The Discrepancy of the Minimum Inhibitory Concentration Results for Methicillin-Resistant Staphylococcus aureus by Various Measurement Methods: A Comparison of Etest® and Microdilution Methods for Vancomycin, Teicoplanin, Linezolid, Daptomycin and Quinupristin-Dalfopristin

Citation: Kitano Y, Fujitani S, Wakatake H, Yanai M, Umekawa S, et al. (2015) The Discrepancy of the Minimum Inhibitory Concentration Results for Methicillin-Resistant Staphylococcus aureus by Various Measurement Methods: A Comparison of Etest® and Microdilution Methods for Vancomycin, Teicoplanin, Linezolid, Daptomycin and Quinupristin-Dalfopristin. Emergency Med 5: 286. doi:10.4172/2165-7548.1000286


Introduction
Currently, MRSA infections have been increasing in number worldwide, including in Japan. The Japan Nosocomial Infections Surveillance report of 2011 showed the rate of MRSA in Staphylococcus aureus isolates was 53% [1].
In 2003, the increase in vancomycin MIC was reported to be an important socio-economic issue as well as a threat to the health care system [2]. In 2006, the Clinical Laboratory Standard Institutes (CLSI) changed the breakpoint of the vancomycin MIC for MRSA [3]. Currently, with the rise in the vancomycin MIC, the Infectious Diseases Society of America (IDSA) guidelines recommend setting a higher vancomycin trough level at 15~20 µg/mL [4]. A recent report showed that higher vancomycin MIC levels (MIC ≥ 2) were associated with higher mortality rates in MRSA bacteremic patients even with the use of specific antimicrobial agents against MRSA [5].
are widely used because of their simplicity. It has been postulated that a discrepancy exists between the MRSA MIC results in various measurement methods, especially between Etest® and BMD methods [9][10][11][12]. Therefore, it is clinically essential to investigate whether such a discrepancy exists between these different MIC measurement methods. In our study, MIC results of MRSA clinical isolates were measured and analyzed using Etest® and five BMD methods for five anti-MRSA antibiotics including vancomycin, teicoplanin, linezolid, daptomycin and Q-D.

Methods
From November 2009 to March 2011, a prospective observational study was performed at two metropolitan tertiary Emergency Departments (EDs) in Japan [13]. Patients with high risk of MRSA  [3] were used for detection of antibiotic resistance. Table 1 shows the summary of the MIC measurement methods and their targeted anti-MRSA antibiotics. All available combinations were measured in our study.
Etest® was performed by evenly spreading the medium in three directions on a commercial agar plate (Mueller Hinton II Agar®, Becton, Dickinson and Company (BD), NJ, USA). The medium was prepared to achieve the bacterial concentration (0.5 McFarland) according to the turbidity standard technique. Etest® and the broth microdilution methods were performed by technicians unrelated to the study to thereby try and limit potential bias.
This study was approved by the Institutional Review Board of the St. Marianna University School of Medicine, Japan. The study design, data collection, data analysis, and manuscript preparation were conducted without industrial financial support.

Statistical analysis
The statistical analysis was performed using Wilcoxon signed rank test and Bland-Altman's analysis [14]. Bland-Altman's analysis was performed using International Business Machines (IBM) Statistical Package for the Social Sciences software version 22.0 (IBM, Corp., Armonk, NY, USA). Bland-Altman's analysis provided the mean difference in addition to the 95% limits of agreement corresponding to the mean difference ±2 standard deviations (SD).

