Contribution of Comammox Process to Sustainable Wastewater Treatment. This project aims to understand the versatility, activity and physiological features of comammox bacteria, the newly-discovered complete nitrifiers, in Australian wastewater treatment systems, and to model and evaluate their contributions to biological nitrogen removal process. Nitrogen transformations are crucial microbial processes in the wastewater treatment ecosystems, with nitrification largely responsible for ammonium ox ....Contribution of Comammox Process to Sustainable Wastewater Treatment. This project aims to understand the versatility, activity and physiological features of comammox bacteria, the newly-discovered complete nitrifiers, in Australian wastewater treatment systems, and to model and evaluate their contributions to biological nitrogen removal process. Nitrogen transformations are crucial microbial processes in the wastewater treatment ecosystems, with nitrification largely responsible for ammonium oxidation but comammox previously overlooked. The expected outcomes will develop new knowledge on the comammox process and provide novel insight and technological solution to refine strategies to manipulate nitrification processes for achieving improved biological nitrogen removal and sustainable wastewater management.Read moreRead less
Developing an integrated device for on-farm detection of sugarcane diseases. Pathogenic organisms cause yield losses of more than $150M pa to the Australian sugarcane industry and many millions more worldwide. Partnering with Sugar Research Australia, this project aims to develop a novel on-farm diagnostic device, comprising new nanotechnology and magnetism-induced microfluidics with naked eye observation and electrochemical detection. This device is expected to enable improved disease managemen ....Developing an integrated device for on-farm detection of sugarcane diseases. Pathogenic organisms cause yield losses of more than $150M pa to the Australian sugarcane industry and many millions more worldwide. Partnering with Sugar Research Australia, this project aims to develop a novel on-farm diagnostic device, comprising new nanotechnology and magnetism-induced microfluidics with naked eye observation and electrochemical detection. This device is expected to enable improved disease management strategies through the prediction of potential risks and rapid and effective actions to mitigate impending yield loss. In turn productivity and sustainability of Australia’s sugar industry will be enhanced. The new platform device has great potential for improved disease management in other crops in Australia and globally.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
Engineer enzyme nanoparticles as antibiotic alternatives for agriculture. Antibiotic usage in agriculture contributes to spread of resistant bacteria. Existing antibiotic alternatives to minimize such usage are focused on growth promotion of animals and infection prevention, but lack efficient treatment. This project aims to engineer enzyme nanoparticles, with synergy from multiple enzymes, to confer better antibacterial abilities against livestock pathogens. It will combine protein engineering, ....Engineer enzyme nanoparticles as antibiotic alternatives for agriculture. Antibiotic usage in agriculture contributes to spread of resistant bacteria. Existing antibiotic alternatives to minimize such usage are focused on growth promotion of animals and infection prevention, but lack efficient treatment. This project aims to engineer enzyme nanoparticles, with synergy from multiple enzymes, to confer better antibacterial abilities against livestock pathogens. It will combine protein engineering, nanotechnology and biophysics to develop new enzyme nanoparticles that can be manufactured at low-cost through self-assembly process. The intended outcome is knowledge on molecular engineering of enzyme nanoparticles and innovative agriculture biotechnology for treatment of bacterial infectious diseases in livestock.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