Non-invasive diagnosis using micropatches that sample biomarkers from skin. We are developing a technology called the micropatch that is laid onto the surface of the skin. When the patch is pulled away, it retains proteins found in the subsurface skin layers. We believe that by analysing these proteins we will be able to diagnose diseases like cancer earlier and therefore have a better chance of treating them successfully. The process is painless, and doctors already use it to give drugs and vac ....Non-invasive diagnosis using micropatches that sample biomarkers from skin. We are developing a technology called the micropatch that is laid onto the surface of the skin. When the patch is pulled away, it retains proteins found in the subsurface skin layers. We believe that by analysing these proteins we will be able to diagnose diseases like cancer earlier and therefore have a better chance of treating them successfully. The process is painless, and doctors already use it to give drugs and vaccines. In the future we hope that our technology will be simple enough for routine diagnosis, even in the Outback where doctors are hundreds of kilometres awayRead moreRead less
In-line SPE-CE for the direct determination of drugs and metabolites in biological fluids based on porous polymer monoliths. A new approach is proposed for the development of novel micro- and nano-scale solid-phase adsorbent materials. These materials are based on porous polymer monoliths formed in situ within a capillary acting as a mould. The allows the material to be readily placed in a defined position, in a process similar to photo-patterning, and alleviates many of the problems usually as ....In-line SPE-CE for the direct determination of drugs and metabolites in biological fluids based on porous polymer monoliths. A new approach is proposed for the development of novel micro- and nano-scale solid-phase adsorbent materials. These materials are based on porous polymer monoliths formed in situ within a capillary acting as a mould. The allows the material to be readily placed in a defined position, in a process similar to photo-patterning, and alleviates many of the problems usually associated with fabrication and miniaturisation. A simple photo-grafting process, initiated by UV light can be used for the selective chemical modification of these materials. These tailored monoliths can then be used for the in-line coupling of biological sample handling and capillary electrophoresis (CE) for the determination of drugs and related metabolites in biological fluids, thus avoiding time-consuming and costly off-line sample pre-treatment. This will lead to the development of new methods for the rapid determination of drugs, metabolites and other small molecules in clinical samples.Read moreRead less
Multimodal biomedical imaging probes: development of advanced polymer nanocomposite devices for oncology. Despite significant research being directed toward cancer treatment, 7.6 million people died world wide in 2007. Early detection and treatment is widely recognised as being effective in significantly reducing mortality rates. Biomedical imaging techniques are routinely used for detection and staging of many cancers. However, greater sensitivity is required so that these techniques can be app ....Multimodal biomedical imaging probes: development of advanced polymer nanocomposite devices for oncology. Despite significant research being directed toward cancer treatment, 7.6 million people died world wide in 2007. Early detection and treatment is widely recognised as being effective in significantly reducing mortality rates. Biomedical imaging techniques are routinely used for detection and staging of many cancers. However, greater sensitivity is required so that these techniques can be applied to very early detection of tumours. To overcome this short-coming the next generation of imaging probes will be developed, which will require fundamental investigations in polymer and nanomaterials science to maximise imaging sensitivity and extend probe functionality. Successful outcomes will lead to significant benefits to healthcare in Australia.Read moreRead less
An investigation of growth processes, structure and properties of biogenically synthesised gold nanoparticles. Nanoparticles can have unique and interesting properties such as optical activity and redox (electronic) behaviour that can be utilised in a number of applications such as drug delivery and cancer hyperthermia treatments, coatings, electronic devices and sensors. The main aims of this research program are to produce novel nanoparticles using an innovative method which uses biological sp ....An investigation of growth processes, structure and properties of biogenically synthesised gold nanoparticles. Nanoparticles can have unique and interesting properties such as optical activity and redox (electronic) behaviour that can be utilised in a number of applications such as drug delivery and cancer hyperthermia treatments, coatings, electronic devices and sensors. The main aims of this research program are to produce novel nanoparticles using an innovative method which uses biological species such as fungi and plant extracts, and to study the growth mechanisms, structure and properties of these nanoparticles. These studies could lead to the discovery of novel nanoparticles with applications in the fields mentioned above. This project also aims to train/educate young Australian graduates in the growing area of advanced materials.Read moreRead less
