Electric field induced surface attachment and detachment of proteins. Microarrays are revolutionising the diagnosis of disease by enabling large amounts of data on genetics and protein expression to be obtained from one sample. Biosensors for diseases and toxins rely on the same mechanism, namely attachment of biological macromolecules to a surface. We propose a new method for controlling the attachment by micromachining an electrode system to apply an electric field to chosen sites. Ultimately ....Electric field induced surface attachment and detachment of proteins. Microarrays are revolutionising the diagnosis of disease by enabling large amounts of data on genetics and protein expression to be obtained from one sample. Biosensors for diseases and toxins rely on the same mechanism, namely attachment of biological macromolecules to a surface. We propose a new method for controlling the attachment by micromachining an electrode system to apply an electric field to chosen sites. Ultimately microelectronic engineering methods will be used. This will give control over the attachment process with potential benefits of orienting attaching molecules, minimising non-specific attachment and enriching diagnostics by enabling interrogation of the force of attachment.Read moreRead less
Soft carbon nanotube materials. There is no doubt that the realisation of new bionic materials will dramatically improve quality of life for many individuals. The new soft conducting materials proposed will impact on several areas of bionics, including the development of the next generation Bionic Ear, conduits for spinal cord regeneration as well as muscle regeneration and other applications. This project will further enhance the international profile of the ARC Centre of Excellence for Electro ....Soft carbon nanotube materials. There is no doubt that the realisation of new bionic materials will dramatically improve quality of life for many individuals. The new soft conducting materials proposed will impact on several areas of bionics, including the development of the next generation Bionic Ear, conduits for spinal cord regeneration as well as muscle regeneration and other applications. This project will further enhance the international profile of the ARC Centre of Excellence for Electromaterials Science in the field of Bionics. The end-user network already in place will ensure all opportunities are fully exploited.Read moreRead less
Nanostructured Degradable Polymer for Drug Delivery. The success of synthesising nanostructured degradable polymers will position Australia at the world forefront in the field of nanotechnology, bioengineering and healthcare sectors in both fundamental and applied research. This multi-disciplinary research has the potential to generate patentable technologies with economic benefits to Australia. The project also involves fundamental research into surface chemistry, nanostructure, polymer science ....Nanostructured Degradable Polymer for Drug Delivery. The success of synthesising nanostructured degradable polymers will position Australia at the world forefront in the field of nanotechnology, bioengineering and healthcare sectors in both fundamental and applied research. This multi-disciplinary research has the potential to generate patentable technologies with economic benefits to Australia. The project also involves fundamental research into surface chemistry, nanostructure, polymer sciences and will be a meaningful contribution to the advancement of scientific knowledge in Australia. All these will enhance the international competitive profile of Australia in the field of nanotechnology for drug delivery.Read moreRead less
Nanobionics. There is no doubt that the realization of new bionic materials capable of functioning at the cellular through to the mechanical level will dramatically improve quality of life for many individuals. For example, the studies proposed here will impact directly on endothelial and muscle cell growth (important for implants such as stents) and nerve cell regeneration (important for peripheral nerve cell and spinal chord repair). The establishment of the research team proposed within the f ....Nanobionics. There is no doubt that the realization of new bionic materials capable of functioning at the cellular through to the mechanical level will dramatically improve quality of life for many individuals. For example, the studies proposed here will impact directly on endothelial and muscle cell growth (important for implants such as stents) and nerve cell regeneration (important for peripheral nerve cell and spinal chord repair). The establishment of the research team proposed within the framework of the ARC Centre of Excellence in Electromaterials Science builds on world class expertise and infrastructure. The end user network in place will ensure all opportunities are exploited to the full extent.Read moreRead less
Designed Delivery - Novel Hydrogels for Drug Delivery from Precisely-Structured Networks. This project will lead to the development of new biodegradable biomaterials ideally suited to many applications in drug delivery and tissue engineering. The understanding of their properties will be built on comprehensive models for diffusion of molecules through the material. The availability of these new biomaterials will facilitate future developments in drug delivery, and will ultimately lead to improve ....Designed Delivery - Novel Hydrogels for Drug Delivery from Precisely-Structured Networks. This project will lead to the development of new biodegradable biomaterials ideally suited to many applications in drug delivery and tissue engineering. The understanding of their properties will be built on comprehensive models for diffusion of molecules through the material. The availability of these new biomaterials will facilitate future developments in drug delivery, and will ultimately lead to improved medical outcomes in many areas such as tissue and bone regeneration. The materials designed in this project will help position the Australian biotechnology and pharmaceutical industries to take advantage of the more than $100B USD market (US alone; growth ~ 10% p.a.) in drug delivery.Read moreRead less
