Biodegradable magnesium alloy scaffolds for bone tissue engineering. This project aims to develop a class of porous, biocompatible, biofunctional and biodegradable magnesium alloy scaffolds with designed pore architecture and mechanical properties mimicking those of natural bone for tissue engineering applications. These magnesium alloy scaffolds will be biocompatible, able to bear loads, and will be gradually replaced by natural bone. The outcomes are expected to benefit the ageing population a ....Biodegradable magnesium alloy scaffolds for bone tissue engineering. This project aims to develop a class of porous, biocompatible, biofunctional and biodegradable magnesium alloy scaffolds with designed pore architecture and mechanical properties mimicking those of natural bone for tissue engineering applications. These magnesium alloy scaffolds will be biocompatible, able to bear loads, and will be gradually replaced by natural bone. The outcomes are expected to benefit the ageing population and people with bone abnormalities.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100012
Funder
Australian Research Council
Funding Amount
$890,000.00
Summary
Dual Column-Focused Ion Beam/Scanning Electron Microscope facility for Queensland. Dual column focused ion beam/scanning electron microscope facility: This facility will precisely cut specimens and surfaces that can be imaged in a variety of ways, including crystallographic and elemental space, of particular use for physical scientists, as well as biological specimens. This instrument will provide information at resolutions between optical and transmission electron microscopy, images that will ....Dual Column-Focused Ion Beam/Scanning Electron Microscope facility for Queensland. Dual column focused ion beam/scanning electron microscope facility: This facility will precisely cut specimens and surfaces that can be imaged in a variety of ways, including crystallographic and elemental space, of particular use for physical scientists, as well as biological specimens. This instrument will provide information at resolutions between optical and transmission electron microscopy, images that will effectively provide the biologist with the ability to develop the complete correlative picture of organelles and cells. The instrument will also provide a much needed resource for researchers across disciplines such as physics, chemistry, biology, geology and engineering.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100139
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
A Hot Isostatic Press (HIP) for aerospace and biomedical component processing. This facility will provide a hot isostatic press of sufficiently large capacity to maximise production efficiencies in aerospace and biomedical applications through net shape manufacturing. The facility will be able to process small components or prototypes which will behave in a manner similar to larger scale components.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100036
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
National in-situ transmission electron microscope facilities. This project will establish six complementary transmission electron microscope (TEM) facilities at various locations. The establishment of the facilities will be a key step in developing advanced capacity in Australia and will support ground-breaking research in diverse material systems for various high-performing applications, including electronics, optoelectronics, light metals, biomaterials, energy, and environment.
Novel manufacturing methods for tissue engineering scaffolds. Novel methods of manufacturing biodegradable polymer scaffolds around which new tissue can be grown within the human body will be developed. Surfactant - polymer assemblies will be used to produce highly porous scaffolds of tunable pore size and connectivity, shape and strength. The results will create a new avenue for systematic investigations into the effects of scaffold structure on tissue growth. This research will lead to the dev ....Novel manufacturing methods for tissue engineering scaffolds. Novel methods of manufacturing biodegradable polymer scaffolds around which new tissue can be grown within the human body will be developed. Surfactant - polymer assemblies will be used to produce highly porous scaffolds of tunable pore size and connectivity, shape and strength. The results will create a new avenue for systematic investigations into the effects of scaffold structure on tissue growth. This research will lead to the development of reliable, well-controlled manufacturing techniques for tissue engineering scaffolds, revolutionising current scaffold manufacturing practices. It will enhance existing collaborations between the University of Melbourne and the Bernard O'Brien Institute of Microsurgery.Read moreRead less
Meso- and Macro-porous Bioactive Glasses for Bone-repairing. This project aims to use self-assembly and pore engineering at different length scales to fabricate novel bioactive glasses of highly ordered mesoporous structure. By precisely controlling the composition, size and volume of both mesopores and macropores, bioactive glasses with improved bone forming activities will be obtained. The successful synthesis of such bioactive glasses is expected to lead to the fundamental understanding of st ....Meso- and Macro-porous Bioactive Glasses for Bone-repairing. This project aims to use self-assembly and pore engineering at different length scales to fabricate novel bioactive glasses of highly ordered mesoporous structure. By precisely controlling the composition, size and volume of both mesopores and macropores, bioactive glasses with improved bone forming activities will be obtained. The successful synthesis of such bioactive glasses is expected to lead to the fundamental understanding of structure-bioactivity relationship, and new materials effective for tissue engineering. This will also open up new opportunities for other applications such as drug delivery, implanting.Read moreRead less
