Heteronuclear parallel imaging and spectroscopy for magnetic resonance. This project will develop novel imaging technology for improved interrogation of biological processes in living tissue. Successful outcomes of this project are expected to contribute significantly to biomedical research efforts, such as improved early detection and treatment of cancer and chronic disease.
Development of improved technologies for high throughput screening of potential disease susceptibility genes. This research is aimed at developing more efficient strategies to identify genes involved in common, human disorders. We aim to develop cost-effective, high throughput approaches for DNA extraction and preparation, accurately determining DNA concentration and quality and for undertaking extensive polymorphism genotyping and analysis. The suitability of equipment, analysis packages and so ....Development of improved technologies for high throughput screening of potential disease susceptibility genes. This research is aimed at developing more efficient strategies to identify genes involved in common, human disorders. We aim to develop cost-effective, high throughput approaches for DNA extraction and preparation, accurately determining DNA concentration and quality and for undertaking extensive polymorphism genotyping and analysis. The suitability of equipment, analysis packages and software, will be assessed and better technologies and packages developed. The study involves collaboration between a research centre with considerable expertise in molecular genetics and Corbett Research, a leader in the field of molecular equipment production. The development of better gene screening technologies has both molecular and commercial significance.Read moreRead less
Optimising vascularisation of tissue engineering chambers for construction of robust tissues. We have produced a device that has commercial application in several fields of basic science, biotechnology and bioengineering. When its full potential is achieved, our innovative organ chamber will strengthen Australia's standing in the biotechnology field and enrich specific applications. The knowledge gained from understanding the growth of blood vessels will benefit several fields including chemical ....Optimising vascularisation of tissue engineering chambers for construction of robust tissues. We have produced a device that has commercial application in several fields of basic science, biotechnology and bioengineering. When its full potential is achieved, our innovative organ chamber will strengthen Australia's standing in the biotechnology field and enrich specific applications. The knowledge gained from understanding the growth of blood vessels will benefit several fields including chemical bioengineering, tissue engineering and repair, polymer chemistry, therapeutics in many areas (like cancer, heart disease, diabetes), hormone manufacture for agricultural, veterinary and medical purposes and cosmetics manufacture. The project will train several post-doctoral fellows and PhD students in this cutting edge field of researchRead moreRead less
Adding a health dimension to integrated automation solutions for intelligent homes. We present a vision for the implementation of intelligent health care technology in the home of the future, focusing on areas of research that have the highest potential payoff over the next ten years for the community, the government and our industry partners. By "intelligent health care technology" we mean smart devices and systems that are aware of their context and can therefore assimilate information to supp ....Adding a health dimension to integrated automation solutions for intelligent homes. We present a vision for the implementation of intelligent health care technology in the home of the future, focusing on areas of research that have the highest potential payoff over the next ten years for the community, the government and our industry partners. By "intelligent health care technology" we mean smart devices and systems that are aware of their context and can therefore assimilate information to support care decisions. We aim to integrate these systems into existing home automation systems designed and marketed by our industrial collaborators. Outcomes will be underpinned by new knowledge acquisition and knowledge based decision systems.Read moreRead less
Engineering Pore Forming Proteins as machines for the delivery of proteins and nanoparticles into cells. This cross disciplinary project will revolutionise our ability to build pore forming nano-machines that specifically deliver complex macromolecules to the cell cytoplasm. The ability to efficiently deliver molecules such as antibodies and nanoparticles to the correct cell population will have enormous therapeutic application. Further, such delivery devices will have revolutionary technologica ....Engineering Pore Forming Proteins as machines for the delivery of proteins and nanoparticles into cells. This cross disciplinary project will revolutionise our ability to build pore forming nano-machines that specifically deliver complex macromolecules to the cell cytoplasm. The ability to efficiently deliver molecules such as antibodies and nanoparticles to the correct cell population will have enormous therapeutic application. Further, such delivery devices will have revolutionary technological potential as commercially relevant research tools.Read moreRead less
A comprehensive framework for interactive home telehealth research. We propose the development of a comprehensive research framework for the next generation of home telecare technology. The framework will support the unattended recording of patient physiological data and allow for patient management and information review by health professionals. It will include knowledge management tools to support clinical decision making. Research will also be conducted into the development of mobile communit ....A comprehensive framework for interactive home telehealth research. We propose the development of a comprehensive research framework for the next generation of home telecare technology. The framework will support the unattended recording of patient physiological data and allow for patient management and information review by health professionals. It will include knowledge management tools to support clinical decision making. Research will also be conducted into the development of mobile community networks and ambulatory monitoring technologies based around Bluetooth piconets.
