Mechanisms of virus transport in indoor environments. The socio-economic benefits to Australia from the project will include the developed and validated model for quantification of virus spread and survival through aerosolation processes, which will become an important tool for: (i) prediction of the pathways of virus spread in indoor environment, and (ii) developing future directions for management and control for prevention or minimization the likelihood of human infections. The ultimate econo ....Mechanisms of virus transport in indoor environments. The socio-economic benefits to Australia from the project will include the developed and validated model for quantification of virus spread and survival through aerosolation processes, which will become an important tool for: (i) prediction of the pathways of virus spread in indoor environment, and (ii) developing future directions for management and control for prevention or minimization the likelihood of human infections. The ultimate economic benefit of this research will be reduction in health care costs and lost productivity. The research will also place Australia in the forefront of international progress and race towards toward better methods for virus spread prevention. Read moreRead less
The development of a two-colour flow cytometric assay for the detection of whole cell biosensors in environmental samples. Macquarie University and the University of Copenhagen have expertise in fluorescence detection and whole cell biosensors respectively. The project will take advantage of these skills and develop a sensitive assay for monitoring biosensor bacteria in soil. The technology will be significant as it will enable real time analysis of antibiotic production in situ through the de ....The development of a two-colour flow cytometric assay for the detection of whole cell biosensors in environmental samples. Macquarie University and the University of Copenhagen have expertise in fluorescence detection and whole cell biosensors respectively. The project will take advantage of these skills and develop a sensitive assay for monitoring biosensor bacteria in soil. The technology will be significant as it will enable real time analysis of antibiotic production in situ through the detection of GFP expression. This work will then be used to isolate new antibiotic produces and will be extended to research into the bioavailability of toxic compounds and stress. An existing collaboration between the two institutions will be extended enabling the transfer and application of biosensor technology to Australia.Read moreRead less
Investigation of Australian crop species for the rhizoremediation of residual sulfonyl urea herbicide contaminations in agricultural soils. This research aims to identify an environmentally sustainable and economically viable solution to the problem of residual herbicide contaminations in agricultural soils. The strategy is focused on stimulation of microbial degradation of pesticides in the root zone of crop species (Lupins). Such a strategy will improve crop yields and reduce soil contaminatio ....Investigation of Australian crop species for the rhizoremediation of residual sulfonyl urea herbicide contaminations in agricultural soils. This research aims to identify an environmentally sustainable and economically viable solution to the problem of residual herbicide contaminations in agricultural soils. The strategy is focused on stimulation of microbial degradation of pesticides in the root zone of crop species (Lupins). Such a strategy will improve crop yields and reduce soil contaminations and environmental impacts at minimal cost. Read moreRead less
Sodium homeostasis and the molecular basis for neurotoxin production by bacteria and algae. An understanding of the physiology of saxitoxin-producing microorgansims in response to salt stress is critical for the prevention of toxic blooms and for risk assessment of contaminated water bodies. This is nowhere more relevant than in the depleted and increasingly saline water resources of inland Australia. This project will develop genetic tests to assay for saxitoxin-producers and to monitor toxin p ....Sodium homeostasis and the molecular basis for neurotoxin production by bacteria and algae. An understanding of the physiology of saxitoxin-producing microorgansims in response to salt stress is critical for the prevention of toxic blooms and for risk assessment of contaminated water bodies. This is nowhere more relevant than in the depleted and increasingly saline water resources of inland Australia. This project will develop genetic tests to assay for saxitoxin-producers and to monitor toxin production in response to the environment, representing an easier, more economic and ethical alternative to current tests. The market for this type of predictive test includes environmental, anti-bioterrorism and fishery organisations. These genes will also allow the bioengineering of novel therapeutic drugs based on neuroactive alkaloids.Read moreRead less
Determination of factors effecting pathogen removal in lagoons treating and storing effluent for reuse. Waste stabilisation ponds are a preferred treatment option for wastewater in many rural and remote communities within Australia and overseas because of their low-tech, robust structure. Reducing numbers of pathogens in the final treated effluent of these systems so that it can be reused, will minimise risks to the public and the environment and improve management of this sustainable water reso ....Determination of factors effecting pathogen removal in lagoons treating and storing effluent for reuse. Waste stabilisation ponds are a preferred treatment option for wastewater in many rural and remote communities within Australia and overseas because of their low-tech, robust structure. Reducing numbers of pathogens in the final treated effluent of these systems so that it can be reused, will minimise risks to the public and the environment and improve management of this sustainable water resource throughout the region. This research also provides an opportunity for Australia to export knowledge on the efficient use of these systems to 2.4 billion people worldwide currently without access to affordable sanitation.Read moreRead less
The biology, structure and function of bacterial virulence effectors. This project is closely aligned with the National Research Priority of Promoting and Maintaining Good Health and will establish a research framework to investigate novel virulence processes that allow bacterial pathogens to infect humans and cause disease. This fresh approach to the study of bacterial pathogenesis will sit outside classic genetic methods to investigate infection and immunity which rely heavily on genetic manip ....The biology, structure and function of bacterial virulence effectors. This project is closely aligned with the National Research Priority of Promoting and Maintaining Good Health and will establish a research framework to investigate novel virulence processes that allow bacterial pathogens to infect humans and cause disease. This fresh approach to the study of bacterial pathogenesis will sit outside classic genetic methods to investigate infection and immunity which rely heavily on genetic manipulation of the pathogen. Other than providing fundamental information on host-pathogen interactions, this work may lead to novel disease interventions by inhibition of bacterial virulence factor activity and/or enhancement of host inflammatory and immune responses.Read moreRead less
Novel Technology for Improving Disinfection Outcomes in Regional and Remote Drinking Water Distribution Systems. Climate shifts have led to water supply shortages in many areas of Australia, both in rural and remote regions and in cities. To ease water shortages, transportation of water over long distances is becoming increasingly necessary. A major impediment to transfer of water through long mains is management of the disinfectant: most disinfectants decay too rapidly, leaving consumers at ris ....Novel Technology for Improving Disinfection Outcomes in Regional and Remote Drinking Water Distribution Systems. Climate shifts have led to water supply shortages in many areas of Australia, both in rural and remote regions and in cities. To ease water shortages, transportation of water over long distances is becoming increasingly necessary. A major impediment to transfer of water through long mains is management of the disinfectant: most disinfectants decay too rapidly, leaving consumers at risk of pathogen exposure. Chloramination, the most viable disinfection technology for this purpose, suffers from a process called nitrification which accelerates disinfectant decay. In this project, we are developing an innovative, patented process to prevent nitrification, which will allow safe and effective disinfection of water supplies in long pipelines.Read moreRead less