Comparison of Etest, chequerboard dilution and time–kill studies for the detection of synergy or antagonism between antifungal agents tested against Candida species

R. E. Lewisa,*, D. J. Diekemab, S. A. Messerc, M. A. Pfallerc and M. E. Klepserd

a Department of Clinical Sciences and Administration, University of Houston College of Pharmacy, Texas Medical Center, 1441 Moursund Street #423, Houston, TX 77030; b Department of Internal Medicine, Division of Infectious Diseases, c Department of Pathology and d Division of Clinical and Administrative Pharmacy, University of Iowa Hospitals and Clinics, Iowa City, IA 52242, USA


    Abstract
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 Acknowledgements
 References
 
Currently, there is considerable debate regarding the best in vitro method for testing antifungal combinations against Candida spp. In this study, we compared the results obtained by chequerboard dilution, time–kill studies and Etest for several antifungal combinations against Candida spp. Three Candida albicans isolates (fluconazole MICs of 1.0, 32 and >256 mg/L) and three non-albicans Candida isolates (C. glabrata, C. tropicalis and C. krusei) were tested in RPMI 1640 medium. By chequerboard testing, the majority of antifungal combinations were found to be indifferent. Notably, antagonism was identified by time–kill studies and by Etest for combinations of amphotericin B–fluconazole, but it was not detected by the chequerboard method. Pre-exposure of isolates to fluconazole did not affect results of the Etest or chequerboard method, but it did increase the frequency of antagonism noted by time–kill methods. This study indicates that chequerboard dilution testing in RPMI medium may not reliably detect the attenuation of amphotericin B activity. Of the three methods, Etest was the simplest to use and yielded reproducible results for testing antifungal combinations.


    Introduction
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 Acknowledgements
 References
 
Interest in the use of combination antifungal therapy has grown considerably over the last decade with the emergence of fluconazole (FLU)-resistant Candida species and the development of new antifungal agents by the pharmaceutical industry. Currently, the National Committee for Clinical Laboratory Standards (NCCLS) has not proposed standardized methods for in vitro testing of antifungal combinations. Although a number of in vitro methods have been described, the chequerboard dilution method and time–kill studies have become the most widely accepted techniques. Each method has advantages and limitations.1 Chequerboard testing is easy to carry out and interpret but provides only a relative measure of potency for the combination (MIC), and it provides little data on the dynamics of the antifungal interaction. Time–kill studies, on the other hand, can help elucidate the pharmacodynamics of an antifungal combination by measuring the effects of the antifungal interaction on the rate and extent of fungal killing. The drawback to time–kill studies, however, is that they are laborious to complete.

Chequerboard testing and time–kill studies are generally carried out under the assumption that the agents tested in combination possess similar dose–response curves and a comparable timecourse of activity.1 This assumption may be problematic, however, for polyene–azole combinations. Previous in vitro studies carried out in our laboratories have demonstrated that the onset of activity for azoles against Candida and Cryptococcus species is considerably slower than the fungicidal activity exerted by amphotericin B (AMB).2,3 Additionally, several investigators have documented the importance of FLU pre-exposure with in vitro test methodology for the detection of antagonism between AMB and FLU.4–6 Because the rapid onset of AMB activity may pre-empt the contribution of azole antifungal activity in the test system, traditional techniques of assessing antifungal combinations, which rely on simultaneous administration of drugs, may fail to detect synergic or antagonistic antifungal interactions.

More recently, the Etest has been investigated as a method for antifungal susceptibility testing and has demonstrated good correlation with broth macrodilution and microdilution testing methods.7–11 Moreover, Etest has been used successfully to test drug combinations against mycobacterium and aerobic Gram-negative bacilli.12,13 If an Etest method could be standardized for testing antifungal combinations, it would represent an ideal testing methodology for the clinical microbiology laboratory.

The objectives of this study were three-fold: (i) to examine the utility of Etest for testing antifungal combinations against Candida species; (ii) to compare agreement between chequerboard, time–kill and Etest methods for the detection of synergy or antagonism of antifungal combinations against Candida species; and (iii) to compare the results of chequerboard, time–kill and Etest methods before and after pre-exposure of test isolates to FLU.


