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Nanoparticles to combat cellular dysfunction. This project aims to design, synthesise and characterise nanoparticles that can mediate the adverse effects of reactive oxygen species. The project expects to develop nanoparticles with tailored chemical functionality to modulate the concentration of reactive oxygen species and develop a platform technology for addressing conditions where reactive species are overproduced. The project will research how nanoparticles’ physicochemical properties affect ....Nanoparticles to combat cellular dysfunction. This project aims to design, synthesise and characterise nanoparticles that can mediate the adverse effects of reactive oxygen species. The project expects to develop nanoparticles with tailored chemical functionality to modulate the concentration of reactive oxygen species and develop a platform technology for addressing conditions where reactive species are overproduced. The project will research how nanoparticles’ physicochemical properties affect their activity, and how they affect cellular function, tissue morphology and particle transport in a biological milieu. The project is expected to benefit the advanced manufacturing, veterinary and medical sectors and could lead to new chemotherapeutics.Read moreRead less
Engineering layered double hydroxide nanoparticles toward an efficient targeted clinical delivery system. This project will develop a more effective drug delivery system using clay nanoparticles and biofriendly serum proteins. Outcomes from this project will provide a tremendous opportunity for potent therapies of cancers, vasculature and neuronal diseases, and place Australia at the forefront of nanotechnology drug delivery research.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100121
Funder
Australian Research Council
Funding Amount
$270,000.00
Summary
An integrated system for characterisation of mechanical behaviour of bio- and nanomaterials at micro and nano scales in Queensland. Australia's material sciences will benefit from a new integrated system capable of microforce and nanomechanical testing of biomaterials, polymers and thin films, medical devices and electronics at the micro and nano scales. This facility will support ground-breaking research. It will help promote strategic collaboration and ensure the competitiveness of related and ....An integrated system for characterisation of mechanical behaviour of bio- and nanomaterials at micro and nano scales in Queensland. Australia's material sciences will benefit from a new integrated system capable of microforce and nanomechanical testing of biomaterials, polymers and thin films, medical devices and electronics at the micro and nano scales. This facility will support ground-breaking research. It will help promote strategic collaboration and ensure the competitiveness of related and emerging industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100168
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
Facility for Characterisation of BioNanomaterials. Facility for characterisation of bionanomaterials:
The facility for characterisation of bionanomaterials aims to provide researchers with access to an integrated facility for advanced characterisation of nanomaterials from inception to application in biomedicine. Nanotechnology has contributed to significant advances across a range of disciplines and is increasingly used in biomedical applications. The facility aims to allow detailed examinatio ....Facility for Characterisation of BioNanomaterials. Facility for characterisation of bionanomaterials:
The facility for characterisation of bionanomaterials aims to provide researchers with access to an integrated facility for advanced characterisation of nanomaterials from inception to application in biomedicine. Nanotechnology has contributed to significant advances across a range of disciplines and is increasingly used in biomedical applications. The facility aims to allow detailed examination of how nanomaterials interact in biological systems; from individual nanoparticles to whole animals, and through developing this fundamental understanding provide the means to produce new and highly effective nanomaterials for biomedical applications. The facility plans to support programs using nanomaterials for molecular imaging and intelligent drug delivery, while developing greater understanding of how to create more effective nanobiomaterials.Read moreRead less
Bioengineering self-assembly of innovative core-shell nanomaterials . This project aims to generate new knowledge in nanoscale bioengineering. It expects to develop a disruptive platform technology for design and manufacture of advanced nanomaterials to provide solutions for unmet needs in industry. It will explore an innovative bioengineering concept that merges biopolymer synthesis with virus-like particle self-assembly to produce innovative tunable core-shell nanomaterials. Expected outcomes ....Bioengineering self-assembly of innovative core-shell nanomaterials . This project aims to generate new knowledge in nanoscale bioengineering. It expects to develop a disruptive platform technology for design and manufacture of advanced nanomaterials to provide solutions for unmet needs in industry. It will explore an innovative bioengineering concept that merges biopolymer synthesis with virus-like particle self-assembly to produce innovative tunable core-shell nanomaterials. Expected outcomes are the development of advanced techniques for design and manufacture of innovate nanomaterials with enhanced stability and performance. This innovative platform technology for precision engineering of high-performance nanomaterials should provide significant benefits for biotechnological and agricultural industries.Read moreRead less
