Supramolecular assembly in photovoltaic electrode design: Studies of ordered porphyrin/acceptor complexes on polythiophene electrodes. This research outlines an improved way to develop dye-sensitised photovoltaic solar cells for the conversion of sunlight into electricity, by increasing the molecular order of the cell components using host, guest interrelationships. As such, it addresses a problem of international concern 'How to reduce greenhouse gas emissions and stop global warming?' since s ....Supramolecular assembly in photovoltaic electrode design: Studies of ordered porphyrin/acceptor complexes on polythiophene electrodes. This research outlines an improved way to develop dye-sensitised photovoltaic solar cells for the conversion of sunlight into electricity, by increasing the molecular order of the cell components using host, guest interrelationships. As such, it addresses a problem of international concern 'How to reduce greenhouse gas emissions and stop global warming?' since solar cells do not produce carbon dioxide. To achieve our goals we draw on the skills of a team of experts from Australia (synthetic organic chemists), New Zealand (polymer and surface chemists) and Italy (photochemist and photophysicist). Such research is very appropriate for regional Australia, especially Central Queensland.Read moreRead less
Environmentally sustainable asymmetric synthesis: design and development of chiral hydrogen bonding organocatalysts. There is a pressing need for more environmentally sustainable and economically viable methods for asymmetric synthesis. This project aims to design, synthesise and evaluate new organocatalysts based on the principle of hydrogen bonding activation, a common feature of Nature's catalysts, enzymes. These inexpensive, non-toxic, air- and moisture-stable catalysts may prove to be more ....Environmentally sustainable asymmetric synthesis: design and development of chiral hydrogen bonding organocatalysts. There is a pressing need for more environmentally sustainable and economically viable methods for asymmetric synthesis. This project aims to design, synthesise and evaluate new organocatalysts based on the principle of hydrogen bonding activation, a common feature of Nature's catalysts, enzymes. These inexpensive, non-toxic, air- and moisture-stable catalysts may prove to be more efficient, selective and have broader applicability than catalysts based on transition metals. The growing Australian pharmaceutical and biotechnology industries will benefit from the development of these new Advanced Materials and the training provided to young scientists in the sought-after fields of asymmetric synthesis and catalysis.Read moreRead less
Development of an Adjustable Porphyrin-based Molecular Platform for Nanotechnology Applications. Nanotechnology, the art of molecular control, is often heralded as the next industrial revolution. For this to be realised, the construction of useful devices will require precise control at the molecular level. Our control is realised through a process called self-assembly which means that the once the components of the device are correctly designed, the device will simply be able to put itself tog ....Development of an Adjustable Porphyrin-based Molecular Platform for Nanotechnology Applications. Nanotechnology, the art of molecular control, is often heralded as the next industrial revolution. For this to be realised, the construction of useful devices will require precise control at the molecular level. Our control is realised through a process called self-assembly which means that the once the components of the device are correctly designed, the device will simply be able to put itself together. This research will use nature's light harvesting elements, namely porphyrins, and our ability to precisely control their position with respect to each other to build new, more efficient solar cells.Read moreRead less
Molecular probes for pancreatic cancer. Cancer has overtaken heart disease as the main cause of premature death in Australia. Currently one in two men and one in three women are diagnosed with cancer during their lifetime. Pancreatic cancer is the fourth leading cause of cancer death in Australia, and the current lack of effective therapies results in a 1 year survival of just over 10%, and a 5 year survival of less than 5%. This project aims to identify and produce new compounds with novel mech ....Molecular probes for pancreatic cancer. Cancer has overtaken heart disease as the main cause of premature death in Australia. Currently one in two men and one in three women are diagnosed with cancer during their lifetime. Pancreatic cancer is the fourth leading cause of cancer death in Australia, and the current lack of effective therapies results in a 1 year survival of just over 10%, and a 5 year survival of less than 5%. This project aims to identify and produce new compounds with novel mechanisms of action that will facilitate our understanding of pancreatic carcinogenesis and provide the basis for the development of new therapeutic strategies. Australians diagnosed with pancreatic cancer in the future may directly benefit from the results of this work.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775676
Funder
Australian Research Council
Funding Amount
$290,000.00
Summary
An X-ray Diffraction Facility for Molecular Structure Determination. Characterisation of new chemical compounds demands proof of molecular structure. Whether for the identification of a new drug candidate, a material with novel properties or in the exploration of previously unknown types of compounds, X-ray crystallography is the definitive technique for this purpose. This proposal is for an X-ray diffractometer that will significantly enhance the capabilities of all synthetic and natural produc ....An X-ray Diffraction Facility for Molecular Structure Determination. Characterisation of new chemical compounds demands proof of molecular structure. Whether for the identification of a new drug candidate, a material with novel properties or in the exploration of previously unknown types of compounds, X-ray crystallography is the definitive technique for this purpose. This proposal is for an X-ray diffractometer that will significantly enhance the capabilities of all synthetic and natural products chemistry research programs undertaken at the Universities of Queensland and Newcastle, all currently in receipt of ARC funding. This research is aligned with the ARC National Research Priorities, of Promoting and Maintaining Good Health and Frontier Technologies for Building and Transforming Australian Industries.Read moreRead less
