Enhancing biopharmaceuticals: A disruptive bioseparation resin technology. This project aims to develop an innovative and disruptive platform technology for designing and manufacturing tailor-made high-performance bioseparation resins to enhance biopharmaceuticals manufacturing. Bacterial cell factories will be developed to enable biotechnological production of innovative polyester bead-based bioseparation resins, which will revolutionise manufacturing of biopharmaceuticals. Expected outcomes o ....Enhancing biopharmaceuticals: A disruptive bioseparation resin technology. This project aims to develop an innovative and disruptive platform technology for designing and manufacturing tailor-made high-performance bioseparation resins to enhance biopharmaceuticals manufacturing. Bacterial cell factories will be developed to enable biotechnological production of innovative polyester bead-based bioseparation resins, which will revolutionise manufacturing of biopharmaceuticals. Expected outcomes of this project are cost-effective and strongly enhanced approaches for biopharmaceuticals recovery, thereby providing significant benefits to accelerate research and development in early stage discovery and manufacture of biologics, therapeutic proteins and vaccines.Read moreRead less
Accelerating pulse breeding using machine learning. Advances in genomics and high throughput phenotyping are generating vast quantities of data that can be applied for crop improvement, however the lack of computational analysis tools and approaches limits the full exploitation of this data. Pulse legumes are currently under utilised in Australian agriculture due to poor adaptation, however they offer significant benefits both for soil improvement and the production of high protein crops. This p ....Accelerating pulse breeding using machine learning. Advances in genomics and high throughput phenotyping are generating vast quantities of data that can be applied for crop improvement, however the lack of computational analysis tools and approaches limits the full exploitation of this data. Pulse legumes are currently under utilised in Australian agriculture due to poor adaptation, however they offer significant benefits both for soil improvement and the production of high protein crops. This project will develop machine learning (ML) tools for the analysis of pulse legume crop traits and their association with genomic variation to accelerate the breeding of high performance pulse legumes for Australian growers.Read moreRead less
A “Goldilocks” live attenuated poultry vaccine for Infectious Coryza. This project aims to develop a safe and effective vaccine for Infectious Coryza using a live-attenuated vaccine approach. Infectious coryza is an acute respiratory disease of chickens and is caused by the bacterial pathogen, Avibacterium paragallinarum. Infectious Coryza can be controlled by appropriate biosecurity practises and this has been successful in the Australian context to date. However, in the USA, Europe and other e ....A “Goldilocks” live attenuated poultry vaccine for Infectious Coryza. This project aims to develop a safe and effective vaccine for Infectious Coryza using a live-attenuated vaccine approach. Infectious coryza is an acute respiratory disease of chickens and is caused by the bacterial pathogen, Avibacterium paragallinarum. Infectious Coryza can be controlled by appropriate biosecurity practises and this has been successful in the Australian context to date. However, in the USA, Europe and other equatorial regions, infectious Coryza remains an unsolved problem. The expected outcome of this project is a cross-serovar protective vaccine to prevent infectious coryza for use in endemic countries and to act as a biosecurity measure to protect Australia's poultry industry against an incursion of this disease.Read moreRead less
Superior Australian psyllium for functional foods. This project aims to establish a breeding program for Plantago ovata in Australia to provide a reliable supply of high quality, superior psyllium as a key ingredient in the gluten-free food industry, providing benefits to the industrial partner, growers in Australia and consumers. Target traits include better harvest index, reduced seed shattering and identification of lines carrying psyllium with novel properties or whole seeds that can be grou ....Superior Australian psyllium for functional foods. This project aims to establish a breeding program for Plantago ovata in Australia to provide a reliable supply of high quality, superior psyllium as a key ingredient in the gluten-free food industry, providing benefits to the industrial partner, growers in Australia and consumers. Target traits include better harvest index, reduced seed shattering and identification of lines carrying psyllium with novel properties or whole seeds that can be ground and used as flour that imparts less intense colour changes or effects on loaf structure, and which may be highly suitable for other baked gluten-free products. The fundamental knowledge gained from the genetic and biochemical anlayses of these lines will also broadly benefit seed biology research.Read moreRead less
Boosting photosynthetic efficiency using a plant nanobionics approach. The project aims to improve light capture and enhance electron transport rates using a plant nanobionics approach. Biocompatible plasmonic low-dimensional transition metal oxides with unique optical and electronics properties will be selected as the bioinspired materials. The investigation will focus on developing oxide compounds as artificial antenna, capturing extended optical wavelengths that are not normally available to ....Boosting photosynthetic efficiency using a plant nanobionics approach. The project aims to improve light capture and enhance electron transport rates using a plant nanobionics approach. Biocompatible plasmonic low-dimensional transition metal oxides with unique optical and electronics properties will be selected as the bioinspired materials. The investigation will focus on developing oxide compounds as artificial antenna, capturing extended optical wavelengths that are not normally available to natural plants. Energetic hot electrons excited from plasmonic materials injected into the plant system will further be explored, achieving unprecedented energy conversion from solar to chemical. The anticipated findings will provide a strong base to develop new plant systems with improved photosynthetic efficiency.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH190100021
