Establishing Australian Health Based Targets For Microbial Water Quality
Funder
National Health and Medical Research Council
Funding Amount
$174,799.00
Summary
It is of great public health importance to ensure that our drinking water supplies are safe. This is true both for conventional drinking water supplies and for supplies derived from alternative water sources, including water derived from recycled sewage. National guidelines exist for management of drinking water and recycled water supplies, but currently there are no targets for determining whether water has an acceptably low level of infectious agents. This project involves a number of steps to ....It is of great public health importance to ensure that our drinking water supplies are safe. This is true both for conventional drinking water supplies and for supplies derived from alternative water sources, including water derived from recycled sewage. National guidelines exist for management of drinking water and recycled water supplies, but currently there are no targets for determining whether water has an acceptably low level of infectious agents. This project involves a number of steps to develop national consensus on health targets for microbial water qualityRead moreRead less
Improving Risk Assessment For Recycled Water: Domestic Laundries And Recreational Parks
Funder
National Health and Medical Research Council
Funding Amount
$81,250.00
Summary
Recent droughts in Australia have meant that recycled water is becoming increasingly important to ensure the sustainability of our water resources. There are four different classes of recycled water (Class A, B, C and D), depending on the level of microbiological contamination. The potential level of exposure of the population to recycled water determines the class of water suitable for various reuse purposes. The need to address water recycling issues in Australia has resulted in increasing num ....Recent droughts in Australia have meant that recycled water is becoming increasingly important to ensure the sustainability of our water resources. There are four different classes of recycled water (Class A, B, C and D), depending on the level of microbiological contamination. The potential level of exposure of the population to recycled water determines the class of water suitable for various reuse purposes. The need to address water recycling issues in Australia has resulted in increasing numbers of innovative recycling schemes such as dual reticulation systems which supply two qualities of water to households, one of high quality for drinking and a second piped system delivering treated recycled water for non-potable (non-drinking) use. In this project, we will investigate the safety of using recycled water in different situations by using water with different known concentrations of micro-organisms to simulate recycled waters of different classes. Most state health authorities in Australia do not approve the use of recycled water for machine washing because of a lack of safety data, but its use in laundries could significantly reduce the need for high quality drinking water. We will perform experiments to help determine the safety of using recycled water for rinsing clothes during a washing machine cycle. Another use of recycled water is for irrigation of recreational parks. Because of safety concerns, when recycled water of Class B or C is used, some states advocate that the public must wait at least 4 hours after watering before they can gain access. This time period may be unnecessary. We will perform experiments to assess the potential exposure to micro-organisms in grass for park users at different time periods following irrigation with water of various classes. The information obtained from this project will help in the decision-making of health and water regulatory agencies.Read moreRead less
The Molecular Basis Of Bacterial Infectious Diseases
Funder
National Health and Medical Research Council
Funding Amount
$16,230,996.00
Summary
Bacterial infectious diseases are a serious threat to human health, accounting for over 10 million deaths each year. This multidisciplinary collaborative team is investigating the complex interactions between major disease-causing bacteria and their human hosts, in order to determine how they cause disease. These studies will make a major contribution to fundamental knowledge in this field. This information is also essential for the development of cheaper and more effective vaccines, as well as ....Bacterial infectious diseases are a serious threat to human health, accounting for over 10 million deaths each year. This multidisciplinary collaborative team is investigating the complex interactions between major disease-causing bacteria and their human hosts, in order to determine how they cause disease. These studies will make a major contribution to fundamental knowledge in this field. This information is also essential for the development of cheaper and more effective vaccines, as well as novel drugs. These are urgently needed to reduce death and illness due to bacterial infectious diseases in the 21st century. 11Read moreRead less
Fungi are increasingly causing life-threatening infections. Little is known about the mechanisms underlying these infections. We will compare the genomes of high and low virulent fungal strains to gain insides into the basis of these differences by using C. gattii as model of a globally highly pathogenic fungus. The findings will be generalized by comparing the obtained results with the genomes of other important pathogenic fungi to develop a scientific basis for better treatment strategies.
The fungal pathogen Cryptococcus neoformans is responsible for up to a million deaths annually, necessitating the development of novel antifungals. We have characterised the GTP biosynthesis enzyme IMP dehydrogenase, revealing it is critical for infection, and structural and functional analysis reveals routes to inhibitor specificity. In the proposed work will develop novel antifungal compounds that target this enzyme, as well as investigate related enzymes as potential future drug targets.
Evolutionary Events Shaping The Genome Of Cryptococcus Neoformans And Their Effects On Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$387,489.00
Summary
Recurring infection in patients with fungal meningitis caused by Cryptococcus neoformans is typically caused by persistence of the original infection rather than reinfection with a new strain. Our analysis of relapse strains shows that small-scale alterations frequently occur at the chromosome ends - regions containing important pathogenesis-related genes in other pathogens. We seek to characterise this microevolution further to understand how it contributes to the success of this pathogen.
An Investigation Into Chromatin Dynamics In Host-pathogen Interactions And Fungal Virulence
Funder
National Health and Medical Research Council
Funding Amount
$700,585.00
Summary
Fungal infections represent a major health burden, with loss of lives that parallels malaria. Only a handful of antifungal therapeutics is available, and mortality remains very high (30% or more). By using molecular biology approaches and animal infection models, this project aims to characterize a new class of promising antifungal drug targets in the major human fungal pathogen Candida albicans. The outcomes will provide the knowledge foundation for future antifungal drug discovery.
The Development Of Novel, Biofilm-resistant Biomaterials
Funder
National Health and Medical Research Council
Funding Amount
$147,360.00
Summary
Almost all patients who are catheterised long term develop a bacterial infection. Most often, the infection is the result of colonisation of the catheter surface by bacteria. Bacterial colonisation of the surface of biomedical devices represents a significant health threat as such bacterial biofilms are extremely resistant to traditional antibiotic regimens. This project aims to develop novel materials that prevent bacterial colonisation on catheters and other biomedical related devices. Our tec ....Almost all patients who are catheterised long term develop a bacterial infection. Most often, the infection is the result of colonisation of the catheter surface by bacteria. Bacterial colonisation of the surface of biomedical devices represents a significant health threat as such bacterial biofilms are extremely resistant to traditional antibiotic regimens. This project aims to develop novel materials that prevent bacterial colonisation on catheters and other biomedical related devices. Our technology is based on compounds identified from a marine alga that prevent bacterial colonisation of its surface. Similarly, we have shown that these compounds, when coated onto test surfaces, prevent bacterial colonisation of a range of materials.Read moreRead less