Polymerization of amyloid fibrils and electroactive hybrid nanowires using ionic liquids. The electronics world is constantly shrinking with devices being miniaturised and increasing levels of complexity built in. To maintain this trend, new technologies and new device fabrication approaches are required. APD Byrne, will develop new materials based on amyloid fibrils by their facile conversion to a range of novel high strength electroactive nanoscopic wires with application in many electronic d ....Polymerization of amyloid fibrils and electroactive hybrid nanowires using ionic liquids. The electronics world is constantly shrinking with devices being miniaturised and increasing levels of complexity built in. To maintain this trend, new technologies and new device fabrication approaches are required. APD Byrne, will develop new materials based on amyloid fibrils by their facile conversion to a range of novel high strength electroactive nanoscopic wires with application in many electronic devices. One such device that will benefit from these nanowires is organic solar cells. Solar is a clean renewable energy source that can reduce Australia's dependence on fossil fuels. The development of new approaches and materials aimed at increasing solar cell efficiencies is an important outcome for Australia.Read moreRead less
Creation of functional surfaces for biodevices and aerospace applications. Polymers are poised to become the materials of choice for a host of applications because of their lightness, strength, ease of forming and biocompatibility. The major challenge lies in optimising their surfaces for each application. For biodevices in particular, the surfaces must support a range of complex and specific interactions. This project will create new polymer surface modifications through innovations in plasma s ....Creation of functional surfaces for biodevices and aerospace applications. Polymers are poised to become the materials of choice for a host of applications because of their lightness, strength, ease of forming and biocompatibility. The major challenge lies in optimising their surfaces for each application. For biodevices in particular, the surfaces must support a range of complex and specific interactions. This project will create new polymer surface modifications through innovations in plasma science and technology. The outcomes will be new surfaces for diagnostic arrays in medicine, biosensors and durable polymer surfaces for low earth orbit.Read moreRead less
New Surfaces for the Control of Endothelial Cell Function: Application in the Design of Biocompatible Stents. Using dewetting of thin polymer films, the present proposal will develop new structured biocompatible surfaces with controlled chemistry and topography, which will allow the growth of a normal (non-activated) monolayer of endothelial cells. Sophisticated molecular parameters will be used to assess that endothelial cells maintain their normal quiescent phenotype. The project sets the grou ....New Surfaces for the Control of Endothelial Cell Function: Application in the Design of Biocompatible Stents. Using dewetting of thin polymer films, the present proposal will develop new structured biocompatible surfaces with controlled chemistry and topography, which will allow the growth of a normal (non-activated) monolayer of endothelial cells. Sophisticated molecular parameters will be used to assess that endothelial cells maintain their normal quiescent phenotype. The project sets the ground work for the design of improved, more biocompatible structured stents to minimise the abnormal growth of cells on and around the stent, thereby reducing the occurrence of vascular complications. Thus this research could improve the success rate of stents implanted into patients with cardiovascular disease and reduce health costs.Read moreRead less
Soft solids rheology and filled elastomeric networks. Elastomeric networks that have imbedded particles are considerably more difficult to model than unfilled networks because the imbedded particles deform the trajectory of the chains. Any treatment must incorporate this dual nature of the network. Our work will address this important issue with particular reference to two important materials - liquid crystalline elastomers and bread dough. We aim to produce an accurate mathematical description ....Soft solids rheology and filled elastomeric networks. Elastomeric networks that have imbedded particles are considerably more difficult to model than unfilled networks because the imbedded particles deform the trajectory of the chains. Any treatment must incorporate this dual nature of the network. Our work will address this important issue with particular reference to two important materials - liquid crystalline elastomers and bread dough. We aim to produce an accurate mathematical description of filled soft viscoelastic solids, which include compressibility and yielding - two important new features.Read moreRead less
New Types of Biomimetic Nanostructured Adhesives. Adhesives are one of the main ways in which we join materials, and have many advantages over other methods of joining. In this work we will make a new class of adhesive using nanotechnology that attempts to copy the very fine-haired feet of animals such as geckos who can stick to almost any surface, under most conditions. We will make these adhesives over large surface areas, and thus they will have commercial possibilities in a range of high tec ....New Types of Biomimetic Nanostructured Adhesives. Adhesives are one of the main ways in which we join materials, and have many advantages over other methods of joining. In this work we will make a new class of adhesive using nanotechnology that attempts to copy the very fine-haired feet of animals such as geckos who can stick to almost any surface, under most conditions. We will make these adhesives over large surface areas, and thus they will have commercial possibilities in a range of high technology industries, as well as in harsh environments. Because we will be able to manipulate the structure and observe property changes, it should also give us a greater insight into the adhesion mechanisms used by many small animals and bugs.Read moreRead less