Capturing full-spectrum of solar energy using TiO2 ordered suprastructures. The project aims to develop a titanium dioxide (TiO2) semiconductor that can use full-spectrum solar energy. Solar-driven photocatalytic processes have important applications in water decontamination and energy production. Their effectiveness is dictated by the semiconductor’s absorbance and conversion of photoenergy to chemical energy. Being inexpensive, chemically and mechanically robust, TiO2 is the most promising mat ....Capturing full-spectrum of solar energy using TiO2 ordered suprastructures. The project aims to develop a titanium dioxide (TiO2) semiconductor that can use full-spectrum solar energy. Solar-driven photocatalytic processes have important applications in water decontamination and energy production. Their effectiveness is dictated by the semiconductor’s absorbance and conversion of photoenergy to chemical energy. Being inexpensive, chemically and mechanically robust, TiO2 is the most promising material for the semiconductor. However, unmodified TiO2 only absorbs ultraviolet light (5 per cent of solar energy). With current progress made in visible absorbance, this project aims to significantly improve TiO2’s absorbance in near infrared by doping with upconversion lanthanides and rendering colloidal crystal suprastructures that can trap light.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100156
Funder
Australian Research Council
Funding Amount
$289,500.00
Summary
3D Two-Photon Nanoprinter for Advanced Multi-Functional Materials & Devices. The Nanoscribe Photonic Professional GT2 Two-Photon 3D Printer enables tailoring materials’ architecture at nanoscale. This results in unique optical, mechanical, electrical, chemical, biochemical, and acoustic properties enabling a wealth of cutting-edge research activities in variety of fields including mechanical/optical/electrical metamaterials, bioinspired hard/soft materials, biomaterials (e.g., structured cell-ti ....3D Two-Photon Nanoprinter for Advanced Multi-Functional Materials & Devices. The Nanoscribe Photonic Professional GT2 Two-Photon 3D Printer enables tailoring materials’ architecture at nanoscale. This results in unique optical, mechanical, electrical, chemical, biochemical, and acoustic properties enabling a wealth of cutting-edge research activities in variety of fields including mechanical/optical/electrical metamaterials, bioinspired hard/soft materials, biomaterials (e.g., structured cell-tissue interfaces), biomedical devices (implantable devices and drug-delivery systems), nanofluidics, and photonic crystals. In each of these fields, we will use GT2 to print variety of polymers, hydrogels, metals and ceramics, for example by printing polymer-derived nanoceramics that will be simultaneously strong and tough.Read moreRead less
Bespoke nanomaterials for understanding nano-bio interactions under flow. This project aims to develop innovative scalable synthesis techniques to produce polymeric nanomaterials with controlled properties and characterise interactions between nanomaterials and cells under flow conditions. This project expects to generate new knowledge in priority research areas of nanotechnology, polymer chemistry and immunology. The outcome of this project is an original scalable and environmentally friendly t ....Bespoke nanomaterials for understanding nano-bio interactions under flow. This project aims to develop innovative scalable synthesis techniques to produce polymeric nanomaterials with controlled properties and characterise interactions between nanomaterials and cells under flow conditions. This project expects to generate new knowledge in priority research areas of nanotechnology, polymer chemistry and immunology. The outcome of this project is an original scalable and environmentally friendly technology, new knowledge of cell-nanomaterial interactions and new design principles for nanoparticles with potential future applications in drug delivery, immunology and nanomedicine. This project should provide significant benefits to polymer, nanomaterial and pharmaceutical research and industry in Australia.Read moreRead less
Platform technologies for multifunctional nanocarrier systems. Smart targeted nanocarriers offer new opportunities for drug delivery. This project aims to develop new platforms for reproducibly producing and screening targeted nanocarriers. The platform technologies developed in this project aim to revolutionise current strategies for designing and evaluating drug delivery systems, and will accelerate the clinical translation of targeted drug delivery. This will include a novel one-step microflu ....Platform technologies for multifunctional nanocarrier systems. Smart targeted nanocarriers offer new opportunities for drug delivery. This project aims to develop new platforms for reproducibly producing and screening targeted nanocarriers. The platform technologies developed in this project aim to revolutionise current strategies for designing and evaluating drug delivery systems, and will accelerate the clinical translation of targeted drug delivery. This will include a novel one-step microfluidic platform technology for reproducibly producing targeted polymer nanocarriers having systematically varied properties, a dual-templating method for making targeted silica nanocapsules and new design of in vivo-mimicking 'Tissue Chips' for screening and evaluating the nanocarriers.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100051
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
An advanced X-ray facility for surface and in-situ materials characterization. An advanced X-ray facility for surface and in-situ materials characterisation: Materials properties are crucial to the performance of devices and structures, and detailed characterisation at a molecular level is important for optimizing new materials. X-rays are a powerful means of achieving the required level of detail in structural characterisation. The aim of this project is to make available an extremely bright X- ....An advanced X-ray facility for surface and in-situ materials characterization. An advanced X-ray facility for surface and in-situ materials characterisation: Materials properties are crucial to the performance of devices and structures, and detailed characterisation at a molecular level is important for optimizing new materials. X-rays are a powerful means of achieving the required level of detail in structural characterisation. The aim of this project is to make available an extremely bright X-ray source with a suite of advanced analytical tools, including surface structural analysis by reflectometry and grazing incidence diffraction and materials structure determination using powder diffraction and microdiffraction at high and low temperatures. The functions of this facility are broad and its applications include materials science, organic electronics, biomaterials and engineering.Read moreRead less