Molecular Epidemiology Of Antibiotic Resistant Salmonella Enterica Strains Causing Human Disease
Funder
National Health and Medical Research Council
Funding Amount
$493,767.00
Summary
Salmonella infections are responsible for a substantial proportion of reported food poisoning cases caused by bacteria and many of these infections are due to antibiotic resistant strains. Infections caused by antibiotic resistant organisms are hard to treat and generally more severe, of longer duration, and result in longer hospital stays. These strains are mostly acquired from foods, e.g. meats, dairy products, poultry, eggs, and other contaminated food products but can also be derived from ot ....Salmonella infections are responsible for a substantial proportion of reported food poisoning cases caused by bacteria and many of these infections are due to antibiotic resistant strains. Infections caused by antibiotic resistant organisms are hard to treat and generally more severe, of longer duration, and result in longer hospital stays. These strains are mostly acquired from foods, e.g. meats, dairy products, poultry, eggs, and other contaminated food products but can also be derived from other sources. Salmonella strains harboured by food-producing animals are the source of most of the food contamination.Tracing the source of individual resistant strains is essential for eradication and as there are many Salmonella types, some of which are found associated only with specific animals or birds, accurate identification is needed. The proposed work will make this process more accurate by using molecular techniques to unequivocally establish suspected connections and reveal further ones that are difficult to discern using current data and methods. This should decrease the number of infections due to resistant strains.Read moreRead less
Antibiotic resistance increases mortality and costs in the Intensive Care Unit (ICU), but the impact of antibiotic therapy has not been adequately studied. We propose to characterise the behaviour of key elements of the bacterial microflora (resistant bacteria and major resistance genes) in response to antibiotics. We have developed new rapid diagnostics to harness these data and this proposal has the potential to greatly improve diagnostic speed and accuracy and thus clinical outcomes.
The PH Of The Malaria Parasite's Digestive Vacuole And Its Role In Antimalarial Drug Resistance
Funder
National Health and Medical Research Council
Funding Amount
$210,990.00
Summary
Malaria is an infectious disease that infects an estimated 300-500 million people and kills an estimated 1.5-2.7 million people annually. The microscopic parasite responsible for the disease is becoming increasingly resistant to most of the antimalarial drugs presently available. However the mechanisms by which it does so are very poorly understood. The malaria parasite invades the red blood cells of its victim. Once itside, it sets about consuming the contents of the cell, ingesting them and de ....Malaria is an infectious disease that infects an estimated 300-500 million people and kills an estimated 1.5-2.7 million people annually. The microscopic parasite responsible for the disease is becoming increasingly resistant to most of the antimalarial drugs presently available. However the mechanisms by which it does so are very poorly understood. The malaria parasite invades the red blood cells of its victim. Once itside, it sets about consuming the contents of the cell, ingesting them and depositing them in a small acidic compartment called the digestive vacuole. Many of the antimalarial drugs presently in use target this compartment and interfere with the processes going on inside it. There is evidence that resistance to antimalarial drugs arises as a result of changes in this compartment, though what these changes are, and how they occur remains a mystery. This work focuses on the mechanisms involved in controlling the acidity of the parasite's digestive vacuole. We have preliminary evidence that parasites showing different levels of antimalarial drug resistance have different levels of acidity in their vacuoles, and that this may be due to differences in the rate at which acid leaks from this compartment. The aim of this work is to obtain a detailed understanding on the mechanisms by which the acidity of the parasite's digestive vacuole is regulated and to gain some insight into whether and how these mechanisms might differ between drug-resistant and drug-sensitive parasites. By so doing, this work might be expected, in the long term, to provide a basis for the devolpment of new drugs with which to combat this deadly and increasingly threatening disease.Read moreRead less