Masters Degrees (Medical Microbiology)

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Browsing Masters Degrees (Medical Microbiology) by Subject "Antibiotic treatment"

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    In Vitro antimicrobial synergy testing of Acinetobachter Baumannii
    (Stellenbosch : University of Stellenbosch, 2010-12) Martin, Siseko; Orth, Heidi; University of Stellenbosch. Faculty of Health Sciences. Dept. of Pathology. Medical Microbiology.
    ENGLISH ABSTRACT: Acinetobacter baumannii has emerged as one of the most troublesome nosocomial pathogens globally. This organism causes infections that are often extremely difficult to treat because of the widespread resistance to the major antibiotic groups. Colonization or infection with multidrugresistant A. baumannii is associated with the following risk factors: prolonged hospital stay, admission to an intensive care unit (ICU), mechanical ventilation, and exposure to broad spectrum antibiotics, recent surgery, invasive procedures, and severe underlying disease. A. baumannii has been isolated as part of the skin flora, mostly in moist regions such as axillae, groin and toe webs. It has also been isolated from the oral cavity and respiratory tract of healthy adults. Debilitated hospitalized patients have a high rate of colonization, especially during nosocomial Acinetobacter outbreaks. This organism is an opportunistic pathogen as it contains few virulence factors. Clinical manifestations of A. baumannii include nosocomial pneumonia, nosocomial bloodstream infections, traumatic battlefield and other wound infections, urinary tract infections, and post-neurological surgery meningitis. Fulminant community-acquired pneumonia has recently been reported, indicating that this organism can be highly pathogenic. The number of multidrug-resistant A. baumannii strains has been increasing worldwide in the past few years. Therefore the selection of empirical antibiotic treatment is very challenging. Antibiotic combinations are used mostly as empirical therapy in critically ill patients. One rationale for the use of combination therapy is to achieve synergy between agents. The checkerboard and time-kill methods are two traditional methods that have been used for synergy testing. These methods are labor intensive, cumbersome, costly, and time consuming. The E-test overlay method is a modification of the E-test method to determine synergy between the different antibiotics. This method is easy to perform, flexible and time efficient. The aim of this study was to assess the in vitro activity of different combinations of colistin, rifampicin, imipenem, and tobramycin against selected clinical strains of A. baumannii using the checkerboard and the E-test synergy methods. The MICs obtained with the E-test and broth microdilution method were compared. The results of the disk diffusion for imipenem and tobramycin as tested in the routine microbiology laboratory were presented for comparison. Overall good reproducibility was obtained with all three methods of sensitivity testing. The agreement of MICs between the broth dilution and E-test methods was good with not more than two dilution differences in MIC values for all isolates, except one in which the rifampicin E-test MIC differed with three dilutions from the MIC obtained with the microdilution method. However, the categorical agreement between the methods for rifampicin was poor. Although MICs did not differ with more than two dilutions in most cases, many major errors occurred because the MICs clustered around the breakpoints. The combinations of colistin + rifampicin, colistin + imipenem, colistin + tobramycin, rifampicin + tobramycin, and imipenem + tobramycin all showed indifferent or additive results by the E-test method. No results indicating synergy were obtained for all the above-mentioned combinations. There was one result indicating antagonistic effect for the combination of colistin + tobramycin. The results of the checkerboard method showed results indicating synergy in four of the six isolates for which the combination of colistin and rifampicin was tested. The other two isolates showed indifferent/additive results. All the other combinations showed indifferent/additive results for all isolates except isolate 30 (col + tob) and isolate 25 (rif + tob) which showed synergism. No antagonistic results were observed by the checkerboard method. When the results obtained with the E-test and checkerboard methods were compared, it was noted that for most antibiotic combinations an indifferent/additive result was obtained. However, for the colistin + rifampicin combination, the checkerboard method showed synergism for 4 of 6 isolates, whereas the E-test method showed indifference and an additive result in one. For the rifampicin + tobramycin, and colistin + tobramycin combinations, synergism was also shown with the checkerboard method in one isolate for each combination. The E-test method however showed an indifferent and additive result respectively. . The E-test method was found to be a rapid, reproducible, easy-to-perform, and flexible method to determine synergistic antibiotic activity. This study was however limited by low numbers of isolates. This might explain why no synergistic results were obtained with the E-test method and few synergistic results with the checkerboard method. Genotypic analysis using pulse-field gel electrophoresis (PFGE) may be considered in future studies to determine relatedness of the isolates which will facilitate the selection of different strains for synergy testing. Furthermore, clinical studies are needed to establish whether in vitro synergy testing is useful in the clinical setting and whether the results of synergy testing will have any bearing on the clinical outcome of patients infected with multidrug resistant A. baumannii.