Results
The summary of the MIC measurement methods and their targeted anti-MRSA antibiotics is summarized in Table 1. In our study, all the available combinations of MIC measurements, as summarized in Table  1, were performed on all 55 MRSA clinical isolates. MRSA isolates of the same generation of subculture were used for all MIC measurements. Etest® and the five BMD methods were performed to measure the MIC of vancomycin, teicoplanin and linezolid. The five BMD methods were as outlined in the methods above. With regard to daptomycin, Etest® and the Vitek2® method were performed. With regards to Q-D, Etest® and the MicroScan® turbidity method and the MicroScan® prompt method were performed.
The MIC results of vancomycin are shown in Table 2 and in Figure 1 (a-e in the left column), respectively. The distribution of the MIC results with modal and average MICs are respectively summarized in Table 2. The distribution of MIC results was constantly and significantly higher by Etest® compared to the BMD methods. The mode of vancomycin MIC was 2 μg/ml (74.5%, 41/55) in Etest® and 0.5 μg/ml (52.7%, 29/55) with the Phoenix® BMD method. The averages of vancomycin MIC were 1.86 μg/ml with Etest® and 0.74 μg/ml with Phoenix® BMD method (p<0.01). showed a larger discrepancy of MICs between the two measurement methods. As can be visualized in the scatterplots, the MICs were constantly and significantly higher by Etest®, and this tendency was more prominent in the Eiken®, Phoenix® and Vitek2® BMD methods. Vancomycin MICs measured by Etest® were consistently twofold dilutions higher than the MICs determined by Eiken®, Phoenix® and Vitek2® BMD methods. The discrepancy was less prominent with the MicroScan® prompt method and the MicroScan® turbidity method; however, the MICs of those methods were still persistently higher in Etest®. Lower MICs by the BMD methods have a risk of underestimating the MRSA MIC, which poses a risk of targeting an insufficiently low trough level of anti-MRSA antibiotics when the MIC measured by Etest® is truly higher to warrant targeting a higher trough level. The difference of the discrepancy is also demonstrated with Bland-Altman's plot in Figure 2. The plot confirmed a larger discrepancy with the Eiken®, Phoenix® and Vitek2® BMD methods, and smaller discrepancies with the MicroScan® prompt method and the MicroScan® turbidity method.
The MIC results of teicoplanin are summarized in Table 3 and in Figure 1 (f-j in the right column). The modal MICs were 2 μg/ml by Etest® and 0.5 μg/ml by the Phoenix® BMD method, respectively. The MIC averages were 1.86 g/ml by Etest® and 0.60 μg/ml by the Phoenix® (p<0.01) method. Teicoplanin MICs showed a similar tendency as those of vancomycin. The MICs generated by Etest® were consistently more than twofold dilutions higher than MICs measured by the Eiken® and Phoenix® BMD methods. The MIC values by Etest® were higher and paralleled those by the BMD methods, i.e. isolates with higher MIC values with Etest® also had higher MIC values for the Eiken® or Phoenix®    methods as shown in Fig 1-f and 1-i. When measured by the Vitek2® method, 54 of 55 isolates resulted in MIC ≤ 0.5 μg/ml when the MIC by Etest® distributed from 0.75 μg/ml to 4 μg/ml with a modal MIC of 2 μg/ml, which indicated that the Vitek2® method could not provide a meaningful differentiation of MICs (Fig 1-j). A similar tendency was observed in the MicroScan® turbidity method and the MicroScan® prompt method; the teicoplanin MICs were almost all reported as ≤ 2 μg/ml by the MicroScan® turbidity method and the MicroScan® prompt method and could not differentiate regarding MICs lower than 2 μg/ml (Figure 1g and h). The MIC results of linezolid showed a similar tendency of higher MIC distribution by Etest® and lower distribution by the BMDs methods (Table S1 and Figure S1). The modal MICs were 3 μg/ml by Etest® and 1 μg/ml by the Phoenix® method, respectively. The MIC averages were 2.55 μg/ml by Etest® and 1.18 μg/ml by the Phoenix® method (p<0.01).
The MIC results of Q-D showed a similar tendency of higher MIC distribution by Etest® and a lower distribution by two BMD methods (Table S2 and Figure S2). The modal MICs were 0.75 μg/ml by Etest® and ≤ 0.5 μg/ml by the MicroScan® turbidity method. The MIC averages were 0.73 μg/ml by Etest® and 0.56 μg/ml by the MicroScan® turbidity method (p<0.01).
The MIC results of daptomycin by Etest® and the Vitek2® method are summarized in Table 4 and Figure 3. In contrast to the results of the other anti-MRSA antibiotics, only daptomycin MICs were distributed higher by the Vitek2® method than by Etest®.

