Building Molecularly Engineered Polymer Nanomaterials. The development of new technologies at the interface between nano- and biotechnology promises to revolutionise healthcare and medicine. This research program will involve the design and synthesis of responsive and programmable polymers and their assembly to form next-generation, engineered materials. The nanomaterials prepared are expected to lead to the development of techniques that enable new types of minimally invasive diagnostics and th ....Building Molecularly Engineered Polymer Nanomaterials. The development of new technologies at the interface between nano- and biotechnology promises to revolutionise healthcare and medicine. This research program will involve the design and synthesis of responsive and programmable polymers and their assembly to form next-generation, engineered materials. The nanomaterials prepared are expected to lead to the development of techniques that enable new types of minimally invasive diagnostics and therapeutics as well as smaller devices. The interdisciplinary research program will cement Australia's position as a leading country in nanobiotechnology research and development.Read moreRead less
Band-Gap Engineered Visible Light Photocatalysts: Enabling Technologies for Sustainable Energy and the Environment. This program will contribute significantly to knowledge advancement in colloid chemistry, nanomaterials and electrochemistry, and is firmly embedded in the National Research Priorities of Frontier Science and an Environmentally Sustainable Australia. In particular, it addresses the goals of water and low emission energy supply. The outcomes of this research will advance a new class ....Band-Gap Engineered Visible Light Photocatalysts: Enabling Technologies for Sustainable Energy and the Environment. This program will contribute significantly to knowledge advancement in colloid chemistry, nanomaterials and electrochemistry, and is firmly embedded in the National Research Priorities of Frontier Science and an Environmentally Sustainable Australia. In particular, it addresses the goals of water and low emission energy supply. The outcomes of this research will advance a new class of visible-light active photocatalysts that underpin the development of hydrogen generation, low cost solar cells and water purification using sunlight. Such technologies will transform the Australian energy and environmental industries and speed up the transition from a fossil fuel economy to a renewable energy economy.Read moreRead less
Energy Conversion and Signal Transduction in Nanomechanical Systems. Miniaturization of materials and electronic devices is an important technological goal. In order to make smaller working devices,we need to understand how to create molecular scale devices such as valves, switches, pumps and motors. This Fellowship will explore ways to make smaller, portable devices that can be used for personal health monitoring,environmental sensing and the detection of disease and pathogens.
Beyond Microarrays: Nano-Scaled Devices for High Throughput Biomolecular Sensing. Current developments in Nanoscience and Nanotechnology hold many promises in terms of revolutionising our industrial base, transforming biology, medical science and practice. This project strives to achieve some of these aims by, for the first time, building and testing nano-scaled devices with the capability to 'read' massive amounts of biological information. With the recent completion of the Human Genome proje ....Beyond Microarrays: Nano-Scaled Devices for High Throughput Biomolecular Sensing. Current developments in Nanoscience and Nanotechnology hold many promises in terms of revolutionising our industrial base, transforming biology, medical science and practice. This project strives to achieve some of these aims by, for the first time, building and testing nano-scaled devices with the capability to 'read' massive amounts of biological information. With the recent completion of the Human Genome project, major opportunities exist to provide spectacular advances in human health care (eg, via personalised medicine) provided that appropriate high-throughput biological reading devices can be developed. In developing such devices, this project also aims to substantially catalyse the Australian Nanotechnology/Biotechnology industry.Read moreRead less
Biologically-Inspired Recognition and Processing in Colloidal Systems. The proposed research will enhance the understanding of forces and adsorption in biologically-inspired synthetic systems, and thereby create new strategies for improving selective adsorption, stabilization, coagulation, and separation. The expected outcomes are: increased understanding of chiral interactions at surfaces, a technique for rapid measurement of surface selectivity, new and better agents for chiral separation, a ....Biologically-Inspired Recognition and Processing in Colloidal Systems. The proposed research will enhance the understanding of forces and adsorption in biologically-inspired synthetic systems, and thereby create new strategies for improving selective adsorption, stabilization, coagulation, and separation. The expected outcomes are: increased understanding of chiral interactions at surfaces, a technique for rapid measurement of surface selectivity, new and better agents for chiral separation, a reduction in the use of organic pollutants, new methods for colloidal processing that will enable the preparation of new materials, and new surface coatings for increasing the useful life-time of medical implants.Read moreRead less
