Evaluation of Disk Diffusion Method for Determining Posaconazole Susceptibility of Filamentous Fungi: Comparison with CLSI Broth Microdiluti
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《抗菌试剂及化学方法》
ABSTRACT
The disk diffusion method was evaluated for determining posaconazole susceptibility against 78 strains of molds using two culture media in comparison with the CLSI (Clinical Laboratory Standards Institute) broth microdilution method (M38-A). A significant correlation between disk diffusion and microdilution methods was observed with both culture media.
TEXT
Invasive infections due to Aspergillus spp. and other filamentous fungi (molds) have emerged as prominent causes of morbidity and mortality worldwide in immunocompromised hosts (2, 6-8, 14). Posaconazole is a water-insoluble investigational triazole with in vitro and in vivo activity against yeasts and molds (1, 3, 11, 15). The Clinical and Laboratory Standards Institute (CLSI; formerly the National Committee for Clinical Laboratory Standards) has developed a reference method for microdilution antifungal susceptibility testing of filamentous fungi (CLSI/NCCLS M38-A) (9). Agar-based methods such as Etest and disk diffusion can be good alternatives because they are simpler and faster than broth-based methods. Some investigators have explored the use of Etest susceptibility testing for posaconazole against filamentous fungi (4, 12), but data on posaconazole testing against molds by the disk diffusion method are lacking. In this study, we investigated the applicability of a disk diffusion method for testing the susceptibility of posaconazole against molds in order to compare the results that were obtained with this assay with those obtained by the broth microdilution method and to evaluate the influence of culture media.
A total of 78 clinical isolates were tested: 57 Aspergillus spp. (20 Aspergillus terreus, 16 Aspergillus fumigatus, 14 Aspergillus flavus, 4 Aspergillus niger, and 3 Aspergillus glaucus) and 21 other filamentous fungi (7 Rhizopus spp., 3 Mucor spp., 5 Scedosporium apiospermum, 3 Scedosporium prolificans, and 3 Fusarium spp.). These isolates were recovered from clinical specimens received in Valme University Hospital in Seville (Spain) and the La Fe University Hospital in Valence (Spain). The identification of each strain was performed using conventional mycological techniques. The mold isolates were maintained in sterile water and were subcultured on antimicrobial-agent-free potato dextrose agar (Difco) to ensure viability and purity. Stock inoculum suspensions were prepared from 7-day-old cultures grown on potato dextrose agar by following CLSI guidelines (document M38-A) (9). Stock suspensions were adjusted spectrophotometrically to optical densities that ranged from 0.09 to 0.11 (80 to 82% transmittance) and contained conidia or sporangiospores and hyphal fragments. The diluted (2x) inoculum sizes ranged from 0.9 x 104 to 4.7 x 104 CFU/ml, as demonstrated by a quantitative colony count on Sabouraud dextrose agar. The same inoculum was used for broth and agar methods.
The broth microdilution test was done in accordance with CLSI guidelines for conidium filamentous fungi (CLSI document M38-A) (9). Posaconazole was obtained from the Schering-Plough Research Institute (Kenilworth, N.J.), and it was dissolved in 100% dimethyl sulfoxide. The MICs were determined after 48 h of incubation. The MIC endpoints were evaluated for the lowest drug concentration that showed a prominent reduction of the growth control in the control well (50% or MIC-2) and the lowest drug concentration that showed absence of growth or complete growth inhibition (100% inhibition or MIC-0) (5).
The procedure for the disk diffusion method was mainly that of CLSI document M44-A (10). Posaconazole disks (5 μg, Oxoid) were used. The following culture media were tested: RPMI agar with 2% glucose (RPMI-G; Izasa, Spain) and Mueller-Hinton agar (Difco) supplemented with 2% glucose and methylene blue (0.5 mg/ml) (MHB) (10). The plates were incubated at 35°C and read at 24 and 48 h. The inhibition zones (IZs, in millimeters) were read at the point of marked decrease in fungal density (IZ-2) and the point of complete inhibition of growth (IZ-0).