Hermetic bonding of biomedical polymers for cardiac-assist devices. The use of a polymeric ventricular assist device will bring a much better quality of life to patients with end-stage heart failure. The project will address the remaining challenge, the creation of a hermetic polymer seal, enabling the development of a small, light and highly efficient heart pump. The project has the potential to improve the lives of many Australians as our demographic profile shifts towards older people. Patie ....Hermetic bonding of biomedical polymers for cardiac-assist devices. The use of a polymeric ventricular assist device will bring a much better quality of life to patients with end-stage heart failure. The project will address the remaining challenge, the creation of a hermetic polymer seal, enabling the development of a small, light and highly efficient heart pump. The project has the potential to improve the lives of many Australians as our demographic profile shifts towards older people. Patients with advanced heart failure will live longer, with a higher quality of life. It will assist heart failure sufferers to remain productive members of our community, because many people who use the device will be fit to return to work.Read moreRead less
Single molecule actuators. The study of actuation processes in single molecules will lead to the development of improved advanced materials for Australian industry and, ultimately, to the more futuristic and exciting nanotechnologies. The research will improve our understanding of how polymer artificial muscles function, so that these materials can be further developed to meet the demand from industry. Applications include biomedical devices, robotic applicators and various machine parts. In ....Single molecule actuators. The study of actuation processes in single molecules will lead to the development of improved advanced materials for Australian industry and, ultimately, to the more futuristic and exciting nanotechnologies. The research will improve our understanding of how polymer artificial muscles function, so that these materials can be further developed to meet the demand from industry. Applications include biomedical devices, robotic applicators and various machine parts. In addition, the research will also contribute to one of the greatest promises of nanotechnology: the development of molecular machines. We will demonstrate the mechanical forces and movements possible from single molecules so that the design of useful nano-machines can begin.Read moreRead less
Novel Drug Delivery Systems. The polymer based structures targeted for production in this project will bring unique capabilities to the field of drug delivery. A multi-drug delivery platform is expected to bring significant improvements in administering therapeutic drugs for a wide range of illnesses and applications. This will have profound effects on the quality of life for those suffering from epilepsy or requiring stent implants. Here we will demonstrate the capabilities of these novel polym ....Novel Drug Delivery Systems. The polymer based structures targeted for production in this project will bring unique capabilities to the field of drug delivery. A multi-drug delivery platform is expected to bring significant improvements in administering therapeutic drugs for a wide range of illnesses and applications. This will have profound effects on the quality of life for those suffering from epilepsy or requiring stent implants. Here we will demonstrate the capabilities of these novel polymer structures both in-vitro and in-vivo.Read moreRead less
Advanced Materials for Stents. The polymer based materials targeted for production in this project will bring unique capabilities to the field of stent design. A multi-component degradable stent system is expected to bring significant improvements in vascular therapeutic treatments for a wide range of illnesses and applications. This will have significant advantages over current treatment and will have a positive impact on the quality of life of patients. The project brings together world leader ....Advanced Materials for Stents. The polymer based materials targeted for production in this project will bring unique capabilities to the field of stent design. A multi-component degradable stent system is expected to bring significant improvements in vascular therapeutic treatments for a wide range of illnesses and applications. This will have significant advantages over current treatment and will have a positive impact on the quality of life of patients. The project brings together world leaders in their respective fields to address a highly multidisciplinary are of research and will provide excellent training for the PhDs and post doctoral research associates, enabling them to work in and contribute to the development of new biomedical industries in Australia.Read moreRead less
Heparan sulfate complexes with VEGF for control of angiogenesis in tissue engineered constructs. The national/community benefits that will arise from this work include, the generation of knowledge related to the growth of blood vessels in the presence of a synthetic polymer that has been made to look like the natural polymers present in the body. This will lead to an understanding of the underlying mechanisms involved that may have down stream effects relevant to the replacement of many types o ....Heparan sulfate complexes with VEGF for control of angiogenesis in tissue engineered constructs. The national/community benefits that will arise from this work include, the generation of knowledge related to the growth of blood vessels in the presence of a synthetic polymer that has been made to look like the natural polymers present in the body. This will lead to an understanding of the underlying mechanisms involved that may have down stream effects relevant to the replacement of many types of tissues being generated for clinical applications, including possible applications in the treatment of heart disease, the largest killer of people in the Western world. Read moreRead less