Nanoengineered Colloids and thin films through self-assembly with potential applications in Bioscince and Nanotechnology. The proposed research program will focus on the preparation, characterisation and application of novel, small (nanometer size) particles and thin (micrometer thick)films derived from such particles. These new and advanced materials will be prepared by usinf a recently developed, highly versatile and facile technology to coat particles in solution. The strategy to be used en ....Nanoengineered Colloids and thin films through self-assembly with potential applications in Bioscince and Nanotechnology. The proposed research program will focus on the preparation, characterisation and application of novel, small (nanometer size) particles and thin (micrometer thick)films derived from such particles. These new and advanced materials will be prepared by usinf a recently developed, highly versatile and facile technology to coat particles in solution. The strategy to be used entails the step-by-step construction of well-defined layers of different composition on particles and flat surfaces, thereby allowing unprecendented control over the material properties and function. This will provide new avenues for the application of nanoscale materials in biotechnology and nanotechnology.Read moreRead less
Manipulation of Nano-Scale Assembly, Structure and Interaction: New Drug Delivery Vehicles and Energy Storage Devices for Miniaturised Portable Electronic Products. Nano-scale molecular and surface interactions will be manipulated to develop new nano-structured products. There will be two themes of research activity. In the first theme, newly discovered ionic liquids will be employed to better elucidate the role of hydrophobic interaction in molecular assembly processes. These findings wil ....Manipulation of Nano-Scale Assembly, Structure and Interaction: New Drug Delivery Vehicles and Energy Storage Devices for Miniaturised Portable Electronic Products. Nano-scale molecular and surface interactions will be manipulated to develop new nano-structured products. There will be two themes of research activity. In the first theme, newly discovered ionic liquids will be employed to better elucidate the role of hydrophobic interaction in molecular assembly processes. These findings will assist in the development of surfactant-drug conjugates that can self-assemble and can converge therapeutic, drug delivery and controlled release functions; allowing drugs to be administered in the therapeutic concentration range for prolonged periods of time with reduced side-effects. In the second theme, nano-materials will be used to converge capacitor and battery technologies to provide a dramatic performance boost to miniaturised portable electronic devices.Read moreRead less
Molecular Engineered Nanomaterials for Advanced Fuel Cells. This program aims to develop a new class of proton-conducting materials with high proton-conductivity, low gas permeability and good thermal stability for application to advanced fuel cells. The strategy for such a new material is to exploit the unique properties of nanoscale particles of metal phosphates and silicates, hybridised with proton-conducting polymers. Such new materials will be enabling technology for commercialising both hy ....Molecular Engineered Nanomaterials for Advanced Fuel Cells. This program aims to develop a new class of proton-conducting materials with high proton-conductivity, low gas permeability and good thermal stability for application to advanced fuel cells. The strategy for such a new material is to exploit the unique properties of nanoscale particles of metal phosphates and silicates, hybridised with proton-conducting polymers. Such new materials will be enabling technology for commercialising both hydrogen and methanol fuel cells, promising a revolutionary clean energy supply particularly for transport vehicles and mobile devices. This research advances the material science of nanostructured composite of proton-conducting nanoparticles, a key to high performance fuel cell membranes.Read moreRead less
Molecular control of apoptosis and protein homeostasis. A million cells are produced every second by cell division. At the same time a million cells commit suicide by a process called apoptosis. When cells fail to die when they should they can develop into cancers. In heart attacks, stroke and neurodegenerative diseases, many cells appear to activate their self destruct mechanism to die unnecessarily. Drugs that can cause cancer cells to kill themselves, or drugs that prevent cells dying when th ....Molecular control of apoptosis and protein homeostasis. A million cells are produced every second by cell division. At the same time a million cells commit suicide by a process called apoptosis. When cells fail to die when they should they can develop into cancers. In heart attacks, stroke and neurodegenerative diseases, many cells appear to activate their self destruct mechanism to die unnecessarily. Drugs that can cause cancer cells to kill themselves, or drugs that prevent cells dying when they shouldn't, would make a major impact on many important diseases. Understanding the molecular mechanisms of cell death is the first step towards developing these drugs.Read moreRead less
Genes to phenotype: Exploiting the marsupial model. This research will exploit one of Australia's finest natural resources, its marsupial fauna. The features of marsupial reproduction and development provide a unique opportunity to answer fundamental biological questions. This research will show how the minor differences in key developmental genes that have arisen in their 100 million year isolation give rise to the characteristic differences in developmental timing and reproduction between mar ....Genes to phenotype: Exploiting the marsupial model. This research will exploit one of Australia's finest natural resources, its marsupial fauna. The features of marsupial reproduction and development provide a unique opportunity to answer fundamental biological questions. This research will show how the minor differences in key developmental genes that have arisen in their 100 million year isolation give rise to the characteristic differences in developmental timing and reproduction between marsupials and other mammals. The focus on reproduction and development will also provide invaluable knowledge to underpin efforts to conserve our endangered species and to control those that are overabundant.Read moreRead less