    Materials and methods
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 Acknowledgements
 References
 
Test organism

Six isolates obtained from the Clinical Microbiology Laboratory at the University of Iowa College of Medicine were selected. Three C. albicans isolates (ATCC CA 90028, CA 1378.33 and CA 20096.0097), one C. glabrata isolate (ATCC CG 582), one C. krusei isolate (ATCC CK 6258) and one C. tropicalis isolate (ATCC CT 2697) were used for all test procedures.

Antifungal agents

FLU (Pfizer, New York, NY), AMB and flucytosine (5FC) (Sigma, St Louis, MO, USA) were used to prepare stock solutions in RPMI 1640 (Sigma) buffered to a pH of 7.0 with 0.165 M morpholinepropanesulphonic acid (MOPS) according to NCCLS recommendations.14

Antifungal susceptibility testing

The MIC of each antifungal was determined by broth microdilution and Etest using methods described by the NCCLS and the Etest manufacturer (AB Biodisk, Solna, Sweden).14 Broth-microdilution MICs were determined in RPMI 1640 medium buffered to a pH of 7.0 with MOPS. The starting inoculum was c. 0.5 x 102 to 2.5 x 103 cfu/mL.

Etest MICs were determined with FLU (0.016–256 mg/L), AMB (0.002–32 mg/L) and 5FC (0.002–32 mg/L) strips provided by the manufacturer (AB Biodisk). Solidified (1.5%) 150 mm RPMI + MOPS agar plates (Remel, Lenexa, KS, USA) served as the test medium. A standardized cell suspension (0.5 McFarland) in sterile 0.85% NaCl was prepared by transferring 3–4 colonies from a 24 h culture on potato dextrose agar (PDA) (Remel). Plates were then inoculated by pouring 5 mL of a 1:4 dilution of this standardized cell suspension on to the agar. After allowing 1–2 min for the suspension to achieve a uniform distribution, excess moisture was aspirated with a vacuum pipette and the plate was allowed to dry at room temperature (15 min). Antifungal strips were then placed on to the inoculated agar using sterile technique.

All tests were incubated at 35°C in a dark, moist chamber. MICs were recorded at 24 and 48 h. The susceptibility endpoint for broth-based testing of AMB was defined as the lowest concentration of drug that resulted in complete inhibition of visible growth. Broth-based susceptibility endpoints for FLU and 5FC were defined as the lowest concentration of drug that resulted in an 80% reduction of visual growth compared with the growth of the control. Similarly, Etest susceptibility endpoints for FLU and 5FC were read at the intersection of the scale of the strip and the first discernible growth-inhibition ellipse according to the recommendations of the manufacturer. The Etest susceptibility endpoint for AMB was read at the intersection of the scale of the strip with the first completely clear ellipse.

Chequerboard microdilution studies

Combinations of AMB + FLU, AMB + 5FC and FLU + 5FC were tested in duplicate using previously described methods.15 The concentration of each antifungal agent tested ranged from 1/32 to 4 x MIC. The initial inoculum was prepared as described for broth-microdilution susceptibility testing. Readings were determined visually and spectrophotometrically (80% reduction) at 490 nm. MIC endpoints were determined as described for broth-microdilution tests. Both on- and off-scale MICs were included in the analysis. High off-scale MICs were converted to the next two-fold dilution, whereas low off-scale MICs were left unchanged. Trays were incubated at 35°C in a dark, moist chamber. Results were read at 24 and 48 h.

To evaluate the interaction of antifungals, the fractional inhibitory concentration (FIC) was calculated for each combination.1,16 The FIC was calculated for each agent by dividing the inhibitory concentration of each antifungal when used in combination by its MIC. FIC values were then added together to define the interaction of the combination. Synergy was defined as an FIC of <=0.5, and additivity was defined as an FIC of >0.5 but <1. Indifference was defined as an FIC of >=1 but <4, whereas antagonism was defined as an FIC of >=4.