Discussion
Our study has three clinical implications. First, by simultaneously   evaluating all available combinations (Table 1), our study has shown that MICs, not only by vancomycin but also by other anti-MRSA antibiotics, had a similar tendency of higher MICs with Etest® compared to the BMD methods. Although similar previous studies have been published, to the best of our knowledge, our study is the first report in which Etest® and five BMD methods have been measured at one time for five anti-MRSA antibiotics (vancomycin, teicoplanin, linezolid, daptomycin and Q-D).
The previous articles are summarized in Table 5. Sader et al. [9] compared Etest® and one BMD method (CLSI being the reference BMD method) for vancomycin and daptomycin; they reported that vancomycin MICs obtained by Etest® were consistently higher than those obtained by the BMD method. Swenson et al. [10] compared Etest® and five BMD methods (MicroScan® prompt method, Vitek2®, Vitek Legacy®, Sensititre®, and Phoenix®) for vancomycin, which showed the similar tendency that the MicroScan® prompt method had a smaller discrepancy and that Vitek2® had a larger discrepancy to Etest®. Kruzel et al. [11] investigated Etest® and five BMD methods (Trek®, BMD in-house, Vitek2®, MicroScan®, and Phoenix®) for vancomycin and daptomycin, which showed a similar tendency of the MIC results by the Vitek2® and Phoenix® methods, which were distributed in a lower range compared to the MicroScan® method. Prakash et al. [12] investigated two kinds of Etest® and two BMD methods for vancomycin.
These articles provided information comparing one or two pairs (i.e. BMDs vs. Etest® for vancomycin alone or for vancomycin/daptomycin). However, the information from our study have clinical importance in providing a more thorough perspective of the discrepancy by obtaining all the available combinations of five BMD methods and Etest® on anti-MRSA antibiotics all at one time. When measured by the Phoenix® method, the MIC measurements of vancomycin, teicoplanin and linezolid are all distributed lower than Etest® as previous studies have also demonstrated. Our study has provided further information that with respect to teicoplanin and linezolid, the discrepancies were larger than with vancomycin, the information that only our study could provide by simultaneous measurements and comparison.
Second, our study demonstrated that among the various BMD methods, the Eiken®, Phoenix® and Vitek2® methods had larger discrepancies compared to Etest®; the MicroScan® prompt method and the MicroScan® turbidity method had smaller discrepancies when compared to Etest® in respect of vancomycin MIC measurement. This provides important information in assessing MIC results obtained in the clinical setting. If the vancomycin MIC is measured by the Eiken®, Phoenix® or Vitek2® BMD methods, clinicians should be aware that it may considerably underestimate the MIC result. Conversely, if the vancomycin MIC is measured by the MicroScan® prompt method or the MicroScan® turbidity method, it can be assumed that it correlates fairly well with the MIC results obtained by Etest®.
Third, our results have shown that daptomycin MIC results were distributed lower by Etest® than by the Vitek2® method, which is the only reverse correlation among other anti-MRSA antibiotics. Previous   Our study has several limitations. First, the 55 clinical isolates investigated were MRSA colonies from patients' nares on admission to the ED. However, our study has generalization as in measuring the MIC level, materials from colonized strains and strains from clinical infections are not intrinsically different. Also, MRSA colonization in nares was reported to be associated with an increased risk of MRSA infection, which indicates that MRSA colonized strains are strongly associated with MRSA infections [15]. Second, the MRSA isolates were from two metropolitan tertiary EDs in Japan. The MRSA epidemiology or antibiogram might differ among institutions or geographic regions. However, it does not affect the MIC measurement methods as stated above. Third, MRSA-MIC measurements were performed only on one occasion. We optimized the MIC measurement accuracy by measuring all 55 samples at one time. After thawing and inoculating from the frozen MRSA colonies, the MRSA isolates of the identical generation of subculture were used for all MIC measurements (Etest® and five BMD methods) to minimize the measurement bias. The MIC of the same 55 colonies were previously measured with three BMD methods (Phoenix®, MicroScan® prompt and MicroScan® turbidity) for another study (data not published). There was minimal deviation between the two MIC results obtained by the same BMD methods at different times.

Conclusion
The MIC measured by various BMD methods tended to show lower results compared to those measured by Etest® with respect to anti-MRSA antibiotics (vancomycin, teicoplanin, linezolid and Q-D).
Among the BMD methods, the MicroScan® prompt method and the MicroScan® turbidity method had less discrepancies from Etest® compared to the Eiken®, Phoenix® and Vitek2® methods in vancomycin MIC measurement.