A. fumigatus ATCC 204305, A. flavus ATCC 204304, Candida parapsilosis 22019, and Candida krusei 6258 were included in each susceptibility test for quality control and assessment of reproducibility.
For analysis of the results, geometric means (GM) and ranges of MICs and arithmetic means and ranges of IZ were calculated. To determine the correlation between the disk diffusion method and the microdilution method, the IZs were plotted against their respective MICs. Pearson's correlation coefficient was used to calculate a regression line for each comparison.
Table 1 shows the results of microdilution at 48 h and disk diffusion at 24 h except for Scedosporium spp., whose disk diffusion test results could be not interpreted at 24 h because of poor growth. Disk diffusion test results for Mucorales could not be interpreted in RPMI agar and MHB at 48 h because they showed overgrowth, and no inhibition zone was observed. For Aspergillus spp., Fusarium spp., and S. prolificans, the MIC-0 and the IZ-0 were in agreement with the MIC-2 and IZ-2, respectively, while for Mucorales, a difference of 2 to 10 mm between the IZ-0 and IZ-2 was observed. The GM of the MICs were low for Aspergillus spp. and Mucorales (0.31 μg/ml) and for S. apiospermum (1); for Fusarium spp. and S. prolificans, the GM of the MICs were high (8 μg/ml). The MIC results for control strains that were obtained by the microdilution method at 48 h were 0.03 μg/ml for C. parapsilosis 22019, 0.25 μg/ml for C. krusei 6258, 0.06 μg/ml for A. fumigatus ATCC 204305, and 0.06 μg/ml for A. flavus ATCC 204304. These results are within the MIC range limits recommended by the M38-A document (9). The respective MIC results that were obtained by the disk diffusion method at 24 h in two media, RPMI-G and MHB, were 34 and 30 mm for C. parapsilosis 22019, 32 and 27 mm for C. krusei 6258, 27 and 30 mm for A. fumigatus ATCC 204305, and 27 and 30 mm for A. flavus ATCC 204304. The respective results obtained at 48 h were 33 and 30 mm for C. parapsilosis 22019, 30 and 24 mm for C. krusei 6258, 25 and 29 mm for A. fumigatus ATCC 204305, and 25 and 29 mm for A. flavus ATCC 204304. The regression statistics are shown in Fig. 1 through 4, which demonstrate the excellent correlation between the 24- and 48-h IZ-0 results relative to the 48-h MIC-0 results. When all strains were considered together, the results for IZ-0 that were obtained with the two media were not significantly different. The results for IZ-0 that were obtained by disk diffusion showed an inverse correlation with those that were obtained with MICs by the microdilution method. (Values for R [Pearson's correlation] are as follows: RPMI-G 24 [correlation between 24-h zones of inhibition {mm} determined by RPMI-G with 48-h MICs by microdilution method], –0.690; RPMI-G 48, –0.803; MHB 24, –0.722; MHB 48, –0.746.) Similarly, no differences were found between the IZ-0 results that were obtained with MHB when each species was studied separately, except for Scedosporium spp., which showed no growth at 24 h in RPMI-G but showed a good growth in MHB. For Aspergillus isolates, lower MICs correlated with the production of measurable IZs-0 around the posaconazole disks. No diameter pattern was observed to differentiate the Aspergillus species. For Fusarium spp. and S. prolificans, the comparison of the results that were obtained by the microdilution and disk diffusion assays showed that the high MICs obtained by the microdilution method correlated very well with the absence of IZs on disk diffusion agar plates in both media.
