Harnessing light and electricity to drive chemical synthesis. This project will explore and establish original strategies that use inputs of energy (light and electricity) to break or form chemical bonds, which can provide new or improved access to valuable compounds. In this way, this research will augment or enhance existing methods for the selective and direct manipulation of molecules by creating tools that allow chemists to prepare molecules under particularly mild conditions. The outcomes ....Harnessing light and electricity to drive chemical synthesis. This project will explore and establish original strategies that use inputs of energy (light and electricity) to break or form chemical bonds, which can provide new or improved access to valuable compounds. In this way, this research will augment or enhance existing methods for the selective and direct manipulation of molecules by creating tools that allow chemists to prepare molecules under particularly mild conditions. The outcomes of the project will include the development of new technology for organic synthesis and forging novel approaches for chemical alkylation and cross-coupling reactions. This can contribute to making important compounds more efficiently, safely and cheaper to produce in the future.Read moreRead less
Organometallic Transformations of Organic Compounds. The program will develop new metal-based catalysts for two main purposes (i) transforming basic hydrocarbons eg. natural gas and low-molecular-weight petroleum products into more advanced compounds (such as alcohols, alkenes and carboxylic acids); and (ii) converting nitrogen gas into nitrogen-containing compounds eg. ammonia or ammonia derivatives. In both projects, the aim is to take readily available and abundant starting materials that ar ....Organometallic Transformations of Organic Compounds. The program will develop new metal-based catalysts for two main purposes (i) transforming basic hydrocarbons eg. natural gas and low-molecular-weight petroleum products into more advanced compounds (such as alcohols, alkenes and carboxylic acids); and (ii) converting nitrogen gas into nitrogen-containing compounds eg. ammonia or ammonia derivatives. In both projects, the aim is to take readily available and abundant starting materials that are currently difficult to utilise and to design and develop specific reagents to convert them to "value-added" products. The program will also explore the mode of action of metal-based reagents leading to better reagent and catalyst design.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100057
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
A diffractometer for small molecule structural elucidation by crystallographic analysis. X-ray diffractometry provides an unambiguous means of identifying the three-dimensional spatial arrangement of atoms within molecules affording important insights into the origins of chemical properties. A modern diffractometer will provide information to help develop new functional materials, therapeutic agents and environmentally sustainable processes.
Examination of unique tear lipids and their role in the tear film's structure and function. The tear film lipid layer covers the eye, stabilises the tears and prevents their evaporation. Yet its structure, function and composition are yet to be fully elucidated. The aim of this project is to fully characterise the unique lipids in this layer, the long-chain omega-hydroxy fatty acids (not found elsewhere in the body), and to determine their role in its structure and function. The project is signi ....Examination of unique tear lipids and their role in the tear film's structure and function. The tear film lipid layer covers the eye, stabilises the tears and prevents their evaporation. Yet its structure, function and composition are yet to be fully elucidated. The aim of this project is to fully characterise the unique lipids in this layer, the long-chain omega-hydroxy fatty acids (not found elsewhere in the body), and to determine their role in its structure and function. The project is significant because the unique combination of skills including synthetic chemistry, mass spectrometry, lipidomics, biochemistry, biophysics which aim to result in a major shift in the understanding of this layer.Read moreRead less
Generation of Novel Fermentation Products and their Exploitation in the Synthesis of Biologically Active Organic Compounds with Therapeutic Potential. Collections of new micro-organisms and their metabolites suitable for use in the chemical synthesis programs will emerge from the proposed research. This will provide a potentially highly-valuable national resource that could serve the needs of many laboratories around Australia by allowing them to establish more direct routes to target molecules ....Generation of Novel Fermentation Products and their Exploitation in the Synthesis of Biologically Active Organic Compounds with Therapeutic Potential. Collections of new micro-organisms and their metabolites suitable for use in the chemical synthesis programs will emerge from the proposed research. This will provide a potentially highly-valuable national resource that could serve the needs of many laboratories around Australia by allowing them to establish more direct routes to target molecules being sought in the development of new therapeutic agents and/or materials. The combined application of molecular biological, microbiological and chemical synthesis techniques in a concerted manner in the one location will lead to a raft of new opportunities for the biotech and pharmaceutical industries in Australia.Read moreRead less
