Reduction of antibiotic usage in the commercial pig industry. This project intends to identify factors that make a pig enterprise more likely to use high levels of antibiotics and develop alternative, vaccination-based methods for disease control. The development of multi-drug resistance in zoonotic bacterial pathogens (e.g. Salmonella and Campylobacter spp.) in pigs has raised concerns that antimicrobial resistance can be transferred from livestock to humans. Although the epidemiology to suppor ....Reduction of antibiotic usage in the commercial pig industry. This project intends to identify factors that make a pig enterprise more likely to use high levels of antibiotics and develop alternative, vaccination-based methods for disease control. The development of multi-drug resistance in zoonotic bacterial pathogens (e.g. Salmonella and Campylobacter spp.) in pigs has raised concerns that antimicrobial resistance can be transferred from livestock to humans. Although the epidemiology to support a claim that there is a causal association between antimicrobial use in food animals and public health is complex there is universal agreement that use of antimicrobials in food animal production should be minimised. This project intends to deliver outcomes that will reduce antibiotic use on commercial pig farms.Read moreRead less
Alphaherpesvirus recombination: safety implications for attenuated Herpesvirus vaccines. Under certain conditions some herpesviruses, including mild vaccine strains, can recombine to generate virulent viruses. Following findings that this occurred naturally between Australian poultry vaccines, with devastating results, this project will study natural herpesvirus recombination with the aim of allowing vaccines to be used more safely.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100093
Funder
Australian Research Council
Funding Amount
$510,000.00
Summary
High-throughput technology targeting antimicrobial resistance in animals. This project aims to establish reference laboratories as biobanks for resistant isolate collections from veterinary diagnostic laboratories / surveillance programmes and a national research network to mitigate antimicrobial resistance in animals. Antimicrobial resistance in zoonotic/foodborne pathogens and livestock commensals is a global issue. This project will use mass-spectroscopy biotypers, information management soft ....High-throughput technology targeting antimicrobial resistance in animals. This project aims to establish reference laboratories as biobanks for resistant isolate collections from veterinary diagnostic laboratories / surveillance programmes and a national research network to mitigate antimicrobial resistance in animals. Antimicrobial resistance in zoonotic/foodborne pathogens and livestock commensals is a global issue. This project will use mass-spectroscopy biotypers, information management software, robotic liquid handling and a research dairy to develop high-throughput screening technologies to rapidly determine major animal species’ resistance status, and research anti-infectives and vaccines for livestock diseases. This will improve the health and production of Australian livestock, leading to greater market access for high quality products.Read moreRead less
Using RNA interference to combat the worst emerging disease of wildlife. This project aims to develop a novel method of disease control in wildlife. It will use recent advances in RNA interference technology to knockdown virulence genes in an emerging pathogen that threatens biodiversity. Pathogens such as the amphibian chytrid fungus continue to cause widespread extinction and urgently require better control methods. RNA interference has been used to increase disease resistance to fungi in plan ....Using RNA interference to combat the worst emerging disease of wildlife. This project aims to develop a novel method of disease control in wildlife. It will use recent advances in RNA interference technology to knockdown virulence genes in an emerging pathogen that threatens biodiversity. Pathogens such as the amphibian chytrid fungus continue to cause widespread extinction and urgently require better control methods. RNA interference has been used to increase disease resistance to fungi in plants but adapting this approach for animals will have wide relevance in combatting fungi and other pathogens. The specific outcomes of this method will be to increase survival rates in a broad range of frog species to improve the success of captive release programs worldwide and hence save frogs from extinction.Read moreRead less