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.
High performance inks for solution based organic light emitting diodes manufacturing. This project aims to introduce an advanced solution processing and printing technique for organic light emitting diode (OLED) fabrication based on a set of innovative macromolecular chemistries. These proceed either photochemically or thermally, exploiting precision macromolecular designs of the polymer precursor materials, which contain advanced emitter systems developed by Cynora. Solution fabrication of OLED ....High performance inks for solution based organic light emitting diodes manufacturing. This project aims to introduce an advanced solution processing and printing technique for organic light emitting diode (OLED) fabrication based on a set of innovative macromolecular chemistries. These proceed either photochemically or thermally, exploiting precision macromolecular designs of the polymer precursor materials, which contain advanced emitter systems developed by Cynora. Solution fabrication of OLED is a challenging, yet ultimately powerful, process with key advantages over current vacuum processing systems, especially with regard to production flexibility, cost and OLED size. The project will provide a functioning technology platform for solution OLED fabrication.Read moreRead less
Dyes and Pigments as Building Blocks for Novel High Performance Organic Semiconductors. Natural dyes and pigments are well known for their bright colours, photochemical and thermal stability, and cheap cost. Recently, the necessity of high performing materials in the organic electronics has stimulated a renaissance of these historical molecules and their subsequent derivatives into new families of ?-conjugated building blocks used to construct new donor-acceptor semiconductors. The aim of this p ....Dyes and Pigments as Building Blocks for Novel High Performance Organic Semiconductors. Natural dyes and pigments are well known for their bright colours, photochemical and thermal stability, and cheap cost. Recently, the necessity of high performing materials in the organic electronics has stimulated a renaissance of these historical molecules and their subsequent derivatives into new families of ?-conjugated building blocks used to construct new donor-acceptor semiconductors. The aim of this project is to explore various novel dyes, pigments and their derivatives for constructing outstanding materials for future organic electronics.Read moreRead less
Nitroxide-containing scaffolds for controlling biofilm-related infections. Bacterial biofilms are a major problem in healthcare systems around the world as they cause persistent and chronic infections, including those associated with medical implants and cystic fibrosis. This project aims to develop new chemical approaches to deliver nitroxides at surface interfaces and in microparticles to facilitate long term control over biofilm growth. It is expected that these functionalised scaffolds will ....Nitroxide-containing scaffolds for controlling biofilm-related infections. Bacterial biofilms are a major problem in healthcare systems around the world as they cause persistent and chronic infections, including those associated with medical implants and cystic fibrosis. This project aims to develop new chemical approaches to deliver nitroxides at surface interfaces and in microparticles to facilitate long term control over biofilm growth. It is expected that these functionalised scaffolds will represent a breakthrough in the field and will have a profound impact by reducing infection rates associated with medical devices and improving airway clearance in cystic fibrosis patients.Read moreRead less
The crucial role of organic-inorganic interfaces in the performance of organic optoelectronic devices. Organic electronic devices such as organic light emitting diodes and organic solar cells are expected to lead to substantial benefits over conventional electronic components. However, there is increasing evidence that the interface between the organic layers and the inorganic electrodes (or active components in hybrid devices) could be sub-optimal in terms of critical properties such as electro ....The crucial role of organic-inorganic interfaces in the performance of organic optoelectronic devices. Organic electronic devices such as organic light emitting diodes and organic solar cells are expected to lead to substantial benefits over conventional electronic components. However, there is increasing evidence that the interface between the organic layers and the inorganic electrodes (or active components in hybrid devices) could be sub-optimal in terms of critical properties such as electron transfer and stability. The aim of this project is to understand the structure and properties of such interfaces and to probe their behaviour at elevated temperatures. The results will pave the way for organic electronic devices to become a commercial reality.Read moreRead less