Funder
Australian Research Council
Funding Amount
$4,999,540.00
Summary
ARC Research Hub to Combat Antimicrobial Resistance. The ARC ITRP Research Hub to Combat Antimicrobial Resistance takes on the global challenge of antimicrobial resistance (AMR) for Australia through a world-first partnership between industry, researchers, and end users. The AMR Hub fosters a pre-commercialisation environment to address both social and laboratory-based preclinical challenges to provide a highly integrated diagnostic, pharmaceutical and end user solution to the problem of AMR. A ....ARC Research Hub to Combat Antimicrobial Resistance. The ARC ITRP Research Hub to Combat Antimicrobial Resistance takes on the global challenge of antimicrobial resistance (AMR) for Australia through a world-first partnership between industry, researchers, and end users. The AMR Hub fosters a pre-commercialisation environment to address both social and laboratory-based preclinical challenges to provide a highly integrated diagnostic, pharmaceutical and end user solution to the problem of AMR. A goal of the Hub is to support the development of new molecular diagnostic technology, improve the processes for identifying potential antibiotic compounds and assess and advise on antimicrobial stewardship with a vision to transform social and health outcomes globally.Read moreRead less
Development of electrophoretic cell sorters. The aim of this research is to develop the next generation of cell sorters to scale production of viable sperm and other cell types. Our approach is to understand the factors that control the migration of cells in an electric field so that we can design large-scale devices to purify cells using electrophoretic separation. The outcomes of this research enable large-scale production of viable sperm for human and animal-assisted conception, benefiting in ....Development of electrophoretic cell sorters. The aim of this research is to develop the next generation of cell sorters to scale production of viable sperm and other cell types. Our approach is to understand the factors that control the migration of cells in an electric field so that we can design large-scale devices to purify cells using electrophoretic separation. The outcomes of this research enable large-scale production of viable sperm for human and animal-assisted conception, benefiting infertile couples and the livestock breeding industry. Successful development of an efficient cell separation technology would add significant commercial value to the Australian biomanufacturing sector. Read moreRead less
Toxic metal removal from wastewater sludge. This project aims to efficiently remove toxic metals from wastewater sludge. Sludge management is a problem for water utilities, incurring substantial costs. Land application of wastewater sludge is a sustainable way of sludge management, but toxic metals hinder its long-term repeated application. The project’s chemical-free and energy-positive technology is based on the treatment of wastewater sludge using acidified nitrite. The outcomes will help wat ....Toxic metal removal from wastewater sludge. This project aims to efficiently remove toxic metals from wastewater sludge. Sludge management is a problem for water utilities, incurring substantial costs. Land application of wastewater sludge is a sustainable way of sludge management, but toxic metals hinder its long-term repeated application. The project’s chemical-free and energy-positive technology is based on the treatment of wastewater sludge using acidified nitrite. The outcomes will help water utilities to sustainably manage sludge and could bring large economic, environmental and social benefits to the water utilities.Read moreRead less
The Integrated Bio-economy Project and the Controlled Biosphere. This project aims to develop advanced controlled environment production systems (Controlled Biosphere) that exceed the industry standard for profitability, sustainability and climatic resilience. It will generate new knowledge and innovations in technology integration through a highly multi-disciplinary approach. The project outcomes will yield Techno-Economic and Life-Cycle Analyses, designs of the Controlled Biosphere and support ....The Integrated Bio-economy Project and the Controlled Biosphere. This project aims to develop advanced controlled environment production systems (Controlled Biosphere) that exceed the industry standard for profitability, sustainability and climatic resilience. It will generate new knowledge and innovations in technology integration through a highly multi-disciplinary approach. The project outcomes will yield Techno-Economic and Life-Cycle Analyses, designs of the Controlled Biosphere and supporting policy frameworks. The benefits of this project address worsening resource constraints (e.g. available fresh water, arable land, nutrients); By 2050 we will require 70% more food, and 80% greenhouse gas emissions reductions, to maintain economic, social, political and climate security.Read moreRead less
Novel Propagation and Conservation Technologies for Australian Macadamia. Australia’s $850M macadamia industry is a booming contributor to regional growth with a strong domestic market niche. However the industry is threatened by a severe plant supply bottleneck. Also wild germplasm for breeding is threatened with extinction. This project aims to innovate world-first tissue culture technologies for macadamia propagation and secure cryo-storage of germplasm, aided by cutting edge genomics. Expect ....Novel Propagation and Conservation Technologies for Australian Macadamia. Australia’s $850M macadamia industry is a booming contributor to regional growth with a strong domestic market niche. However the industry is threatened by a severe plant supply bottleneck. Also wild germplasm for breeding is threatened with extinction. This project aims to innovate world-first tissue culture technologies for macadamia propagation and secure cryo-storage of germplasm, aided by cutting edge genomics. Expected outcomes of these new, cross-disciplinary techniques are on-demand supply of superior trees to growers and the protection of invaluable germplasm. This should provide significant benefits for industry growth, food security and conservation de-risked from global change.Read moreRead less