Time–kill studies

Time–kill studies of each antifungal combination were carried out by a method that we have described previously.17 Earlier studies in our laboratory have documented a lack of antifungal carryover with these methods with the range of antifungal concentrations tested in this study. The lower limit of accuracy with this method is 50 cfu/mL. Both a fungicidal high concentration (HC) 2.5 mg/L (2–4 x MIC) and a fungistatic low concentration (LC) 0.25 mg/L (0.25–0.5 x MIC) of AMB alone and in combination were tested. One millilitre of a standardized cell suspension (0.5 McFarland) was transferred to sterile tubes containing 9 mL of growth medium (RPMI 1640 + MOPS) plus the following antifungal concentrations: (i) control (no drug); (ii) LC-AMB; (iii) HC-AMB; (iv) FLU 20 mg/L; (v) 5FC 50 mg/L; (vi) LC-AMB + FLU; (vii) HC-AMB + FLU; (viii) LC-AMB + 5FC; (ix) HC-AMB + 5FC; (x) FLU + 5FC. Tubes were incubated at 35°C for 24 h on an orbital shaker. At predetermined timepoints (0, 4, 8, 12 and 24 h), samples were aseptically removed and serially diluted, and 30 µL aliquots were plated on to PDA for colony-count determination. All plates were incubated for 48 h at 35°C. All testing was carried out in duplicate.

Antifungal interaction tested by time–kill methods was defined using established criteria. Briefly, a >=2 log10 increase in killing as measured by viable cfu/mL at 24 h between the combination and the most active constituent was defined as synergy, and a <2 but >1 log10 increase was defined as additive. A decrease in killing from the least active agent of <2 log10 cfu/mL was defined as indifference, whereas a decrease in killing of >2 log10 cfu was defined as antagonism.16

Etest studies

A modification of previously reported methods for testing antibacterial combinations against Mycobacterium spp. with Etest was used to test antifungal combinations (Fig-ure 1).12,13 Test medium and inoculum preparation were as described previously for susceptibility testing. Antifungal interactions were defined by criteria recommended by the manufacturer (AB Biodisk). Synergy was defined as a decrease of >=3 dilutions in the resultant MIC. Additivity was defined as a decrease of >=2 but <3 and indifference as a decrease of <2 dilutions in the MIC. Antagonism was defined as an increase of >=3 dilutions of the MIC for the antifungal combination. To facilitate comparisons with the chequerboard method, an FIC index was calculated from Etest MIC data that were rounded up to the nearest two-fold dilution. All testing was carried out in duplicate.

FLU pre-exposure

To evaluate the influence of FLU pre-exposure, each test isolate was prepared as follows. One millilitre of a standardized cell suspension (3.0 McFarland) was added to a culture vial containing 9 mL of growth medium with FLU (20 mg/L). The cell suspension was then incubated for 12 h at 35°C on an orbital shaker. Following the incubation period, the cell suspension was pelleted and washed in sterile saline twice by centrifugation (2800 rpm x 10 min x 3) and resuspended in warm, drug-free growth medium. The resultant suspension was then re-standardized to 1 x 105 to 5 x 105 cfu/ml (0.5 McFarland turbidity) and used for chequerboard, time–kill and Etest testing.

Analysis

All plates and trays were read at 24 and 48 h by a single investigator, and results were confirmed by a second investigator. The frequency of synergy, additivity, indifference and antagonism were tabulated and compared for each isolate–drug combination before and after FLU pre-exposure. For purposes of comparison, the time–kill test was considered to be the reference method.


    Results
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 Acknowledgements
 References
 
In vitro susceptibility testing

The median MICs determined by broth microdilution and Etest are presented in Table 1Go. In general, there was good agreement between the Etest and broth-microdilution methods.


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Table 1. Median MIC (mg/L) results by broth microdilution and Etest (n = 5)
 
Antifungal combination testing

Results presented in Tables 2 and 3GoGo demonstrate that agreement between the Etest and the chequerboard methods was poor. Antifungal synergy was detected by the chequerboard method in six of 18 (33%) tests with or without FLU pre-exposure, whereas synergy was not detected by Etest (0 of 18). Combinations that included 5FC were most likely to exhibit synergic activity by chequerboard testing. Antagonism was not detected for any of the antifungal combinations tested by chequerboard dilution, but it was noted in three of 18 (17%) isolates tested by Etest (all isolates susceptible or susceptible dose-dependent to FLU).


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Table 2. Chequerboard and Etest results (without FLU pre-exposure)
 

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Table 3. Chequerboard and Etest results (with FLU pre-exposure)
 
Time–kill studies (Figures 2 and 3GoGo) identified antagonism between HC-AMB and FLU for three isolates (CA 90028, CA 1378.33 and CT 2697) after FLU pre-exposure. Synergy was only noted by time–kill studies for LC-AMB + 5FC against isolate CA 20096.0097. Overall, agreement between chequerboard testing and time–kill studies (concurrent identification of synergy, antagonism, indifference or additivity) was found in seven of 18 tests (38%) with those isolates without FLU pre-exposure and only two of 18 tests (11%) with FLU pre-exposure.



