formed. Two distinct types of cascade reactions will be investigated and naturally-occurring molecules with antineoplastic, anti-immunosuppressive, antiviral and antimalarial activities will be prepared. These new, expedient routes a ....New Cascade Routes to Biologically Important Molecules. This research involves the development of short and efficient syntheses of several different classes of biologically active molecules using cascade reactions: spectacular events in which many chemical bonds are formed. Two distinct types of cascade reactions will be investigated and naturally-occurring molecules with antineoplastic, anti-immunosuppressive, antiviral and antimalarial activities will be prepared. These new, expedient routes allow the preparation of a wide range of structurally-related analogues; an important prerequisite for the preparation of libraries of compounds for biological evaluation. Along the way, important information about the chemical reactivity patterns of a newly-prepared, fundamental class of hydrocarbon molecules will be obtained.Read moreRead less
New Horizons in Diels-Alder Chemistry. Using a unique joint experimental-computational approach, we will develop reliable ways to predict the outcome of one of the most important chemical reactions. Practical applications of these new predictive tools will be developed involving powerful new versions of the reaction. Several different classes of biologically active natural products will be prepared including molecules with antitumor and antiretroviral activities. Libraries of structurally-relate ....New Horizons in Diels-Alder Chemistry. Using a unique joint experimental-computational approach, we will develop reliable ways to predict the outcome of one of the most important chemical reactions. Practical applications of these new predictive tools will be developed involving powerful new versions of the reaction. Several different classes of biologically active natural products will be prepared including molecules with antitumor and antiretroviral activities. Libraries of structurally-related analogues of natural compounds will be synthesised for biological evaluation.Read moreRead less
Experimental and Computational Investigations into Enantioselective Domino Sequences. This research program aims to develop more efficient methods for the chemical synthesis of organic substances: the materials that make up all known life forms, our medicines, and many designed materials. This research involves primarily the invention of new, enabling science. Specifically, we are trying to develop new and very general strategies to make organic compounds selectively and more efficiently than be ....Experimental and Computational Investigations into Enantioselective Domino Sequences. This research program aims to develop more efficient methods for the chemical synthesis of organic substances: the materials that make up all known life forms, our medicines, and many designed materials. This research involves primarily the invention of new, enabling science. Specifically, we are trying to develop new and very general strategies to make organic compounds selectively and more efficiently than before. A more efficient chemical synthesis means less waste, lower energy consumption and less environmental impact. Research of this kind is absolutely essential for the development of new medicines and materials. Australia lags behind many of the world's developed countries in this very important area of endeavour.Read moreRead less
Experimental-Computational Investigations into Diels-Alder Sequences. Organic molecules are an integral part of our world - in us, around us and, importantly, in our medicines. Chemists design experiments to make specific molecules by mixing the appropriate chemicals. Often, however, the outcome can't be predicted. We are developing ways to accurately predict these outcomes using computer modelling of chemical reactions. This will allow us to better understand reactions and make molecules more e ....Experimental-Computational Investigations into Diels-Alder Sequences. Organic molecules are an integral part of our world - in us, around us and, importantly, in our medicines. Chemists design experiments to make specific molecules by mixing the appropriate chemicals. Often, however, the outcome can't be predicted. We are developing ways to accurately predict these outcomes using computer modelling of chemical reactions. This will allow us to better understand reactions and make molecules more efficiently. Such research is the basis for the development of new pharmaceuticals. Few people in Australia are working in this area and we expect to train four to six people during the course of this project.Read moreRead less
