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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
Miniaturised biosensors with high selectivity . This project aims to develop a technological platform for the fabrication of miniaturised and flexible sensors that enable the quantitative detection of important bioactive compounds such as fatty acids and biogenic amines. By utilising multi-enzymatic reactions in solid phase and engineering task-specific inks, chemiresistive sensors will be printed seamlessly as a whole. The sensors will respond to complex target biomolecules via a series of enzy ....Miniaturised biosensors with high selectivity . This project aims to develop a technological platform for the fabrication of miniaturised and flexible sensors that enable the quantitative detection of important bioactive compounds such as fatty acids and biogenic amines. By utilising multi-enzymatic reactions in solid phase and engineering task-specific inks, chemiresistive sensors will be printed seamlessly as a whole. The sensors will respond to complex target biomolecules via a series of enzymatic reactions through which the analyte will convert to much simpler, reactive and hence measurable molecules. This project will enable to design miniaturised sensors for point-of-care detection of biomolecules that cannot be yet evaluated by the end users.Read moreRead less
Star Polymers As Novel Antimicrobial And Immunomodulatory Agents
Funder
National Health and Medical Research Council
Funding Amount
$945,908.00
Summary
The rise in antibiotic resistance in bacteria is considered as a major public health threat that is not being met by antibiotic research. This project will modify a novel star polymer that we have shown kills antibiotic resistant bacteria but does not induce resistance. The project will make and characterise new versions of the star polymer to produce antimicrobial materials that target and kill the multi-drug resistant bacteria that are a major cause of bacterial infections and death.
Clean technologies for the synthesis and purification of a biohybrid and biodegradable polymer. The project aims to transform an Australian industry in the forefront of the global market for manufacturing biodegradable polymers and boost export earnings derived from CO2 based biohybrid polymers. The project will develop cost-effective and clean methods for processing CO2 based polymers and demonstrate its potential for packaging and biomedical applications.
Functional drug-releasing polymer nano-composites for preventing medical device infection and encrustation. By developing new methodologies for producing functional biomaterials, this research will benefit Australia by continuing our high profile in this research field and by producing economic benefits arising from development and export of materials technologies to the major user groups in USA and Europe. With our demonstrated linkages with Australian based biomaterials developers at CSIRO an ....Functional drug-releasing polymer nano-composites for preventing medical device infection and encrustation. By developing new methodologies for producing functional biomaterials, this research will benefit Australia by continuing our high profile in this research field and by producing economic benefits arising from development and export of materials technologies to the major user groups in USA and Europe. With our demonstrated linkages with Australian based biomaterials developers at CSIRO and University of Queensland, as well as with companies involved in the commercialisation of polyurethane based medical devices (Aortech P/L), this group is well placed to continue the research at a more applied level once the early basic stage is complete.Read moreRead less
Guided droplet deposition: Microfabrication of advanced materials. The progress of micro and nanofabrication is opening an array of new opportunities with a new degree of freedom for manufacturing. This process will complement the existing micromanufacturing facilities in Melbourne. While metal printing and deposition of polymers is presently available, the guided droplet deposition will extend current capabilities to include ceramics and high melting temperature metals. Direct application to me ....Guided droplet deposition: Microfabrication of advanced materials. The progress of micro and nanofabrication is opening an array of new opportunities with a new degree of freedom for manufacturing. This process will complement the existing micromanufacturing facilities in Melbourne. While metal printing and deposition of polymers is presently available, the guided droplet deposition will extend current capabilities to include ceramics and high melting temperature metals. Direct application to medical devices will provide a more effective surface for improved performance and allow the incorporation of smart and sensor materials for multifunctional devices. 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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883056
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Vacuum Ultraviolet Spectrophotometer and Rapid Photoluminescence Mapping System for Development of Advanced Materials and Biosystems. Australia's energy and renewable energy, defence, biosystem and pharmaceutical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economy's strength. Future progress of these industries is expected to be largely driven by advances in materials and biosystems. The installation of the p ....Vacuum Ultraviolet Spectrophotometer and Rapid Photoluminescence Mapping System for Development of Advanced Materials and Biosystems. Australia's energy and renewable energy, defence, biosystem and pharmaceutical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economy's strength. Future progress of these industries is expected to be largely driven by advances in materials and biosystems. The installation of the proposed facilities will add a new dimension to high-level research performance and significantly enhance the capability for characterization of various forms of materials and biosystems in Australia. The continual development of advanced material and biosystem technology will potentially provide a sustainable means for meeting the increasing global challenge for the industries.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
Failure of Complex Biomechanical Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate dental crown structures. We are now at a critical point in the understanding of how these structures fail, and are beginning to make substantive predictions to improve des ....Failure of Complex Biomechanical Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate dental crown structures. We are now at a critical point in the understanding of how these structures fail, and are beginning to make substantive predictions to improve designs for prolonged life. The project is connected to the dental community and international crown material manufacturers through a broader NIH project in the USA. The improved materials and crown designs resulting from this project will have impact worldwide, including Australia.Read moreRead less