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Figure 2. Summary of 24 h time–kill study results for AMB + FLU combinations: {square}, AMB 0.25 mg/L FLU pre-exposed; , AMB 2.5 mg/L FLU pre-exposed; , AMB 0.25 mg/L FLU simultaneous; {boxtimes}, AMB 2.5 mg/L FLU simultaneous.

 


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Figure 3. Summary of 24 h time–kill study results for 5FC + AMB and 5FC + FLU combinations: {square}, AMB 0.25 mg/L + 5FC; , AMB 2.5 mg/L + 5FC; , FLU + 5FC.

 
In contrast to the chequerboard dilution method, the agreement between Etest and time–kill studies was good (Tables 2 and 3GoGo and Figures 2 and 3GoGo). Analysis of the results of antifungal combinations (synergy, antagonism, indifference, additivity) concurred with time–kill studies in 15 of 18 tests (83%) using LC-AMB without FLU preexposure and 14 of 18 tests (78%) with FLU pre-exposure. When HC-AMB was used in time–kill studies, concordance between Etest results and time–kill studies was 15 of 18 (83%) without FLU pre-exposure and 18 of 18 (100%) with FLU pre-exposure. As with time–kill studies, antagonism was noted by Etest with AMB–FLU combinations against CA 90028, CA 1378.33 and CT 2697 (Tables 2 and 3GoGo and Figure 4Go). Pre-exposure with FLU had no discernible effect on the determination of synergy or antagonism with the Etest method.



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Figure 4. Antifungal antagonism demonstrated by Etest with FLU-susceptible and FLU resistant species. (a) C. albicans 90028; (b) C. albicans 20096.0097. Arrows represent intersection of ellipse and Etest strip.

 

    Discussion
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 Acknowledgements
 References
 
Despite the recent proposal of standardized methods for antifungal susceptibility testing, uniform techniques for assessing the activity of antifungals in combination are still lacking.14,18 Chequerboard testing and time–kill studies have emerged as the methods most frequently employed for testing antifungal combinations. There have been few comparative studies to determine the best method. Petrou & Rogers6 utilized both chequerboard testing and time–kill studies to evaluate polyene–azole interactions against Candida spp. and Saccharomyces cerevisiae. Although agreement between the two methods was deemed acceptable by the authors, they noted better sensitivity and reproducibility with time–kill studies, particularly in the ability of time–kill testing to detect azole-mediated antagonism of AMB fungicidal activity. Our findings4,5 support their observations.

AMB and azole antifungals possess a different timecourse of activity; therefore, we speculated that preexposure of the Candida isolates to FLU (thus ensuring the full antifungal effect of FLU at the time that AMB or 5FC was introduced into the test system) might change the results of the chequerboard tests. Interestingly, FLU pre-exposure did not increase the frequency of antagonism noted by the chequerboard method. This lack of antagonism could be explained in two ways. First, broth-microdilution antifungal susceptibility testing of AMB in RPMI medium frequently demonstrates a ‘clustering’ (narrow distribution) of MICs.14,18 Thus, the method is not well suited for discriminating between susceptible and resistant isolates. Therefore, the broth-microdilution method (on which chequerboard testing is based) may not be able to discern a synergic or antagonistic interaction with AMB combinations. Secondly, because AMB–azole antagonism appears to be one-sided (the activity of the azole appears to persist despite the abrogation of AMB fungidal activity), detecting a four-dilution change in the MIC of AMB, which would be necessary to detect antagonism (an FIC index of >=4), seems unlikely. Whether or not antagonism could be detected by chequerboard testing in other media (i.e. antibiotic medium #3) is a question currently under investigation.

Another interesting finding in this study was the influence of FLU susceptibility on the development of AMB–FLU antagonism detected in vitro. With the exception of C. glabrata (CG 582), antagonism was noted by time–kill and Etest methods for isolates that were FLU susceptible or susceptible dose-dependent (CA 90028, CA 1378.33 and CT 2697). Antagonism, however, was absent or less pronounced for the FLU-resistant C. albicans isolate (CA 20096.097) or for C. krusei (CK 6258). These findings are consistent with the theory that AMB antagonism develops secondary to azole-mediated depletion of ergosterol binding sites. Further studies are required, however, before this finding can be validated.

