Stronger, coarser-grained biodegradable zinc alloys. This project aims to develop stronger and more durable zinc alloys for a new generation of biodegradable metals for potential load-bearing orthopaedic applications. It expects to deliver a group of novel zinc alloys with better properties and a new technology for manufacturing them, and to use advanced experimental techniques to reveal deformation and strengthening mechanisms that underlie the unusual Hall-Petch and anomalous twinning phenomen ....Stronger, coarser-grained biodegradable zinc alloys. This project aims to develop stronger and more durable zinc alloys for a new generation of biodegradable metals for potential load-bearing orthopaedic applications. It expects to deliver a group of novel zinc alloys with better properties and a new technology for manufacturing them, and to use advanced experimental techniques to reveal deformation and strengthening mechanisms that underlie the unusual Hall-Petch and anomalous twinning phenomena and the unprecedented properties of these alloys. Expected outcomes are likely to form the technology and scientific basis for developing better biodegradable metallic alloys. This has the potential eventually to create a better life for thousands of Australian patients.Read moreRead less
Stronger zinc alloys for more flexible biodegradable stents. This project aims to develop stronger zinc alloys for a new class of biodegradable metallic stents. A key challenge for biodegradable stent technology is to make stents as thin as possible while also being strong. This project will develop ultra-high strength zinc alloys that can be used to fabricate thinner biodegradable stents for easier surgical operation. The project outcomes should be a major step in the design and development of ....Stronger zinc alloys for more flexible biodegradable stents. This project aims to develop stronger zinc alloys for a new class of biodegradable metallic stents. A key challenge for biodegradable stent technology is to make stents as thin as possible while also being strong. This project will develop ultra-high strength zinc alloys that can be used to fabricate thinner biodegradable stents for easier surgical operation. The project outcomes should be a major step in the design and development of a new generation of biodegradable stents that will avoid the risks associated with existing products and potentially create a better life for millions of patients worldwide.Read moreRead less
Innovative Zn alloys with essential mechanical and biofunctional properties. This project aims to develop a breakthrough understanding of the impact of alloying additions on the strengthening mechanisms, degradation behaviour, antibacterial properties and biofunctionalities of zinc alloys. The project expects to generate new knowledge in alloying strategies, plastic deformation and surface modification of zinc alloys to achieve mechanical, corrosion and biofunctional properties satisfying the re ....Innovative Zn alloys with essential mechanical and biofunctional properties. This project aims to develop a breakthrough understanding of the impact of alloying additions on the strengthening mechanisms, degradation behaviour, antibacterial properties and biofunctionalities of zinc alloys. The project expects to generate new knowledge in alloying strategies, plastic deformation and surface modification of zinc alloys to achieve mechanical, corrosion and biofunctional properties satisfying the requirements of biodegradable metallic materials. The expected outcomes are the development of novel zinc alloys and practical technologies for industry applications, such as thermomechanical processing and surface coating. The benefits are expected to extend to physical metallurgy and biomaterial manufacturing.Read moreRead less
Oxygenation history of the Earth and the evolution of complex life. This project will investigate how and when the atmosphere became oxygen-rich by analyzing ancient barrier reefs and other rocks that formed between 1000 to 300 million years ago, spanning the appearance and diversification of animals and plants. The project is significant because the buildup of oxygen in the atmosphere was arguably the most important chemical process ever to have occurred on Earth and controlled the evolution of ....Oxygenation history of the Earth and the evolution of complex life. This project will investigate how and when the atmosphere became oxygen-rich by analyzing ancient barrier reefs and other rocks that formed between 1000 to 300 million years ago, spanning the appearance and diversification of animals and plants. The project is significant because the buildup of oxygen in the atmosphere was arguably the most important chemical process ever to have occurred on Earth and controlled the evolution of environments, climate and life. A major outcome will be an improved understanding of how the Earth's atmosphere and climate are regulated by geological processes. This project will generate new knowledge about how sedimentary zinc, lead and copper ore deposits form, which may guide exploration for these commodities.Read moreRead less
