Folding and dynamics of bioengineered cyclic cystine knot proteins. This project will increase knowledge of the structure and function of an important family of proteins, namely the conotoxins. Conotoxins are of particular interest in Australia as nearly 300 species of cone snails occur in Australian waters and they represent a rich source of novel peptides for drug discovery. This project will enhance their stability by altering their structures and will have a direct impact on peptide-drug ba ....Folding and dynamics of bioengineered cyclic cystine knot proteins. This project will increase knowledge of the structure and function of an important family of proteins, namely the conotoxins. Conotoxins are of particular interest in Australia as nearly 300 species of cone snails occur in Australian waters and they represent a rich source of novel peptides for drug discovery. This project will enhance their stability by altering their structures and will have a direct impact on peptide-drug based therapies, resulting in economic and social benefits for Australian society. Additionally, some peptides under study have agricultural significance for crop protection and this too, has the potential to provide significant economic benefits. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668038
Funder
Australian Research Council
Funding Amount
$175,000.00
Summary
From Fundamentals to Complex Architecture in Free-Radical Polymerisation: Designing Future Generations of Macromolecular Materials. This research will help maintain the profile of Australia as a serious player in the important field of polymer chemistry. It will lay the groundwork for the preparation of novel materials of commercial value. These materials will enable more effective use of Australia's natural resources, support the development of high value-added Australian manufacturing industri ....From Fundamentals to Complex Architecture in Free-Radical Polymerisation: Designing Future Generations of Macromolecular Materials. This research will help maintain the profile of Australia as a serious player in the important field of polymer chemistry. It will lay the groundwork for the preparation of novel materials of commercial value. These materials will enable more effective use of Australia's natural resources, support the development of high value-added Australian manufacturing industries, and find application in human and animal medicine. They will enhance the health and well-being of the Australian community and engender a sense of wonder in susceptible members of this community.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453637
Funder
Australian Research Council
Funding Amount
$256,804.00
Summary
Multi-dimensional polymer characterization facility. The microstructure of polymers dominates their physical properties. This integrated facility will create a world-leading means of characterizing in multiple dimensions the microstructure of complex polymers, eg copolymers and branched polymers. The facility will yield information on the distributions of chain end-groups, monomer microstructure, and branches, as functions of molecular weight. The facility will provide otherwise unobtainable dat ....Multi-dimensional polymer characterization facility. The microstructure of polymers dominates their physical properties. This integrated facility will create a world-leading means of characterizing in multiple dimensions the microstructure of complex polymers, eg copolymers and branched polymers. The facility will yield information on the distributions of chain end-groups, monomer microstructure, and branches, as functions of molecular weight. The facility will provide otherwise unobtainable data for a set of projects exploring questions ranging from how new synthetic materials with tailor-made properties can be created, through to how our understanding of natural polymers can be advanced to improve crop utilization.Read moreRead less
Novel Complex Architecture Polymers via a Combination of RAFT Chemistry and Pericyclic Reactions: Synthesis and Characterization. The project aims at advancing the synthetic limits and broadening the synthetic scope of living free radical polymerization and thus enhancing the library of polymer structures available for applications ranging from drug delivery to opto-electronics. Current material design for these applications is yet to reach its full potential through innovative synthetic approac ....Novel Complex Architecture Polymers via a Combination of RAFT Chemistry and Pericyclic Reactions: Synthesis and Characterization. The project aims at advancing the synthetic limits and broadening the synthetic scope of living free radical polymerization and thus enhancing the library of polymer structures available for applications ranging from drug delivery to opto-electronics. Current material design for these applications is yet to reach its full potential through innovative synthetic approaches. The proposal critically underpins and further advances Australia's leading position in both breakthrough science as well as advanced materials. Due to its significant scientific breadth and large coverage of both synthetic and physical aspects of polymer science, the project also provides a significant platform for research training at both honours and PhD level.Read moreRead less
Defining Polymer Structures in Radical Polymerization Systems: Chain Birth, Chain Growth and Complex Macromolecular Architectures. The project underpins and extends Australia's leading position in the development and application of novel methods to generate advanced polymeric materials. By carefully studying the reaction pathways underpinning the polymerization processes, an in-depth picture of the polymerization is obtained. The research outcomes will strongly benefit the preparation of the com ....Defining Polymer Structures in Radical Polymerization Systems: Chain Birth, Chain Growth and Complex Macromolecular Architectures. The project underpins and extends Australia's leading position in the development and application of novel methods to generate advanced polymeric materials. By carefully studying the reaction pathways underpinning the polymerization processes, an in-depth picture of the polymerization is obtained. The research outcomes will strongly benefit the preparation of the coming generations of intelligent polymer materials of a highly controlled structure, responsive to their environment, with an even broader range of applications than existing polymers. In addition, the project has a substantial educational component providing training embedded in cutting polymer science for several honours and 1 PhD student.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0454249