Antifungal synergy in this study was seen only with 5FC combinations. However, the fact that synergy was largely detected by the chequerboard method and not corroborated by Etest or time–kill studies raises the question of a testing artefact seen only with chequerboard dilution. Broth-microdilution susceptibility testing of 5FC alone is often difficult to interpret because of trailing phenomena seen with 5FC against Candida spp. In the presence of a second agent, the trailing seen with 5FC is often absent or decreased. Therefore, it is possible that the visual/spectrophotometric endpoint (80% reduction) used to determine the MIC of 5FC alone is less appropriate when the drug is used in combination.

The results of the Etest studies indicate that this method could be an acceptable alternative to time–kill studies with antifungal agents. The technique employed for testing the antifungal combination was simple to use, time-efficient and yielded reproducible results. Unlike the findings with time–kill studies, FLU pre-exposure produced no discernible effect on the Etest results. It is possible that pre-exposure for 1 h with an azole in agar-based medium is sufficient for detecting polyene–azole antagonism. Unlike previous Etest work carried out with antibacterials, we opted not to place the Etest strips simultaneously on the agar at 90° angles.12 AMB and FLU exhibit different diffusion characteristics through agar, resulting in dissimilar ellipse patterns. Moreover, the growth endpoints used to measure the MIC by Etest are different for the two agents. Therefore, we felt interpretation of separate ellipses at 90° angles would be difficult. It may be possible to test antifungal combinations by incorporating azoles or 5FC into agar, but this would be time-consuming and the advantage of testing continuous gradients of antifungal concentrations would be lost.

In summary, our results indicate that Etest and time–kill methods correlate well for the testing of antifungal combinations. Chequerboard testing for antifungals, particularly those involving AMB in RPMI media, should be interpreted with caution, as this technique appears to display poor sensitivity for detecting changes in the activity of AMB. On the basis of our work, Etest appeared to be a good method for the in vitro testing of antifungal combinations, although more prolonged pre-exposure studies are required. Further studies utilizing different growth media, testing of novel antifungal combinations, synergy testing of azole-resistant yeast and the evaluation of antifungal combinations against moulds such as Aspergillus should be pursued with Etest methodology. Although the concentrations used in our studies reflect antifungal concentrations that can be achieved in human patients, the in vivo significance of our findings remains to be determined. Therefore, our in vitro results cannot be extrapolated to the clinical setting until better in vivo correlative data are available.



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Figure 1. Etest method for testing antifungal combinations. (a) Etest strip (Drug A) is placed on agar and removed after 1 h. (b) Second Etest strip (Drug B) is placed on agar over demarcation left from previous strip. (c) Additional Etest strips are applied (Drugs A and B), the plate is incubated and MICs are read at 24 and 48 h.

 

    Acknowledgements
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 Acknowledgements
 References
 
The authors thank Anne Bolmström for her technical expertise and provision of the Etest strips. This study was supported by a grant from the Society of Infectious Diseases Pharmacists/Pfizer Inc. Presented at the Thirty-ninth Interscience Conference on Antimicrobial Agents and Chemotherapy, San Francisco, CA, 1999.


    Notes
 
* Corresponding author. Tel: +1-713-795-8326; Fax: +1-713-795-8383; E-mail: rlewis{at}uh.edu Back


    References
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 Acknowledgements
 References
 
1 . Eliopolous, G. M. & Moellering, R. C. (1996). Antimicrobial combinations. In Antibiotics in Laboratory Medicine, 3rd edn, (Lorian, V., Ed.), pp. 330–96. Williams & Wilkins, Baltimore, MD.

2 . Klepser, M. E., Wolfe, E. J., Jones, R. N., Nightingale, C. H. & Pfaller, M. A. (1997). Antifungal pharmacodynamic characteristics of fluconazole and amphotericin B tested against Candida albicans. Antimicrobial Agents and Chemotherapy 41, 1392–5.[Abstract]

3 . Klepser, M. E., Wolfe, E. J. & Pfaller, M. A. (1998). Antifungal pharmacodynamic characteristics of fluconazole and amphotericin B against Cryptococcus neoformans. Journal of Antimicrobial Chemotherapy 41, 397–401.[Abstract]

4 . Lewis, R. E., Lund, B. C., Klepser, M. E., Ernst, E. J. & Pfaller, M. A. (1998). Assessment of antifungal activities of fluconazole and amphotericin B administered alone and in combination against Candida albicans by using a dynamic in vitro mycotic infection model. Antimicrobial Agents and Chemotherapy 42, 1382–6.[Abstract/Free Full Text]

