Detection and viability of waterborne pathogens using a gut-on-chip. This project aims to resolve a significant problem for water utilities. Microbial pathogens Cryptosporidium, norovirus and adenovirus are the main public health concern for drinking water in developed nations. Water monitoring is limited by the lack of fast, reliable detection methods and viability assays for these pathogens. This project will use a novel gut-on-a-chip to develop for the first time rapid infectivity assays for ....Detection and viability of waterborne pathogens using a gut-on-chip. This project aims to resolve a significant problem for water utilities. Microbial pathogens Cryptosporidium, norovirus and adenovirus are the main public health concern for drinking water in developed nations. Water monitoring is limited by the lack of fast, reliable detection methods and viability assays for these pathogens. This project will use a novel gut-on-a-chip to develop for the first time rapid infectivity assays for Cryptosporidium, norovirus and adenovirus. Significant benefits include improved diagnostics and water disinfection assays, improved water treatment and reduced costs with global impact.Read moreRead less
Eco-friendly pesticides for crop protection. The aims of the project are to develop robust methods for measuring bioactive pesticidal molecules in butterfly pea cultivars, characterise their modes of action, determine the exposure and persistence of these molecules in field runoff and waterways and, in the longer term, develop butterfly pea cultivars with optimised bioactivity and safety. The major outcome of the project is the generation of new knowledge that will contribute to the development ....Eco-friendly pesticides for crop protection. The aims of the project are to develop robust methods for measuring bioactive pesticidal molecules in butterfly pea cultivars, characterise their modes of action, determine the exposure and persistence of these molecules in field runoff and waterways and, in the longer term, develop butterfly pea cultivars with optimised bioactivity and safety. The major outcome of the project is the generation of new knowledge that will contribute to the development of novel antifungal and insecticidal agents. This outcome is significant as there is a huge need for new pesticidal agents that exhibit wide safety margins, reduce problems associated with resistance to existing treatments, and that are safe for the environment.Read moreRead less
Plant cyclotides as novel sustainable tools for crop protection . This project between the University of Queensland and Syngenta, a top-tier agricultural biotech company, aims at developing new crop protection technologies based on peptides. Insecticides are essential to meet the 60% increase in food production goal set by the UN but long-term exposure to traditional insecticides can harm beneficial pollinating insect populations. Expected outcomes include an exciting new insecticide technology ....Plant cyclotides as novel sustainable tools for crop protection . This project between the University of Queensland and Syngenta, a top-tier agricultural biotech company, aims at developing new crop protection technologies based on peptides. Insecticides are essential to meet the 60% increase in food production goal set by the UN but long-term exposure to traditional insecticides can harm beneficial pollinating insect populations. Expected outcomes include an exciting new insecticide technology based on natural plant defense peptides, the cyclotides, which has potential to revolutionise crop protection, leading to safer products for the environment. Benefits from the technology include a reduction in toxic insecticide residues, precision targetted applications and agrichemicals that degrade without trace.Read moreRead less
Developing feasible in situ control of mange disease in wombats. Our goal is the development of feasible in situ control of sarcoptic mange in wombat populations. Globally important, the Sarcoptes scabiei mite infects >100 mammal species and is among the 50 most common human diseases, causing health, welfare and population impacts. This infection is treatable, and we will test a new treatment (fluralaner), develop new models to guide management, and conduct replicated field trials. This will ena ....Developing feasible in situ control of mange disease in wombats. Our goal is the development of feasible in situ control of sarcoptic mange in wombat populations. Globally important, the Sarcoptes scabiei mite infects >100 mammal species and is among the 50 most common human diseases, causing health, welfare and population impacts. This infection is treatable, and we will test a new treatment (fluralaner), develop new models to guide management, and conduct replicated field trials. This will enable science-based guidelines, advancing disease control, local eradication, and regulatory approval for wombats. Our research framework is adaptable to other mange-impacted species, and advance methods and theory for control of treatable disease in wildlife.Read moreRead less
Enhanced natural insecticidal activity against a pest of national priority . This project aims to deliver environmentally friendly, non-genetically modified crop protection tools against a catastrophic pest, the fall armyworm. This project expects to generate new knowledge of natural plant protection strategies and their application in targeted crop protection using a combination of unconventional, but cleverly integrated, cutting-edge technologies and approaches. Expected outcomes include compr ....Enhanced natural insecticidal activity against a pest of national priority . This project aims to deliver environmentally friendly, non-genetically modified crop protection tools against a catastrophic pest, the fall armyworm. This project expects to generate new knowledge of natural plant protection strategies and their application in targeted crop protection using a combination of unconventional, but cleverly integrated, cutting-edge technologies and approaches. Expected outcomes include comprehensive new technologies to fight against the most damaging global crop pest, improved Australian agritech capacity and strengthened international collaborations. This should provide significant benefits, such as added security for Australia’s most important agricultural crops and regions, and global food production.Read moreRead less
