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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Probing the function of protein molecular motors on nano-fabricated structures. The function of protein linear molecular motors, which are natural dynamic bio-nano-devices with a ubiquitous importance in multicellular organisms, will be 'probed' with purposefully designed nano-structures fabricated via photo- or Scanning Probe Microscopy Lithography, that is, flat polymeric surfaces with combinatorial combinations of physico-chemistries; and micro/nano-channels and nano-wells with critical dimen ....Probing the function of protein molecular motors on nano-fabricated structures. The function of protein linear molecular motors, which are natural dynamic bio-nano-devices with a ubiquitous importance in multicellular organisms, will be 'probed' with purposefully designed nano-structures fabricated via photo- or Scanning Probe Microscopy Lithography, that is, flat polymeric surfaces with combinatorial combinations of physico-chemistries; and micro/nano-channels and nano-wells with critical dimensions similar to the scale of the probed biomolecules. The project turns 'up-side down' the challenge of invasive nano-probing of biomolecules using it in an engineered manner. The fundamental understanding of linear molecular motors will impact on biomedical science and on the assessment of hybrid natural-artificial dynamic nano-devices.Read moreRead less
Exploiting the self-assembly of hydrophobin proteins to engineer functional nanostructuring surfaces. There is an increasing world-wide demand for advanced nano-biomaterials with novel properties. We will use natural hydrophobin proteins to coat nanodevices and make them more compatible with biological systems. Hydrophobin coatings will be applicable to biosensors, medical devices, diagnostics and drug delivery systems. The research will lead to an understanding of the basic mechanisms of protei ....Exploiting the self-assembly of hydrophobin proteins to engineer functional nanostructuring surfaces. There is an increasing world-wide demand for advanced nano-biomaterials with novel properties. We will use natural hydrophobin proteins to coat nanodevices and make them more compatible with biological systems. Hydrophobin coatings will be applicable to biosensors, medical devices, diagnostics and drug delivery systems. The research will lead to an understanding of the basic mechanisms of protein self-assembly and will have application outcomes that contribute to Australia being an important player in the field of nanotechnology. This is critical for Australia's long term competitiveness and productivity in and beyond the 21st century.Read moreRead less
Opto-Microfluidics: A Rapid and Sensitive Platform for Biological Diagnostics. One in four people above 25 years suffer from diabetes-related diseases in Australia, with an associated economic cost exceeding $3 billion a year. A microdevice for continuous glucose monitoring would help patients to manage the disease, leading to huge individual, clinical and societal benefits. Life expectancy is expected to increase along with quality of life. Integration of the microdevice with insulin delivery w ....Opto-Microfluidics: A Rapid and Sensitive Platform for Biological Diagnostics. One in four people above 25 years suffer from diabetes-related diseases in Australia, with an associated economic cost exceeding $3 billion a year. A microdevice for continuous glucose monitoring would help patients to manage the disease, leading to huge individual, clinical and societal benefits. Life expectancy is expected to increase along with quality of life. Integration of the microdevice with insulin delivery would realise an 'artificial pancreas', revolutionising the management and treatment of the disease. The technology will also provide a platform for other point-of-care medical diagnostic devices, which will allow early participation in this emerging market and cement Australia's position in bionanotechnology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989341
Funder
Australian Research Council
Funding Amount
$690,000.00
Summary
Advanced NanoBiomaterials Imaging Facility. The convergence of nanotechnology with biotechnology offers unprecedented opportunities to prepare nanomaterials with defined structure and function on the nanometre scale. However, the small length scales involved in nanomaterials present challenges in their characterisation, and in turn, their interaction with biological systems. The Advanced NanoBiomaterials Imaging Facility will provide state-of-the-art equipment for examining the properties of nan ....Advanced NanoBiomaterials Imaging Facility. The convergence of nanotechnology with biotechnology offers unprecedented opportunities to prepare nanomaterials with defined structure and function on the nanometre scale. However, the small length scales involved in nanomaterials present challenges in their characterisation, and in turn, their interaction with biological systems. The Advanced NanoBiomaterials Imaging Facility will provide state-of-the-art equipment for examining the properties of nanomaterials and their interaction with biosystems. The equipment will facilitate the development of new materials that are expected to underpin advances in drug delivery, diagnostics and implant devices, further strengthening Australia's strong reputation in these areas.Read moreRead less
Simulating two-phase electrodynamic flows in droplet-based microfluidic circuit elements. The knowledge, data and analysis tools developed within this project will facilitate the economical production of electrodynamically controlled integrated droplet-based microfluidic devices for critical high-demand applications such as: genome sequencing; protein evolution, synthesis and crystallisation; micro-structured pharmaceuticals; disposable devices for biomedical analysis; portable point-of-entry (b ....Simulating two-phase electrodynamic flows in droplet-based microfluidic circuit elements. The knowledge, data and analysis tools developed within this project will facilitate the economical production of electrodynamically controlled integrated droplet-based microfluidic devices for critical high-demand applications such as: genome sequencing; protein evolution, synthesis and crystallisation; micro-structured pharmaceuticals; disposable devices for biomedical analysis; portable point-of-entry (biochem)security analysis devices. Hence this project is an investment in enabling technologies to benefit Australia's growing biotech, pharmaceutical and micro/nanotechnology sectors. Tangible community benefits (e.g., in improved diagnostic technologies, pharmaceuticals) will result.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775612
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Nanomaterials Optical Characterisation Facility. Nanotechnology is expected to revolutionize a wide variety of fields, from medicine to agriculture, communications and electronics. However, the small length scales involved present significant challenges with regard to characterising the nanomaterials produced. The Nanomaterials Optical Characterisation facility will provide state-of-the-art equipment for examining the properties of nanomaterials. The equipment will be pivotal in assisting the de ....Nanomaterials Optical Characterisation Facility. Nanotechnology is expected to revolutionize a wide variety of fields, from medicine to agriculture, communications and electronics. However, the small length scales involved present significant challenges with regard to characterising the nanomaterials produced. The Nanomaterials Optical Characterisation facility will provide state-of-the-art equipment for examining the properties of nanomaterials. The equipment will be pivotal in assisting the development of next-generation medicines, implants, optical devices and surface coatings, further strengthening Australia's formidable reputation in these areas.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989471
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Facility for innovation in structural biomaterials engineering. Biomaterials are used in a diverse range of environments that impact on the way that all Australians live. The Facility for Innovation in Structural Biomaterials Engineering will greatly assist researchers to undertake cross-disciplinary projects aimed at improving human health eg. smart materials that assist stem cell therapies for treating deafness and spinal cord injuries, as well the way we live eg. more durable building materia ....Facility for innovation in structural biomaterials engineering. Biomaterials are used in a diverse range of environments that impact on the way that all Australians live. The Facility for Innovation in Structural Biomaterials Engineering will greatly assist researchers to undertake cross-disciplinary projects aimed at improving human health eg. smart materials that assist stem cell therapies for treating deafness and spinal cord injuries, as well the way we live eg. more durable building materials for a sustainable national infrastructure. The facility will help Australia remain at the forefront of these high priority areas and see both individuals and industry benefit from advanced biomaterial products.Read moreRead less