Mimicking the perivascular niche with boronolectin-based biomaterials. This project aims to address roadblocks in perivascular stem cell manufacturing by discovering novel mechanisms and materials that improve cell quality outcomes during extended culture. An innovative, interdisciplinary approach to biomaterials discovery, combining live cell-based screening of cell surface glycans, bio-inspired materials design and synthesis, and niche mimicry, will enable the discovery of cell surface glycan- ....Mimicking the perivascular niche with boronolectin-based biomaterials. This project aims to address roadblocks in perivascular stem cell manufacturing by discovering novel mechanisms and materials that improve cell quality outcomes during extended culture. An innovative, interdisciplinary approach to biomaterials discovery, combining live cell-based screening of cell surface glycans, bio-inspired materials design and synthesis, and niche mimicry, will enable the discovery of cell surface glycan-mediated interactions that support long-term expansion and potency maintenance, and synthetic biomaterials that can mimic them. Significant benefits for stem cell researchers, manufacturers and end users are expected from the project and the application of this scalable biomaterial platform.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668532
Funder
Australian Research Council
Funding Amount
$680,000.00
Summary
A Focussed Ion Beam-Scanning Electron Microscope for Advanced Analytical and Nanotechnology Research in South East Queensland. The minerals industry underpins Australia's current economic prosperity. The aging of the population presents major economic challenges in the delivery of cost effective health services. New nanotechnology-enabled industries will contribute to future national economic and environmental well-being. The research enhanced by this facility impacts all these areas. It will i ....A Focussed Ion Beam-Scanning Electron Microscope for Advanced Analytical and Nanotechnology Research in South East Queensland. The minerals industry underpins Australia's current economic prosperity. The aging of the population presents major economic challenges in the delivery of cost effective health services. New nanotechnology-enabled industries will contribute to future national economic and environmental well-being. The research enhanced by this facility impacts all these areas. It will improve mineral extraction and processing, enhance fundamental understanding of cellular interactions with textured surfaces, and lead to improved implantable material designs and improved implantable device lifetimes (eg hip and knee replacements). Development of advanced nanotechnology applications in energy, optoelectronics and sensors will be also be extended.Read moreRead less
An Integrated Biotechnological Process for Production of Lactic Acid from Carbohydrate-Waste Streams by Rhizopus sp. Lactic acid is the most widely occurring multifunctional organic acid. It has enormous applications in food and food-related industries, and great potential use for production of biodegradable and biocompatible polylactate polymers. The aim of this research is to develop an innovative biotechnological process, incorporating simultaneous saccharification and fermentation, which int ....An Integrated Biotechnological Process for Production of Lactic Acid from Carbohydrate-Waste Streams by Rhizopus sp. Lactic acid is the most widely occurring multifunctional organic acid. It has enormous applications in food and food-related industries, and great potential use for production of biodegradable and biocompatible polylactate polymers. The aim of this research is to develop an innovative biotechnological process, incorporating simultaneous saccharification and fermentation, which integrates the production of lactic acid with the treatment of high strength food industry ?effluent? streams - carbohydrate waste streams. The proposed SSF process will cultivate an identified fungal Rhizopus sp strain on the waste streams, as production substrates, leading to an environmentally friendly and economically sustainable new technology for the food industry.Read moreRead less
Self-assembly of gelling biopolymer particles. Biopolymers provide a renewable source of structuring agents for a variety of potential uses in food, pharmaceutical and other applications that require bio-compatibility. Swollen biopolymer particles of sub-millimetre size are particularly useful as they combine macroscopic structure formation with an ability to flow and a desirable soft solid texture. Two limitations to the current utilisation of biopolymer particles are that they either cannot be ....Self-assembly of gelling biopolymer particles. Biopolymers provide a renewable source of structuring agents for a variety of potential uses in food, pharmaceutical and other applications that require bio-compatibility. Swollen biopolymer particles of sub-millimetre size are particularly useful as they combine macroscopic structure formation with an ability to flow and a desirable soft solid texture. Two limitations to the current utilisation of biopolymer particles are that they either cannot be predictably produced direct from a dried form, or if they are (e.g. cooked starch granules), there is a lack of scientific understanding that limits use of natural sources without subsequent chemical modification. This project will provide the science & technology to overcome these limitations.Read moreRead less