5 . Ernst, E. J., Klepser, M. E. & Pfaller, M. A. (1998). In vitro interaction of fluconazole and amphotericin B administered sequentially against Candida albicans: effect of concentration and exposure time. Diagnostic Microbiology and Infectious Disease 32, 205–10.[ISI][Medline]

6 . Petrou, M. A. & Rogers, T. R. (1991). Interactions in vitro between polyenes and imidazoles against yeasts. Journal of Antimicrobial Chemotherapy 27, 491–506.[Abstract]

7 . Pfaller, M. A., Messer, S. A., Bolmstrom, A., Odds, F. C. & Rex, J. H. (1996). Multisite reproducibility of the Etest MIC method for antifungal susceptibility testing of yeast isolates. Journal of Clinical Microbiology 34, 1691–3.[Abstract]

8 . Pfaller, M. A., Messer, S. A. & Bolmstrom, A. (1998). Evaluation of Etest for determining in vitro susceptibility of yeast isolates to amphotericin B. Diagnostic Microbiology and Infectious Disease 32, 223–7.[ISI][Medline]

9 . Pfaller, M. A., Messer, S. A., Karlsson, A. & Bolmstrom, A. (1998). Evaluation of the Etest method for determining fluconazole susceptibilities of 402 clinical yeast isolates by using three different agar media. Journal of Clinical Microbiology 36, 2586–9.[Abstract/Free Full Text]

10 . Wanger, A., Mills, K., Nelson, P. W. & Rex, J. H. (1995). Comparison of Etest and National Committee for Clinical Laboratory Standards broth macrodilution method for antifungal susceptibility testing: enhanced ability to detect amphotericin B-resistant Candida isolates. Antimicrobial Agents and Chemotherapy 39, 2520–2.[Abstract]

11 . Warnock, D. W., Johnson, E. M. & Rogers, T. R. (1998). Multi-centre evaluation of the Etest method for antifungal drug susceptibility testing of Candida spp. and Cryptococcus neoformans. BSAC Working Party on Antifungal Chemotherapy. Journal of Antimicrobial Chemotherapy 42, 321–31.[Abstract]

12 . White, R. L., Burgess, D. S., Manduru, M. & Bosso, J. A. (1996). Comparison of three different in vitro methods of detecting synergy: time–kill, checkerboard, and E test. Antimicrobial Agents and Chemotherapy 40, 1914–8.[Abstract]

13 . Bolmström, A., Karlsson, Å., Nordström, U. & Mills, K. (1995). Etest for drug combination studies with mycobacteria. In Programs and Abstracts of the Nineteenth International Congress of Chemotherapy, Ontario, Canada, 1995. Abstract 1142, p. 318c. Pulses Group Inc., Oakville, CA, USA.

14 . National Committee for Clinical Laboratory Standards. (1997). Reference Method for Broth Dilution Antifungal Susceptibility Testing of Yeasts: Approved Standard M-27A. NCCLS, Villanova, PA.

15 . Pfaller, M., Gordee, R., Gerarden, T., Yu, M. & Wenzel, R. (1989). Fungicidal activity of cilofungin (LY121019) alone and in combination with anticapsin or other antifungal agents. European Journal of Clinical Microbiology and Infectious Diseases 8, 564–7.[ISI][Medline]

16 . American Society for Microbiology. (2000). Instructions to authors. Antimicrobial Agents and Chemotherapy 44, xvi.

17 . Klepser, M. E., Ernst, E. J., Lewis, R. E., Ernst, M. E. & Pfaller, M. A. (1998). Influence of test conditions on antifungal time–kill curve results: proposal for standardized methods. Antimicrobial Agents and Chemotherapy 42, 1207–12.[Abstract/Free Full Text]

18 . Rex, J. H., Pfaller, M. A., Galgiani, J. N., Bartlett, M. S., Espinel-Ingroff, A., Ghannoum, M. A. et al. (1997). Development of interpretive breakpoints for antifungal susceptibility testing: conceptual framework and analysis of in vitroin vivo correlation data for fluconazole, itraconazole, and Candida infections. Clinical Infectious Diseases 24, 235–47.[ISI][Medline]

Received 16 January 2001; returned 17 July 2001; revised 28 August 2001; accepted 31 October 2001