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Novel organic architectures and functional materials from tropylium ions. This project aims to develop new synthetic applications of tropylium ions, as versatile building blocks, to access a broad range of organic structures that used to be difficult and problematic to synthesise. The non-benzenoid aromatic tropylium ion exhibits a unique combination of structural stability and chemical reactivity. This project expects to use tropylium ions as chromophores to derive novel ‘push-and-pull’ organic ....Novel organic architectures and functional materials from tropylium ions. This project aims to develop new synthetic applications of tropylium ions, as versatile building blocks, to access a broad range of organic structures that used to be difficult and problematic to synthesise. The non-benzenoid aromatic tropylium ion exhibits a unique combination of structural stability and chemical reactivity. This project expects to use tropylium ions as chromophores to derive novel ‘push-and-pull’ organic dyes with highly applicable physicochemical properties.This will provide access to a family of novel complex organic structures in a new chemical space, as well as new materials for opto-electronic and sensing applications, respectively.Read moreRead less
Internally decorated discrete Metallo-supramolecular Assemblies and infinite Metal-Organic Frameworks as molecular containers. In the macroscopic world, containers are used to hold, provide physical protection, or create a modified environment for their contents. This project will result in the synthesis of novel molecular container materials that provide decorated internal surfaces capable of selectively binding chemical species. In addition to the breakthrough scientific benefits of establish ....Internally decorated discrete Metallo-supramolecular Assemblies and infinite Metal-Organic Frameworks as molecular containers. In the macroscopic world, containers are used to hold, provide physical protection, or create a modified environment for their contents. This project will result in the synthesis of novel molecular container materials that provide decorated internal surfaces capable of selectively binding chemical species. In addition to the breakthrough scientific benefits of establishing the fundamentals of these systems, the binding of chemicals, which are environmental contaminants, will provide the grounding for applications that will contribute to the national priority of 'Frontier technologies'. Furthermore, this research will lead to the training of the next generation of Australian scientists by quality international researchers.Read moreRead less
Nanoengineering Smart and Precise Antimicrobial Polymers. Designing the next generation of antimicrobial polymers. This proposal aims to combat the critical global issue of antibiotic resistance via fundamental and innovative chemistry design solutions. The proposed new design will enable the polymers to activate intelligently and precisely in the presence of specific stimuli such as bacterial enzymes for the first time, thereby endowing the polymers with both antimicrobial and biocompatible pro ....Nanoengineering Smart and Precise Antimicrobial Polymers. Designing the next generation of antimicrobial polymers. This proposal aims to combat the critical global issue of antibiotic resistance via fundamental and innovative chemistry design solutions. The proposed new design will enable the polymers to activate intelligently and precisely in the presence of specific stimuli such as bacterial enzymes for the first time, thereby endowing the polymers with both antimicrobial and biocompatible properties. Both properties are crucially needed for successful translation into practical applications. This proposal will lead to new and effective avenues in fighting multidrug-resistant bacteria and will significantly benefit Australia's healthcare and agriculture sectors.Read moreRead less
Sequence-defined polymers and green chemistry. This project aims to synthesise polymers that have precise chemical structure and mimic the biological activities of natural biopolymers like peptides and proteins. Monomer sequence regulation in these natural biopolymers is important in biology and necessary for crucial features of life, such as molecular recognition, self-replication and catalysis. Current artificial techniques for biopolymer synthesis are time consuming and present low yields at ....Sequence-defined polymers and green chemistry. This project aims to synthesise polymers that have precise chemical structure and mimic the biological activities of natural biopolymers like peptides and proteins. Monomer sequence regulation in these natural biopolymers is important in biology and necessary for crucial features of life, such as molecular recognition, self-replication and catalysis. Current artificial techniques for biopolymer synthesis are time consuming and present low yields at high costs. This project expects its new materials will increase manufacturing sustainability, chemical diversity and industrial viability; produce health benefits for Australia by improving chemotherapy and diagnosis for diseases; and benefit the Australian economy.Read moreRead less