To our knowledge, this is the first report that uses the disk diffusion assay for susceptibility testing of posaconazole against filamentous fungi isolates and which compares the results with the microdilution method. For this reason, our results are difficult to compare with those of other authors who also tested filamentous fungi, because they used other drugs. Although the CLSI recommends using Mueller-Hinton medium for the agar test to yeasts, there is no agreement on the medium to use for filamentous fungi and as a consequence, in this work, we have evaluated two media. The disk diffusion results in RPMI-G and MHB showed a good correlation with those obtained by the CLSI method. Similar results were obtained for voriconazole against Aspergillus spp. by Serrano et al. (13) with MHB. The disk diffusion method is less labor intensive than the broth microdilution method and it is an attractive alternative for determining susceptibility to posaconazole because of its simplicity and low cost. Besides, it allows us to obtain the results earlier because it is possible to do the reading at 24 h of incubation. However the inability of RPMI-G to determine the susceptibility test result at 24 h for Scedosporium spp. appears to be a limitation of this medium. Additional studies with a higher number of strains are needed.
In this study, we obtained a good correlation between both methods. However, the utility of the disk diffusion method will depend on the MIC breakpoints that are selected and their corresponding diameter zone ranges. Further studies would be necessary to determine the interpretive criteria for both methods and to establish the correlation with in vivo response.
EFERENCES
Cacciapuoti, A., D. Loebenberg, E. Corcoran, F. Menzel, Jr., E. L. Moss, Jr., C. Norris, M. Michalski, K. Raynor, J. Halpern, C. Mendrick, B. Arnold, B. Antonacci, R. Parmegiani, T. Yarosh-Tomaine, G. H. Miller, and R. S. Hare. 2000. In vitro and in vivo activities of SCH 56592 (posaconazole), a new triazole antifungal agent, against Aspergillus and Candida. Antimicrob. Agents Chemother. 44:2017-2022.
Denning, D. W., A. Marinas, J. Cohen, D. Spence, R. Herbrecht, L. Pagano, C. Kibbler, V. Kcrmery, F. Offner, C. Cordonnier, U. Jehn, M. Ellis, L. Collete, R. Sylvester, et al. 1998. An EORTC multicentre prospective survey of invasive aspergillosis in haematological patients: diagnosis and therapeutic outcome. J. Infect. 37:173-180.
Espinel-Ingroff, A. 1998. Comparison of in vitro activities of the new triazole SCH56592 and the echinocandins MK-0991 (L-743,872) and LY303366 against opportunistic filamentous and dimorphic fungi and yeasts. J. Clin. Microbiol. 36:2950-2956.
Espinel-Ingroff, A., and A. Rezusta. 2002. E-test method for testing susceptibilities of Aspergillus spp. to new triazoles voriconazole and posaconazole and to established antifungal agents: comparison with the NCCLS broth microdilution method. J. Clin. Microbiol. 40:2101-2107.
Espinel-Ingroff, A., M. Barlett, V. Chaturvedi, M. Ghannoum, K. C. Hazen, M. A. Pfaller, M. Rinaldi, and T. J. Walsh. 2001. Optimal susceptibility testing conditions for detection of azole resistance in Aspergillus spp: NCCLS collaborative evaluation. Antimicrob. Agents Chemother. 45:1828-1835.
Groll, A. H., and T. J. Walsh. 2001. Uncommon opportunistic fungi: new nosocomial threats. Clin. Microbiol. Infect. 7(Suppl. 2):8-24.
Marr, K. A., R. A. Carter, F. Crippa, A. Wald, and L. Corey. 2002. Epidemiology and outcome of mould infections in hematopoietic stem cell transplant recipients. Clin. Infect. Dis. 34:909-917.
McNeil, M. M., S. L. Nash, R. A. Hajjeh, M. A. Phelan, L. A. Conn, B. D. Plikalytin, and D. W. Warnock. 2001. Trends in mortality due to invasive mycotic diseases in the United States, 1980-1997. Clin. Infect. Dis. 33:641-647.
National Committee for Clinical Laboratory Standards. 2002. Reference method for broth dilution antifungal susceptibility testing of filamentous fungi. Approved standard M38-A. National Committee for Clinical Laboratory Standards, Wayne, Pa.
National Committee for Clinical Laboratory Standards. 2004. Method for antifungal disk diffusion susceptibility testing of yeasts: NCCLS document M44-A. National Committee for Clinical Laboratory Standards, Wayne, Pa.
