Special Research Initiatives - Grant ID: SR0354636
Funder
Australian Research Council
Funding Amount
$30,000.00
Summary
Australian Computational Molecular Science Network. Computational Molecular Science (CMS) involves the use of theory and computational methods to simulate and visualise molecular systems ranging from small atmospheric species to proteins, nucleic acids, chemical polymers and materials. It represents our most incisive expression of what we understand about the molecular basis of nature. The CMS network will integrate and cross-fertilize both fundamental and application-based expertize in molecula ....Australian Computational Molecular Science Network. Computational Molecular Science (CMS) involves the use of theory and computational methods to simulate and visualise molecular systems ranging from small atmospheric species to proteins, nucleic acids, chemical polymers and materials. It represents our most incisive expression of what we understand about the molecular basis of nature. The CMS network will integrate and cross-fertilize both fundamental and application-based expertize in molecular scale computations in the fields of nanoscience, biomaterials, biotechnology, biomedical science and environmental science. It will uncover and explore critical new interdisciplinary science and create new molecular-based paradigms that will drive advances in these fields over the next decade.Read moreRead less
Joint Theoretical and Experimental Electron Momentum Spectroscopic Studies for DNA Bases. The study of DNA structure is an area of intense research activity and continues to reveal new levels of complexity and diversity. Recent experiments (Science, 2002) provided direct evidences of the adenine non-planarity, indicating non-rigidity of DNA bases. Electron momentum spectroscopy (EMS) has been identified to be an appropriate technique in the study of chemical binding mechanism and orbitals at mol ....Joint Theoretical and Experimental Electron Momentum Spectroscopic Studies for DNA Bases. The study of DNA structure is an area of intense research activity and continues to reveal new levels of complexity and diversity. Recent experiments (Science, 2002) provided direct evidences of the adenine non-planarity, indicating non-rigidity of DNA bases. Electron momentum spectroscopy (EMS) has been identified to be an appropriate technique in the study of chemical binding mechanism and orbitals at molecular level. The aims of the project is to study orbitals and interactions of DNA and RNA bases such as adenine, thymine (uracil), guanine and cytosine using momentum space quantum mechanics and EMS experimental techniques. The outcome of the project will improve our understanding of the DNA double helical strand structure.Read moreRead less
Experimental Electron Densities, Crystal Engineering and Molecular Recognition: A Supramolecular Approach to Drug Design. GABA receptors are important therapeutic targets for the treatment of a number of disorders from memory dysfunction, to muscle spasticity and chronic pain. This project is designed to address some of the fundamental questions associated with drug/target interactions. This work will lead to a greater understanding of how the chemical structure of a drug can be tailored to prod ....Experimental Electron Densities, Crystal Engineering and Molecular Recognition: A Supramolecular Approach to Drug Design. GABA receptors are important therapeutic targets for the treatment of a number of disorders from memory dysfunction, to muscle spasticity and chronic pain. This project is designed to address some of the fundamental questions associated with drug/target interactions. This work will lead to a greater understanding of how the chemical structure of a drug can be tailored to produce a more effective compound. The outcomes of this program will highlight Australia as a strong contributing nation in molecular design. It is certain that the outcomes of this program will benefit Australia by providing a much greater level of understanding of the fundamental properties of molecules and how others may be rationally designed to suit a specific role.Read moreRead less