Understanding dynamic interfaces in electrochemical systems. This project aims to develop nanoscale characterisation methods to understand dynamic processes in zinc-ion batteries and high temperature electrolysis systems under real working (in operando) conditions. This project expects to reveal critical solid-liquid and solid-gas interfacial processes in these two distinctly different electrochemical systems. The expected outcomes include improved understanding of electrochemical interfaces and ....Understanding dynamic interfaces in electrochemical systems. This project aims to develop nanoscale characterisation methods to understand dynamic processes in zinc-ion batteries and high temperature electrolysis systems under real working (in operando) conditions. This project expects to reveal critical solid-liquid and solid-gas interfacial processes in these two distinctly different electrochemical systems. The expected outcomes include improved understanding of electrochemical interfaces and improved tools and methods to observe nanoscale interfacial processes. This information can be used to underpin mechanistic models, which will facilitate new materials design. Read moreRead less
Nettles & toxic toupees: the molecular weaponry of venomous caterpillars. This project aims to investigate the structure, function and evolution of peptide toxins in venoms made by caterpillars in superfamily Zygaenoidea. Caterpillars in this group are covered in spines that inject pain-causing venoms, and this protects them from vertebrate and invertebrate predators. This project will test if peptides in this venom cause pain by pharmacological modulation of mammalian ion channels and signallin ....Nettles & toxic toupees: the molecular weaponry of venomous caterpillars. This project aims to investigate the structure, function and evolution of peptide toxins in venoms made by caterpillars in superfamily Zygaenoidea. Caterpillars in this group are covered in spines that inject pain-causing venoms, and this protects them from vertebrate and invertebrate predators. This project will test if peptides in this venom cause pain by pharmacological modulation of mammalian ion channels and signalling receptors, and if they have insecticidal properties. The first three-dimensional structures of caterpillar venom peptides will also be solved. Genomes of representatives of two different zygaenoid families will be produced, and genomic techniques will be used to elucidate how venom use evolved at the molecular level.Read moreRead less
Thioamide ligations: new technologies for peptide and protein synthesis. This project aims to develop novel amide-bond forming reactions for the chemical synthesis of peptides and proteins. New peptide ligation strategies, including an asparagine-based ligation and a residue-independent ligation will be developed that exploit the recent discovery of silver-promoted coupling reactions of thioamides. A novel late-stage, chemo-selective assembly of N-glycosylated asparagine residues in peptides and ....Thioamide ligations: new technologies for peptide and protein synthesis. This project aims to develop novel amide-bond forming reactions for the chemical synthesis of peptides and proteins. New peptide ligation strategies, including an asparagine-based ligation and a residue-independent ligation will be developed that exploit the recent discovery of silver-promoted coupling reactions of thioamides. A novel late-stage, chemo-selective assembly of N-glycosylated asparagine residues in peptides and proteins will also be developed. The outcomes of this research will lead to breakthroughs in synthetic methodologies for the assembly and functionalisation of peptides and proteins, thereby enabling access to a range of homogeneous, post translationally modified proteins though total chemical synthesis. These research outcomes will expand Australia's research capability and global competitiveness in the field of biotechnology, delivering significant benefits to the third largest manufacturing sector in Australia.Read moreRead less
Single-session Introduction of Mutations in Parallel Lines (SIMPL). This project aims to develop a novel method for markedly accelerating production of genetically modified mice, which are a key 'tool' for studying biological processes and diseases. The work plans to take CRISPR, the latest gene-editing technique, to the next level by developing a novel CRISPR-based method to generate different mouse strains with distinct variations of the same gene sequences, at a fraction of the present cost a ....Single-session Introduction of Mutations in Parallel Lines (SIMPL). This project aims to develop a novel method for markedly accelerating production of genetically modified mice, which are a key 'tool' for studying biological processes and diseases. The work plans to take CRISPR, the latest gene-editing technique, to the next level by developing a novel CRISPR-based method to generate different mouse strains with distinct variations of the same gene sequences, at a fraction of the present cost and time. This project should overcome a major barrier to studying gene function with unprecedented detail, thereby opening new avenues for future research into biological processes. Thus, the outcomes from this project should impact on the entire field of biomedical research, and advance Australia's biotech industry.Read moreRead less