Understanding population growth time lags in invasive species. This project will use data collected from wild animals, landholder surveys, and computer simulation models to understand why invasive chital deer (Axis axis) are suddenly increasing in number after many years of slow population growth. By combining multiple empirical datasets and developing new modelling techniques, we will generate a new method for understanding population trends in introduced species. The results of this study will ....Understanding population growth time lags in invasive species. This project will use data collected from wild animals, landholder surveys, and computer simulation models to understand why invasive chital deer (Axis axis) are suddenly increasing in number after many years of slow population growth. By combining multiple empirical datasets and developing new modelling techniques, we will generate a new method for understanding population trends in introduced species. The results of this study will allow Queensland Department of Agriculture and Fisheries and others to better predict invasive species growth rates, which will allow for better, and more cost effective control methods. Read moreRead less
Novel biological and genetic disease control tools for the barley industry. This project places Australian barley breeders at the forefront of disease resistance by providing them with novel tools to develop varieties with enhanced protection against fungal diseases. The aims are to produce fungal strains with multiple virulence genes for fast and cost-effective testing of barley lines, untangle the fungal/host gene interaction for resistance breeding and identify new sources of resistance. The ....Novel biological and genetic disease control tools for the barley industry. This project places Australian barley breeders at the forefront of disease resistance by providing them with novel tools to develop varieties with enhanced protection against fungal diseases. The aims are to produce fungal strains with multiple virulence genes for fast and cost-effective testing of barley lines, untangle the fungal/host gene interaction for resistance breeding and identify new sources of resistance. The outcomes will lead to the commercialisation by Australian breeding companies of barley varieties with durable fungal resistance. This will benefit the Australian economy by providing sustainability and protection for barley breeding thereby significantly reducing crop losses for this important global agricultural commodity.Read moreRead less
Seafood safety: high throughput diagnostics for ciguatoxin risk assessment. This project aims to develop a novel, high throughput platform for rapidly assessing ciguatoxins. Species of the marine microalgae Gambierdiscus produce ciguatoxins, which accumulate in fish through marine food chains to cause the often debilitating human illness called ciguatera fish poisoning. Ciiguatera fish poisoning is a growing and substantial risk for the $2.2 billion Australian commercial fishing industry. This s ....Seafood safety: high throughput diagnostics for ciguatoxin risk assessment. This project aims to develop a novel, high throughput platform for rapidly assessing ciguatoxins. Species of the marine microalgae Gambierdiscus produce ciguatoxins, which accumulate in fish through marine food chains to cause the often debilitating human illness called ciguatera fish poisoning. Ciiguatera fish poisoning is a growing and substantial risk for the $2.2 billion Australian commercial fishing industry. This serious illness is increasingly impacting more southerly areas of Australia due to environmental changes. The outcomes of this project include new knowledge of the risk of ciguatoxins at Australian 'hot spot' sites, extensively field tested methods for detecting Gambierdiscus and ciguatoxins in situ and key data to inform policy to safeguard the seafood industry and consumers.
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Correction of non-linearity in inductively-coupled-plasma mass-spectrometry. Chemical analyses by mass spectrometers underpin key Australian economic sectors, particularly minerals and agriculture. The quadrupole inductively-coupled-plasma mass-spectrometer has seen a particular rise in prominence over last 25 years. In this collaboration between mass spectrometrists and the leading instrument designer, we will improve the linearity of its detection system for more precise and accurate data. Bet ....Correction of non-linearity in inductively-coupled-plasma mass-spectrometry. Chemical analyses by mass spectrometers underpin key Australian economic sectors, particularly minerals and agriculture. The quadrupole inductively-coupled-plasma mass-spectrometer has seen a particular rise in prominence over last 25 years. In this collaboration between mass spectrometrists and the leading instrument designer, we will improve the linearity of its detection system for more precise and accurate data. Better elemental and isotope ratio data from these high-throughput instruments will open up new real-world applications in many areas of Australian interest, such as biosecurity, forensics, groundwater management, and drug design. The research will also inform design of the next generation instruments by the industry partner.Read moreRead less
Increasing amphibian immunity to combat disease causing mass extinction. This project aims to increase amphibian survival to combat the devastating chytrid fungus by identifying resistance genes and increasing their frequency in the host population. The project is interdisciplinary and uses targeted genetic manipulation techniques developed for agriculture to improve disease resistance in wildlife for the first time. Expected outcomes include 1) enhanced international collaborations in comparati ....Increasing amphibian immunity to combat disease causing mass extinction. This project aims to increase amphibian survival to combat the devastating chytrid fungus by identifying resistance genes and increasing their frequency in the host population. The project is interdisciplinary and uses targeted genetic manipulation techniques developed for agriculture to improve disease resistance in wildlife for the first time. Expected outcomes include 1) enhanced international collaborations in comparative immunology, 2) a comprehensive understanding of immunity to chytridiomycosis, and 3) disease resistant amphibians. The anticipated benefit is ability to apply the optimal method to improve conservation of wildlife threatened by emerging disease, such as marker assisted selective breeding or genetic engineering.Read moreRead less