The long-term outcomes of this research will be improved patient health outcomes in the chronically ill and a decreased overall health care expenditure by reducing hospital admissions.Read moreRead less
Optimising the body's immune response with a Nanopatch that delivers biomolecules to the skin. The team is developing a new improved way to vaccinate against deadly infectious diseases such as influenza and malaria. They believe their Nanopatch technology will boost the power of seasonal influenza vaccination and could even solve vaccine shortages in an influenza pandemic. This is because the Nanopatch needs much less vaccine per person than a conventional syringe. They also predict that vaccine ....Optimising the body's immune response with a Nanopatch that delivers biomolecules to the skin. The team is developing a new improved way to vaccinate against deadly infectious diseases such as influenza and malaria. They believe their Nanopatch technology will boost the power of seasonal influenza vaccination and could even solve vaccine shortages in an influenza pandemic. This is because the Nanopatch needs much less vaccine per person than a conventional syringe. They also predict that vaccines delivered with a Nanopatch will require less refrigeration than conventional vaccines and can be safely administered by individuals without medical training, making the benefits of vaccination accessible to more people more cheaply, even in remote areas.Read moreRead less
Novel Antimicrobial Biomaterials. There is a clear need for new materials that repel bacteria. Infections associated with biomaterials incur a high cost in terms of human health and well being, but such infections also increase the burden on the health care system by extending hospital stays and significantly elevating costs. The cost of a catheter-related blood stream infection is around $50,000 for patients in intensive care units. If all medical devices are considered, the cost of related inf ....Novel Antimicrobial Biomaterials. There is a clear need for new materials that repel bacteria. Infections associated with biomaterials incur a high cost in terms of human health and well being, but such infections also increase the burden on the health care system by extending hospital stays and significantly elevating costs. The cost of a catheter-related blood stream infection is around $50,000 for patients in intensive care units. If all medical devices are considered, the cost of related infections is then approximately $20 billion. The technology proposed here has the potential to reduce biomaterial related infection rates, improve health care and reduce health care costs. Read moreRead less
Development of Cathodic Arc Plasma Immersion Ion Implantation (PIII) for biomaterials applications. Medical prostheses have intricate geometries, consisting of shapes such as screws, holes, wedges, cones and textured surfaces. Plasma Immersion Ion Implantation using metal or carbon ions produced by a cathodic arc has been found to be an excellent process for producing surface modification with the properties required in medical applications, such as low stress and excellent adhesion of very thic ....Development of Cathodic Arc Plasma Immersion Ion Implantation (PIII) for biomaterials applications. Medical prostheses have intricate geometries, consisting of shapes such as screws, holes, wedges, cones and textured surfaces. Plasma Immersion Ion Implantation using metal or carbon ions produced by a cathodic arc has been found to be an excellent process for producing surface modification with the properties required in medical applications, such as low stress and excellent adhesion of very thick coatings. To date this process has only been applied to simple, flat substrates. Extending it to shapes of interest for biomaterials applications will require comprehensive understanding and control of the sheath dynamics, which our combined theoretical and experimental approach will provide.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100175
Funder
Australian Research Council
Funding Amount
$347,070.00
Summary
Three-dimensional additive bio-fabrication facility: printing bioprinters. This project aims to develop bioprinting systems that will provide new insights into fundamental biological processes. The 3D Additive Bio-Fabrication Facility - Printing Bioprinters capability will use 3D polymer and metal additive manufacturing technologies to create the next generation of bioprinting methodologies and 3D fabrication tools. It is the aim that these customised additive manufacturing systems will be used ....Three-dimensional additive bio-fabrication facility: printing bioprinters. This project aims to develop bioprinting systems that will provide new insights into fundamental biological processes. The 3D Additive Bio-Fabrication Facility - Printing Bioprinters capability will use 3D polymer and metal additive manufacturing technologies to create the next generation of bioprinting methodologies and 3D fabrication tools. It is the aim that these customised additive manufacturing systems will be used to produce structures wherein living cells are spatially organised in combination with appropriate biomaterials and bioactive components, such as drugs or growth factors, in order to influence subsequent biological behaviour.Read moreRead less