Enhanced Synthetic Efficiency For Molecular Complexity and Diversity. This project aims to introduce new, broad-spectrum strategies that permit more efficient and selective ways to access complex organic molecules. The approach involves maximising the molecule-building potential of some of the smallest accessible molecular building blocks. Significant outcomes expected from this work include much shorter chemical syntheses of important organic substances and much improved, broad scope synthetic ....Enhanced Synthetic Efficiency For Molecular Complexity and Diversity. This project aims to introduce new, broad-spectrum strategies that permit more efficient and selective ways to access complex organic molecules. The approach involves maximising the molecule-building potential of some of the smallest accessible molecular building blocks. Significant outcomes expected from this work include much shorter chemical syntheses of important organic substances and much improved, broad scope synthetic methods. The concepts introduced by this work aims to benefit industry and manufacturing by introducing more efficient methods for fine chemical manufacture, while simultaneously lowering energy use and producing less waste.Read moreRead less
Multi-Bond-Forming Processes: Step-Economical Synthesis In Batch And Flow. This project aims to develop better ways to make and understand organic substances: the materials that make up all known life forms, our medicines, and many designed materials. Based on the previous development of powerful multi-bond-forming processes, the purpose of this project is to develop cascade sequences involving dendralenes in new and innovative ways. The project plans to generalise these processes and apply them ....Multi-Bond-Forming Processes: Step-Economical Synthesis In Batch And Flow. This project aims to develop better ways to make and understand organic substances: the materials that make up all known life forms, our medicines, and many designed materials. Based on the previous development of powerful multi-bond-forming processes, the purpose of this project is to develop cascade sequences involving dendralenes in new and innovative ways. The project plans to generalise these processes and apply them in short total syntheses; extend the boundaries of multi-bond-forming processes and break new records; and reach higher levels of synthetic efficiency and selectivity by introducing the latest flow chemistry and automated reaction optimisation technology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100127
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Flow Reactor Chemical Synthesis Facility. Flow reactor chemical synthesis facility: This flow chemistry facility aims to greatly expand upon the traditional scale batch synthesis operations that are currently in use by organic, organometallic, biological and materials chemistry researchers while minimising environmental impact. The anticipated advantages of this facility are manifold and include both significantly enhanced capabilities (broader experimental/chemical space) and considerably impro ....Flow Reactor Chemical Synthesis Facility. Flow reactor chemical synthesis facility: This flow chemistry facility aims to greatly expand upon the traditional scale batch synthesis operations that are currently in use by organic, organometallic, biological and materials chemistry researchers while minimising environmental impact. The anticipated advantages of this facility are manifold and include both significantly enhanced capabilities (broader experimental/chemical space) and considerably improved safety and efficiency (no unstable intermediate accumulation, greater selectivity, cleaner products, reduced solvent requirements).Read moreRead less
Elucidating the Mode of Action of Nicotinic Receptor Ligands. Changes in brain function can cause human diseases such as epilepsy, schizophrenia and Alzheimer's disease. To develop new medicines to treat these conditions we need to study how drugs act in the brain. This project will use new methods of chemistry to make drugs, which will then be tested for biological activity at important brain receptors. This will tell us which compounds are most effective as potential drugs and also exactly whe ....Elucidating the Mode of Action of Nicotinic Receptor Ligands. Changes in brain function can cause human diseases such as epilepsy, schizophrenia and Alzheimer's disease. To develop new medicines to treat these conditions we need to study how drugs act in the brain. This project will use new methods of chemistry to make drugs, which will then be tested for biological activity at important brain receptors. This will tell us which compounds are most effective as potential drugs and also exactly where they act in the brain. Read moreRead less
Elucidating the Mode of Action of Nicotinic Receptor Ligands. Changes in brain function can cause human diseases such as epilepsy, schizophrenia and Alzheimer's disease. To develop new medicines to treat these conditions we need to study how drugs act in the brain. This project will use new methods of chemistry to make drugs, which will then be tested for biological activity at important brain receptors. This will tell us which compounds are most effective as potential drugs and also exactly whe ....Elucidating the Mode of Action of Nicotinic Receptor Ligands. Changes in brain function can cause human diseases such as epilepsy, schizophrenia and Alzheimer's disease. To develop new medicines to treat these conditions we need to study how drugs act in the brain. This project will use new methods of chemistry to make drugs, which will then be tested for biological activity at important brain receptors. This will tell us which compounds are most effective as potential drugs and also exactly where they act in the brain. Read moreRead less