Developing novel chemistries for removing environmental surface biofilms to reduce hospital acquired infections. This project will develop new detergents that more efficiently clean hospitals. This will increase hospital safety by decreasing infections, thus saving lives and healthcare costs.
Vaccinating Against Helicobacter Pylori-induced Gastric Cancer
Funder
National Health and Medical Research Council
Funding Amount
$1,088,714.00
Summary
Stomach cancer is the 3rd leading cause of cancer-related deaths. Most stomach cancers result from inflammation due to Helicobacter pylori infection. Most infections are treatable with antibiotics but this does not protect against cancers that develop before infection is diagnosed. Normal vaccine approaches aimed at this infection have been unsuccessful. We have identified a new approach for protecting against stomach cancer by preventing inflammation; this project aims to develop this vaccine.
Development of a safe and immunogenic anti-chlamydia vaccine for the koala. Many koala populations are under threat of extinction from chlamydial disease.The project will develop a chlamydial vaccine and conduct trials in several wild koala populations for safety and effectiveness.
New models as tools for defining mechanisms of microbe survival in the urogenital tract. Bacteria that infect the human urogenital tract can cause serious disease and these infections represent a large cost to the health-care system world-wide. This study will focus on how bacteria survive in the human urogenital tract and this will impact on strategies aimed at preventing and treating these infections.
A single vaccine for influenza and pneumonia. Influenza and bacterial pneumonia collaborate to kill millions of people each year. This project aims to develop a single vaccine that will provide long-lasting protection against both influenza and pneumonia.
The development and evaluation of a new therapy for the prevention and treatment of bacterial infections in hospitals. The technology used in this project will enable products to be developed from the Australian dairy industry which may safely provide protection and treatment for diarrhoea acquired in hospitals for which there are few effective options. The product will be cost effective and can be used as a public health tool to control outbreaks in those most susceptible to severe disease.
Understanding The Role Of The Essential Regulator WalKR In Staphylococcus Aureus
Funder
National Health and Medical Research Council
Funding Amount
$555,239.00
Summary
Staphylococcus aureus is one of the most common human bacterial pathogens. This project aims to characterise an important global control system in S. aureus, and determine if chemical inhibitors of this control system could be used to treat S. aureus disease in the future.
Linking Genomics Of Burkholderia Pseudomallei To Melioidosis: Diversity Of Clinical Manifestations, Changing Epidemiology And Microevolution In Chronic Carriage.
Funder
National Health and Medical Research Council
Funding Amount
$602,769.00
Summary
The Darwin Prospective Melioidosis Study has documented 761 cases since 1989, with 102 fatalities. This study has led to improved therapy and public health initiatives. New technology to sequence whole bacterial genomes provides an opportunity to determine why urban melioidosis is increasing and to analyse this unique 22+ year set of bacteria and their linked patient data to find the important bacterial virulence factors, forming a foundation for future diagnostics, therapeutics, and vaccines.
Host-pathogen interactions: the role of mimicry. The proposed research program, using a combination of structure and functional analysis will provide insight into the mechanism of nucleotide hydrolysis by the enzymes NTPDases. This study will not only improve our fundamental understanding of NTPDase action but could lead to the rational design of antimicrobials.
Understanding heat shock protein complex vaccines. This project aims to understand the mechanism of action and formulation requirements of a novel vaccine technology that utilises heat shock protein complexes. By understanding how this technology works, future vaccines can be improved to induce the immune response required to target specific pathogens, as well as give assurance regarding its safety.