Funder
Australian Research Council
Funding Amount
$157,004.00
Summary
Specialist Analysis Facility for the Development of New Nanotechnologies. Nanotechnology is a developing technology with a limited number of academic research groups working in this field. Advanced infrastructure is requested for the characterisation and analysis of novel polymers, nanomaterials and biomaterials. The specialist applications herein demand both characterisation and processing control at the nanoscopic level and will greatly enhance teaching and core research capability within Fl ....Specialist Analysis Facility for the Development of New Nanotechnologies. Nanotechnology is a developing technology with a limited number of academic research groups working in this field. Advanced infrastructure is requested for the characterisation and analysis of novel polymers, nanomaterials and biomaterials. The specialist applications herein demand both characterisation and processing control at the nanoscopic level and will greatly enhance teaching and core research capability within Flinders University and the University of South Australia. This equipment will allow the universities to carry out this research in a unique manner. Other researchers cannot offer the synergy of synthesis, processing and characterisation of nanomaterials and biomaterials as described in this project.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0211003
Funder
Australian Research Council
Funding Amount
$125,000.00
Summary
A Facility for Probing Nanostructure in Polymers. The properties of a polymer are only partly determined by its molecular structure. It is now clear that the organization of molecular structure and phase morphology on a nano-scale has an equally important role in determining material behaviour. Increasingly this can be manipulated by judicious choice of formulation and processing variables. The polymer Nano-Structure Facility will bring together Australia's principal polymer experts in this a ....A Facility for Probing Nanostructure in Polymers. The properties of a polymer are only partly determined by its molecular structure. It is now clear that the organization of molecular structure and phase morphology on a nano-scale has an equally important role in determining material behaviour. Increasingly this can be manipulated by judicious choice of formulation and processing variables. The polymer Nano-Structure Facility will bring together Australia's principal polymer experts in this area of structure-property relations and provide them with shared access to the appropriate, modern analytical tools required to probe the nano-structure of such new materials with enhanced properties.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668517
Funder
Australian Research Council
Funding Amount
$220,000.00
Summary
Hyphenated techniques in polymer science and engineering. The collaborator's research capabilities will be greatly enhanced because the equipment will allow simultaneous measurements of various properties which can provide much more information than sequential experiments. Students will be able to undertake research with state-of-the-art equipment which will enhance their research careers and employment prospects. The resulting information will be invaluable to the development of polymer blends ....Hyphenated techniques in polymer science and engineering. The collaborator's research capabilities will be greatly enhanced because the equipment will allow simultaneous measurements of various properties which can provide much more information than sequential experiments. Students will be able to undertake research with state-of-the-art equipment which will enhance their research careers and employment prospects. The resulting information will be invaluable to the development of polymer blends with optimized morphology and mechanical properties; improved polymer processing techniques linked to how the structure and orientation develops; the development of new materials, including novel human tissue implants, from studies of the rheology and phase structure of a polymer during photopolymerization.Read moreRead less
The Synthesis and Evaluation of White Nano Particles that Reinforce the Mechanical Properties of Elastomers. This project will introduce admicellar polymerization technique to produce a bound polymer layer on the surface of fillers used for reinforcement of elastomers. The novel approach in this project will provide advanced material with excellent mechanical properties. Such composites can be used in various high performance elastomer applications such as rubber for tyres in automotive vehicles ....The Synthesis and Evaluation of White Nano Particles that Reinforce the Mechanical Properties of Elastomers. This project will introduce admicellar polymerization technique to produce a bound polymer layer on the surface of fillers used for reinforcement of elastomers. The novel approach in this project will provide advanced material with excellent mechanical properties. Such composites can be used in various high performance elastomer applications such as rubber for tyres in automotive vehicles. Products based on this new technology will produce significantly improved properties. The development of this new technology will not only advance polymer science, it will also provide great opportunities for new elastomer applications in a number of industries.Read moreRead less
Novel biomaterials from improved understanding of the structure of starch. The microstructure of starch, comprising two polymers of glucose: amylose (linear, except for a few long branches) and amylopectin (with a complex tree-like architecture), is described by a high-dimensional function. This project examines simplified measures of the full microstructure, such as the distribution of lengths if all links were cut, and also properties which depend on the full architecture, such as viscoelastic ....Novel biomaterials from improved understanding of the structure of starch. The microstructure of starch, comprising two polymers of glucose: amylose (linear, except for a few long branches) and amylopectin (with a complex tree-like architecture), is described by a high-dimensional function. This project examines simplified measures of the full microstructure, such as the distribution of lengths if all links were cut, and also properties which depend on the full architecture, such as viscoelastic response and adhesion. Theory, simulation and neural networks will be used to guide experiments to elucidate which partial structure measures control which property. Outcomes will include means of helping biotechnology create improved biomaterials, and plant breeders to improve food quality.Read moreRead less