Engineering two dimensional polymers for membrane-based chemical separation. This project aims to develop novel two-dimensional polymers with precisely controlled pore-sizes for preparing membrane materials which can efficiently separate these gaseous chemicals at ambient temperatures. Key industrial chemical mixtures with similar size and boiling points are difficult to separate by conventional distillation methods. Currently, purification of olefins alone accounts for 0.3% of global energy use ....Engineering two dimensional polymers for membrane-based chemical separation. This project aims to develop novel two-dimensional polymers with precisely controlled pore-sizes for preparing membrane materials which can efficiently separate these gaseous chemicals at ambient temperatures. Key industrial chemical mixtures with similar size and boiling points are difficult to separate by conventional distillation methods. Currently, purification of olefins alone accounts for 0.3% of global energy use. The expected outcomes of the project will have a huge impact on industrial purification processing by providing a disruptive membrane technology, and will significantly reduce energy consumption and open up new routes for resources.Read moreRead less
Platinum drugs containing core-shell nanoparticles. Many drugs such as cancer drugs contain metal ions. While the therapeutic benefits of metal containing drugs are highly promising, their administration is often accompanied by substantial side effects. Encapsulation of these drugs into nano-sized core-shell particles will prolong the circulation of the drug and therefore reduce the amount of repeated administrations. In addition, the shape and nature of the particle will enable the targeted del ....Platinum drugs containing core-shell nanoparticles. Many drugs such as cancer drugs contain metal ions. While the therapeutic benefits of metal containing drugs are highly promising, their administration is often accompanied by substantial side effects. Encapsulation of these drugs into nano-sized core-shell particles will prolong the circulation of the drug and therefore reduce the amount of repeated administrations. In addition, the shape and nature of the particle will enable the targeted delivery of these drug loaded nanocarriers to the tumor while healthy tissue remains unaffected. Read moreRead less
Polymer nanodiscs. This project aims to produce disc-shaped polymer nanomaterials by utilising a new self-assembly concept based on oppositely charged polymers. This project expects to generate a modular technology that allows synthesis and control over the geometry and functionality of polymer nanoparticles. This level of control will permit a precise investigation of polymer nanodisc properties for nanomedicine applications. Expected outcomes of this project will be the fundamental understandi ....Polymer nanodiscs. This project aims to produce disc-shaped polymer nanomaterials by utilising a new self-assembly concept based on oppositely charged polymers. This project expects to generate a modular technology that allows synthesis and control over the geometry and functionality of polymer nanoparticles. This level of control will permit a precise investigation of polymer nanodisc properties for nanomedicine applications. Expected outcomes of this project will be the fundamental understanding of how nanoparticle geometry affects particle-cell interaction and how nanoscale polymer discs can be used to mimic biological nanoparticles in shape and function.Read moreRead less
Vesicles stabilised by compressed carbon dioxide as nanoreactors and templates for radical polymerisation. A new environmentally friendly method for synthesis of surfactant vesicles involving stabilisation using low pressure carbon dioxide will be applied to the synthesis of hollow polymeric nanoparticles and polymer of well-defined structure. The resulting polymeric structures will have applications in drug delivery and nano-engineered materials.
Multimodal polymeric nanocarriers designed for the controlled and site specific delivery of nitric oxide. Nitric oxide (NO) plays a key role in the development of different diseases. The chronic deficiency of NO results in severe problems such as cardiovascular diseases, liver fibrosis, diabetes, cancer, Alzheimer’s diseases, etc. This project will describe a new method to deliver specifically nitric oxide using macromolecules.
New platform technologies for the chemical synthesis of post-translationally modified proteins. The last decade has seen an explosion in the number of protein drugs approved for use in the clinic, a large proportion of which possess post-translational modifications (PTMs). These modified protein drugs are produced and sold as mixtures which has led to difficulties in understanding the role of specific PTMs on activity and in gaining clinical approval for candidate drugs. This project will provid ....New platform technologies for the chemical synthesis of post-translationally modified proteins. The last decade has seen an explosion in the number of protein drugs approved for use in the clinic, a large proportion of which possess post-translational modifications (PTMs). These modified protein drugs are produced and sold as mixtures which has led to difficulties in understanding the role of specific PTMs on activity and in gaining clinical approval for candidate drugs. This project will provide a fundamental solution to this problem through the development of novel synthetic methods and a powerful new platform technology for accessing PTM proteins in pure form. The utility of this technology will be demonstrated through its use in the total chemical synthesis of a range of PTM proteins for applications in biology and medicine.Read moreRead less