The development of copper-free click chemistry to label biomolecules within living cells. Understanding how cells work is central to modern advances in biomedical science, however many cellular processes are invisible to the researcher because of a lack of appropriate tools. This proposal will apply modern chemistry approaches to the design of new chemical tools for visualising biomolecules within living cells and for investigating cell function. This project brings together experts in chemistry ....The development of copper-free click chemistry to label biomolecules within living cells. Understanding how cells work is central to modern advances in biomedical science, however many cellular processes are invisible to the researcher because of a lack of appropriate tools. This proposal will apply modern chemistry approaches to the design of new chemical tools for visualising biomolecules within living cells and for investigating cell function. This project brings together experts in chemistry, stem cells and malaria and has applications for development of much needed new therapeutics. This research will advance biomedical research and generate new discoveries for a competitive advantage for Australian science, with potential economic return for the nation.Read moreRead less
Total chemical synthesis of a redesigned enzyme, HIV-1 PR, containing an artificial tunable catalytic apparatus. The research project proposed represents a novel approach using total chemical synthesis to study the enzyme action of the HIV-1 PR, an aspartyl protease essential for the replication of AIDS virus. The redesign of the catalytic apparatus will allow us to investigate molecular aspects of its action. The synthetic polypeptide chain will be folded and characterised for the correct folde ....Total chemical synthesis of a redesigned enzyme, HIV-1 PR, containing an artificial tunable catalytic apparatus. The research project proposed represents a novel approach using total chemical synthesis to study the enzyme action of the HIV-1 PR, an aspartyl protease essential for the replication of AIDS virus. The redesign of the catalytic apparatus will allow us to investigate molecular aspects of its action. The synthetic polypeptide chain will be folded and characterised for the correct folded structure by NMR, and assayed for enzymatic activity. It can be expected that significant new insights into the molecular basis of the properties of the HIV-1 PR will be obtained. This will be an important contribution to biomedical research.Read moreRead less
CHARACTERISATION OF NOVEL BIOACTIVES FROM AUSTRALIAN HONEY WITH THERAPEUTIC POTENTIAL. Honey from specific Australian flowering plants has been identified that contain significant therapeutic properties in wound healing and other treatments. The research project proposed will identify and fully characterise the bioactive components of selected Australian honey (Medihoney) with antibiotic and growth promoting activites. These aims will be supported by high resolution mass spectrometry interfaced ....CHARACTERISATION OF NOVEL BIOACTIVES FROM AUSTRALIAN HONEY WITH THERAPEUTIC POTENTIAL. Honey from specific Australian flowering plants has been identified that contain significant therapeutic properties in wound healing and other treatments. The research project proposed will identify and fully characterise the bioactive components of selected Australian honey (Medihoney) with antibiotic and growth promoting activites. These aims will be supported by high resolution mass spectrometry interfaced with HPLC and or affinity chip surfaces, 750 MHz NMR analysis and a range of relevant bioassays on specific organisms and cell lines. These outcomes will not only enhance the value of current honey-based products but have the potential to identify new therapeutic lead molecules.Read moreRead less
New vistas in porphyrin chemistry via metal-catalyzed couplings with hydrazine derivatives. This project will address basic scientific questions and develop new substances for use in molecular electronics and cancer therapy. We will make and study entirely new molecules derived from porphyrins, which in Nature have vital roles in photosynthesis, oxygen transport and enzyme catalysis. This breakthrough research will reveal knowledge vital to the advancement of fundamental chemical science and als ....New vistas in porphyrin chemistry via metal-catalyzed couplings with hydrazine derivatives. This project will address basic scientific questions and develop new substances for use in molecular electronics and cancer therapy. We will make and study entirely new molecules derived from porphyrins, which in Nature have vital roles in photosynthesis, oxygen transport and enzyme catalysis. This breakthrough research will reveal knowledge vital to the advancement of fundamental chemical science and also offer excellent training in cutting edge research for young Australian scientists. In addition, porphyrin-like substances are used in cancer diagnosis and treatment and have properties essential for the next generation of nanoelectronic devices, and this project is aimed at these eventual outcomes.Read moreRead less
Chemical building block size principles for discovery chemists. This project aims to deliver an innovative platform of new fundamental molecules, and associated design principles that will assist discovery chemists (DCs) to sidestep outdated, caged hydrocarbon chemical building blocks (CHCBBs). The expanding global population places significant challenges on discovery chemistry, driven by an appetite for innovative chemical technologies for societal longevity such as pharmaceuticals, agrichemica ....Chemical building block size principles for discovery chemists. This project aims to deliver an innovative platform of new fundamental molecules, and associated design principles that will assist discovery chemists (DCs) to sidestep outdated, caged hydrocarbon chemical building blocks (CHCBBs). The expanding global population places significant challenges on discovery chemistry, driven by an appetite for innovative chemical technologies for societal longevity such as pharmaceuticals, agrichemicals, and microelectronics. In translating this new CHCBB technology into accessible commodity supply streams, the project hopes to provide DCs with tools to sustain chemical technology evolution in a multitude of key industries that underpin the longevity of society.Read moreRead less