ARC Centre of Excellence for Electromaterials Science. The ARC Centre of Excellence for Electromaterials Science (ACES) will create next generation electrochemical devices via the precision assembly of nano/micro dimensional components into macroscopic structures. Through the discovery of new materials and structures, and understanding how spatial arrangement in 3D influences chemical, physical and biological properties, ACES will define the cutting edge of Electromaterials Science. The resultin ....ARC Centre of Excellence for Electromaterials Science. The ARC Centre of Excellence for Electromaterials Science (ACES) will create next generation electrochemical devices via the precision assembly of nano/micro dimensional components into macroscopic structures. Through the discovery of new materials and structures, and understanding how spatial arrangement in 3D influences chemical, physical and biological properties, ACES will define the cutting edge of Electromaterials Science. The resulting technology breakthroughs will have a direct impact on some of today's most challenging global problems in clean energy, synthetic biosystems, diagnostics and soft robotics. National benefit to Australia will be realised through the creation of new manufacturing industries.Read moreRead less
Macromolecular Engineering of Functional Metal–Ligand Materials. Materials self-assembled from metal ions and ligands have a range of important applications, including as advanced coatings, adhesives and catalysts. However, these materials have been largely limited to those assembled from naturally occurring ligands such as phenolics, restricting their properties and function. This project aims to greatly expand the range of accessible properties of metal–phenolic materials by combining self-ass ....Macromolecular Engineering of Functional Metal–Ligand Materials. Materials self-assembled from metal ions and ligands have a range of important applications, including as advanced coatings, adhesives and catalysts. However, these materials have been largely limited to those assembled from naturally occurring ligands such as phenolics, restricting their properties and function. This project aims to greatly expand the range of accessible properties of metal–phenolic materials by combining self-assembly with advanced polymer synthesis techniques. The expected outcome of the project is a new class of functional materials applicable as self-healing coatings, nanoadhesives and antimicrobial surfaces, thus underpinning next-generation technologies in materials science and nanotechnology.Read moreRead less
Smart materials from semi-soft particles. This project will combine precision polymer chemistry to material science to develop structured nanoparticles for applications in photonics and shape memory materials.
Impact of Biological Coatings on Nanoparticle–Immune Cell Interactions. Nanomaterials exposed to biological environments such as blood or lymph fluids rapidly adsorb a layer of biomolecules on their surface, forming a biomolecular corona, and profoundly altering their properties. This project aims to resolve the influence of biomolecular coronas on nanoparticle–immune cell interactions by combining particle engineering, immunology, proteomics and bioinformatic analysis. The project expected outc ....Impact of Biological Coatings on Nanoparticle–Immune Cell Interactions. Nanomaterials exposed to biological environments such as blood or lymph fluids rapidly adsorb a layer of biomolecules on their surface, forming a biomolecular corona, and profoundly altering their properties. This project aims to resolve the influence of biomolecular coronas on nanoparticle–immune cell interactions by combining particle engineering, immunology, proteomics and bioinformatic analysis. The project expected outcomes are to generate new knowledge in nanomaterial–immune cell behaviour and design principles for nanoparticles with prospective applications in the agricultural, veterinary and biomedical sectors.Read moreRead less
Multifunctional and Multimodal Theranostics: Manipulating Material Properties for Advanced Diagnostics. The utilisation of polymers in nanomedicine requires a bottom-up approach, where the fundamental chemistry is well-established and understood before it enables an application. This project develops branched polymers as new nanomaterials for theranostics; imaging modalities that “switch-on” when miRNA is released will quantify how much nanomaterial gets to a specific site, while a built-in sens ....Multifunctional and Multimodal Theranostics: Manipulating Material Properties for Advanced Diagnostics. The utilisation of polymers in nanomedicine requires a bottom-up approach, where the fundamental chemistry is well-established and understood before it enables an application. This project develops branched polymers as new nanomaterials for theranostics; imaging modalities that “switch-on” when miRNA is released will quantify how much nanomaterial gets to a specific site, while a built-in sensor based on physical changes in the nanomaterial will measure the onset and progression of necrosis. The aim is to develop a fundamental understanding of how polymer architecture and functionality can be utilised to drive device performance, providing a platform to probe new technology and methodologies for development of next generation theranostics.Read moreRead less