ARC Centre of Excellence for Innovations in Peptide and Protein Science. The ARC Centre of Excellence for Innovations in Peptide and Protein Science (CIPPS) strives to build a critical understanding of peptides and proteins in order to unleash the potential of these biomolecules for human benefit. We will discover nature’s untapped reservoir of peptides and proteins, decode their structures and functions, and
develop enhanced synthetic technologies to address biology’s next grand challenge—the d ....ARC Centre of Excellence for Innovations in Peptide and Protein Science. The ARC Centre of Excellence for Innovations in Peptide and Protein Science (CIPPS) strives to build a critical understanding of peptides and proteins in order to unleash the potential of these biomolecules for human benefit. We will discover nature’s untapped reservoir of peptides and proteins, decode their structures and functions, and
develop enhanced synthetic technologies to address biology’s next grand challenge—the design of peptides and proteins for targeted scientific, agricultural, biotechnology, animal health and pharmaceutical applications. CIPPS will assemble leading researchers from diverse disciplines to create a sustainable national entity that will drive new Australian industries and train next generation researchers.Read moreRead less
Taking nature's lead in the development of new and improved enzyme inhibitors. This project will address some key fundamental issues associated with advancing a chemical entity from proof of principle through to a new pharmaceutical. The compounds in the study target cancer, cataract and other diseases that are confronting Australia's ageing population.
Heparan sulphate mimetics: Versatile tools for chemical biology. This project aims to develop chemical tools to study heparan sulphate-binding proteins. Heparan sulphate is a complex polysaccharide that is ubiquitously expressed on mammalian cells and interacts with proteins to mediate numerous biological and pathological functions. These interactions are poorly understood. This project will use homogeneous, structurally defined compounds to study heparan sulphate and its binding partners in bio ....Heparan sulphate mimetics: Versatile tools for chemical biology. This project aims to develop chemical tools to study heparan sulphate-binding proteins. Heparan sulphate is a complex polysaccharide that is ubiquitously expressed on mammalian cells and interacts with proteins to mediate numerous biological and pathological functions. These interactions are poorly understood. This project will use homogeneous, structurally defined compounds to study heparan sulphate and its binding partners in biology. This is expected to lead to a better, molecular-level understanding of these fundamental processes, and may have future applications in biotechnology and drug development.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989946
Funder
Australian Research Council
Funding Amount
$357,000.00
Summary
High Resolution LC/MS and MALDI for Molecular and Macromolecular Characterisation. The provision of high-resolution and matrix assisted laser desorption ionisation mass spectrometers configured for the molecular and macromolecular research of high quality research groups will lead to earlier and better fundamental discoveries that are directed at important practical developments in medicine, biotechnology, nanotechnology, light-energy harvesting, polymer materials and sensors. These include anti ....High Resolution LC/MS and MALDI for Molecular and Macromolecular Characterisation. The provision of high-resolution and matrix assisted laser desorption ionisation mass spectrometers configured for the molecular and macromolecular research of high quality research groups will lead to earlier and better fundamental discoveries that are directed at important practical developments in medicine, biotechnology, nanotechnology, light-energy harvesting, polymer materials and sensors. These include anticancer agents, nanodevices for drug delivery, better polymers with more energy efficient industrial processes, bioactive molecules for industrially important nitrogen fixation and many more. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668374
Funder
Australian Research Council
Funding Amount
$470,000.00
Summary
State-of-the-art NMR Facilities. This proposal will significantly enhance the NMR research capability and capacities at UoW and ANU. These schools have internationally recognised strengths in fundamentals of synthetic organic chemistry, therapeutic drug design and synthesis, protein chemistry and structural biology. This equipment will enhance the productivity of these researchers, increase their collaborative and scientific outputs and allow for training of students in the latest technologies ....State-of-the-art NMR Facilities. This proposal will significantly enhance the NMR research capability and capacities at UoW and ANU. These schools have internationally recognised strengths in fundamentals of synthetic organic chemistry, therapeutic drug design and synthesis, protein chemistry and structural biology. This equipment will enhance the productivity of these researchers, increase their collaborative and scientific outputs and allow for training of students in the latest technologies and importantly, contribute to Australia's development as a knowledge-based economy.Read moreRead less