Bioanalytical Microchips Based on Integrated, Application Tailored Monolithic Modules. Microfluidic devices offer substantial advantages over current technology, in terms of speed, cost of analysis, portability, operator simplicity and safety. Integrating multiple analytical processes within a simple and reliable portable device will lead to application in a range of areas, from pharmacology to therapeutic drug monitoring, proteomic and metabolomic screening for disease diagnosis and drug develo ....Bioanalytical Microchips Based on Integrated, Application Tailored Monolithic Modules. Microfluidic devices offer substantial advantages over current technology, in terms of speed, cost of analysis, portability, operator simplicity and safety. Integrating multiple analytical processes within a simple and reliable portable device will lead to application in a range of areas, from pharmacology to therapeutic drug monitoring, proteomic and metabolomic screening for disease diagnosis and drug development, and also for performing clinical diagnostics in a rural area. This will significantly impact on the quality of life of the Nation as a whole, not only due to expedient diagnosis and treatment which has obvious health benefits, but also in the considerable financial benefits that result from early and efficient treatment. Read moreRead less
Advanced nanoparticle stabilisation and functionalisation: small particles with huge potential. Australia is strongly investing in nanotechnology and through the governments priority goals 'Frontier Technologies for Building and Transforming Australian Industries' it has been recognised as an important area for investment. This proposal will help develop an internationally recognised nano-industry. It is envisaged that the particles made during this work will have direct implications for the pub ....Advanced nanoparticle stabilisation and functionalisation: small particles with huge potential. Australia is strongly investing in nanotechnology and through the governments priority goals 'Frontier Technologies for Building and Transforming Australian Industries' it has been recognised as an important area for investment. This proposal will help develop an internationally recognised nano-industry. It is envisaged that the particles made during this work will have direct implications for the public - creating a new class of medical diagnostic particles with better resolution and specificity. These particles have the potential to diagnose patients more precisely and at an earlier stage than is currently available. Additionally, these particles could be designed to load drugs and hence could be used to treat diseases such as cancer.Read moreRead less
Nanoscale Coating and Biomodification of Colloids for Biological Applications. The research entails the preparation of novel biofunctional colloids of nanometer to micrometer dimensions and their utilisation in biological applications. Self-assembly processes will be exploited to achieve nanoscale biomodification of technologically important colloid particles, including latex beads and rare earth and semiconductor nanoparticles. The studies conducted will generate fundamental knowledge pertainin ....Nanoscale Coating and Biomodification of Colloids for Biological Applications. The research entails the preparation of novel biofunctional colloids of nanometer to micrometer dimensions and their utilisation in biological applications. Self-assembly processes will be exploited to achieve nanoscale biomodification of technologically important colloid particles, including latex beads and rare earth and semiconductor nanoparticles. The studies conducted will generate fundamental knowledge pertaining to the underlying factors that govern the formation of biofunctional colloid particles through self-assembly. This is essential for the development of tailored colloids that will meet the demands placed on nanomaterials synthesis and performance by nanotechnology. The colloids prepared will find new applications in medicine, biocatalysis and bioassays.Read moreRead less
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
Development of non-iodinated, non ionic, water-soluble metal based compounds for clinical administration as radiographic contrast media. Every year Australia spends more than $50 million on importing radiographic contrast media, in an international market worth more than $1 billion pa. Existing iodine based agents, which currently cause major adverse reactions in 1% of the population, could be replaced by new metal based imaging media which provide both enhanced contrast and greater patient safe ....Development of non-iodinated, non ionic, water-soluble metal based compounds for clinical administration as radiographic contrast media. Every year Australia spends more than $50 million on importing radiographic contrast media, in an international market worth more than $1 billion pa. Existing iodine based agents, which currently cause major adverse reactions in 1% of the population, could be replaced by new metal based imaging media which provide both enhanced contrast and greater patient safety and comfort. Even a small fraction of the international market would generate millions of dollars in overseas income from a range of potential sources, including licensing/royalties to export by a local start-up company, and expansion of rare earth mining in Australia.Read moreRead less
Understanding Electron Transfer through Surface Bound Rigid Molecular Constructs: From Fundamental Studies to New Sensing and Photovoltaic Applications. Electron transfer is not only a vital process in biological systems but is the cornerstone of the new generation of nanoscale devices such as molecular electronics, photovoltaic devices and biosensors. For most applications electron transfer occurs close to a surface but the influence of the surface is not well understood. This project aims ....Understanding Electron Transfer through Surface Bound Rigid Molecular Constructs: From Fundamental Studies to New Sensing and Photovoltaic Applications. Electron transfer is not only a vital process in biological systems but is the cornerstone of the new generation of nanoscale devices such as molecular electronics, photovoltaic devices and biosensors. For most applications electron transfer occurs close to a surface but the influence of the surface is not well understood. This project aims to increase our understanding of the role of surfaces on the electron transfer behaviour using a novel range of rigid 'molecular wires'. The knowledge gained will be exploited in the development of novel biosensors for environmental and health monitoring and new highly efficient solar cells for energy conversion.Read moreRead less