Biomolecular activity modulated by interaction with nanostructures. Nanotechnological methods are able to reliably fabricate artificial nanostructures with dimensions similar to those of large biomolecules (a few to tens of nanometers). This study focuses on the interaction of artificial nanostructures with biomolecules such as proteins and DNA, and will enable scientists to better understand biomolecular recognition and binding events, which are central to all biological processes. The underst ....Biomolecular activity modulated by interaction with nanostructures. Nanotechnological methods are able to reliably fabricate artificial nanostructures with dimensions similar to those of large biomolecules (a few to tens of nanometers). This study focuses on the interaction of artificial nanostructures with biomolecules such as proteins and DNA, and will enable scientists to better understand biomolecular recognition and binding events, which are central to all biological processes. The understanding gained can then be used to design biomimetic surfaces for use in health monitoring and medical diagnostic devices with improved sensitivity, robustness and portability, thereby providing significant benefits to the health sector.Read moreRead less
Special Research Initiatives - Grant ID: SR0354588
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Integrated Nanoscale Biosystems Network (INBN). The INBN will integrate high-priority research, already identified by the ARC, in materials nanoscience and engineering with nanoscale biology. The INBN will provide the means to consolidate world-class multidisciplinary Australian research groups in existing Centres of Excellence, including several Federation Fellows, into a nanobiotechnology focus. The significant outcomes of INBN are the critical mass of outstanding researchers in the nanobiosci ....Integrated Nanoscale Biosystems Network (INBN). The INBN will integrate high-priority research, already identified by the ARC, in materials nanoscience and engineering with nanoscale biology. The INBN will provide the means to consolidate world-class multidisciplinary Australian research groups in existing Centres of Excellence, including several Federation Fellows, into a nanobiotechnology focus. The significant outcomes of INBN are the critical mass of outstanding researchers in the nanobiosciences, facilitation of innovative research to produce novel intellectual property and provision of pathways into collaborative research with international scientists and industry, and the training and development of the next generation scientists for this emerging discipline.
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Engineering and Assembly of Bioinspired Nanostructured Materials. Scientific and technological advances at the frontiers of nano- and bio-technology are poised to revolutionise healthcare and medicine. This project will involve the design, synthesis and engineering of functional biopolymer building blocks. These 'smart' biopolymers will then be assembled into responsive, nanostructured materials for targeted drug delivery and biosensing applications. These materials are expected to ultimately ha ....Engineering and Assembly of Bioinspired Nanostructured Materials. Scientific and technological advances at the frontiers of nano- and bio-technology are poised to revolutionise healthcare and medicine. This project will involve the design, synthesis and engineering of functional biopolymer building blocks. These 'smart' biopolymers will then be assembled into responsive, nanostructured materials for targeted drug delivery and biosensing applications. These materials are expected to ultimately have health benefits for Australian citizens and contribute to the development of a robust Australian nanobiotechnology industry. The project will also provide excellent opportunities for the development of outstanding young scientists and will foster exciting, multidisciplinary collaborations.Read moreRead less
ARC Centre of Excellence - Australian Centre for Electromaterials Science. The Centre will tackle some of the biggest challenges facing society: those of renewable energy, sustainable industries and enhancing human health. Improvements in all these areas are possible by developing electromaterials with improved efficiency in the generation and transfer of electrical charge. By developing new nano-materials and new theories to explain their behaviour, the Centre will make advances in the areas ....ARC Centre of Excellence - Australian Centre for Electromaterials Science. The Centre will tackle some of the biggest challenges facing society: those of renewable energy, sustainable industries and enhancing human health. Improvements in all these areas are possible by developing electromaterials with improved efficiency in the generation and transfer of electrical charge. By developing new nano-materials and new theories to explain their behaviour, the Centre will make advances in the areas of human health through the regeneration of damaged nerves (eg. in spinal injury) and development of artificial muscles; in renewable energy (plastic solar cells, lightweight batteries and electronic textiles) and in sustainable industries (recovery of precious metals and new corrosion protection technologies).Read moreRead less
New Biomimetic Nanostructured Coatings for Hip Implants. Over 30,000 hip implants operations take place in Australia each year, due largely to a significant and growing proportion of the population suffering from conditions such as osteoporosis. The coating on the implants, required to cause good bone ingrowth and adhesion between bone and implant, is far from perfect. We propose to spray coatings which mimic the structure of bone, and thus offer improved mechanical properties such as appropriat ....New Biomimetic Nanostructured Coatings for Hip Implants. Over 30,000 hip implants operations take place in Australia each year, due largely to a significant and growing proportion of the population suffering from conditions such as osteoporosis. The coating on the implants, required to cause good bone ingrowth and adhesion between bone and implant, is far from perfect. We propose to spray coatings which mimic the structure of bone, and thus offer improved mechanical properties such as appropriate rigidity and toughness, and stimulate better bone growth at the interface. In this way the implant should be much longer lasting and the need for undesirable revision surgery reduced. The processing technique proposed could also be a useful platform coating technology in a number of other industries.Read moreRead less