Oakley, K. L., C. B. Moore, and D. W. Denning. 1997. In vitro activity of SCH56592 and comparison with activities of amphotericin B and itraconazole against Aspergillus spp. Antimicrob. Agents Chemother. 41:1124-1126.
Pfaller, M. A., S. A. Messer, L. Boyken, R. J. Hollis, and D. J. Dikema. 2003. In vitro susceptibility testing of filamentous fungi: comparison of E-test and reference M38-A microdilution methods for determining posaconazole MICs. Diagn. Microbiol. Infect. Dis. 45:241-244.
Serrano, M. C., M. Ramírez, D. Morilla, A. Valverde, M. Chavez, A. Espinel-Ingroff, R. Claro, A. Fernandez, C. Almeida, and E. Martín Mazuelos. 2004. A comparative study of the disc diffusion method with the broth microdilution and Etest methods for voriconazole susceptibility testing of Aspergillus spp. J. Antimicrob. Chemother. 53:739-742.
Singh, N., and D. L. Paterson. 2005. Aspergillus infections in transplant recipients. Clin. Microbiol. Rev. 18:44-69.
Sun, Q. N., L. K. Najvar, R. Bocanegra, D. Lobennerg, and J. R. Graybill. 2002. In vivo activity of posaconazole against Mucor spp. in an immunosuppressed-mouse model. Antimicrob. Agents Chemother. 46:2310-2312.
S. Microbiología,S. Bioestadística, U. Investigacion, Valme University Hospital, Seville, Spain, La Fe University Hospital, Valencia, Spain.(E. Lopez-Oviedo, A. I. Al)
The disk diffusion method was evaluated for determining posaconazole susceptibility against 78 strains of molds using two culture media in comparison with the CLSI (Clinical Laboratory Standards Institute) broth microdilution method (M38-A). A significant correlation between disk diffusion and microdilution methods was observed with both culture media.
TEXT
Invasive infections due to Aspergillus spp. and other filamentous fungi (molds) have emerged as prominent causes of morbidity and mortality worldwide in immunocompromised hosts (2, 6-8, 14). Posaconazole is a water-insoluble investigational triazole with in vitro and in vivo activity against yeasts and molds (1, 3, 11, 15). The Clinical and Laboratory Standards Institute (CLSI; formerly the National Committee for Clinical Laboratory Standards) has developed a reference method for microdilution antifungal susceptibility testing of filamentous fungi (CLSI/NCCLS M38-A) (9). Agar-based methods such as Etest and disk diffusion can be good alternatives because they are simpler and faster than broth-based methods. Some investigators have explored the use of Etest susceptibility testing for posaconazole against filamentous fungi (4, 12), but data on posaconazole testing against molds by the disk diffusion method are lacking. In this study, we investigated the applicability of a disk diffusion method for testing the susceptibility of posaconazole against molds in order to compare the results that were obtained with this assay with those obtained by the broth microdilution method and to evaluate the influence of culture media.
A total of 78 clinical isolates were tested: 57 Aspergillus spp. (20 Aspergillus terreus, 16 Aspergillus fumigatus, 14 Aspergillus flavus, 4 Aspergillus niger, and 3 Aspergillus glaucus) and 21 other filamentous fungi (7 Rhizopus spp., 3 Mucor spp., 5 Scedosporium apiospermum, 3 Scedosporium prolificans, and 3 Fusarium spp.). These isolates were recovered from clinical specimens received in Valme University Hospital in Seville (Spain) and the La Fe University Hospital in Valence (Spain). The identification of each strain was performed using conventional mycological techniques. The mold isolates were maintained in sterile water and were subcultured on antimicrobial-agent-free potato dextrose agar (Difco) to ensure viability and purity. Stock inoculum suspensions were prepared from 7-day-old cultures grown on potato dextrose agar by following CLSI guidelines (document M38-A) (9). Stock suspensions were adjusted spectrophotometrically to optical densities that ranged from 0.09 to 0.11 (80 to 82% transmittance) and contained conidia or sporangiospores and hyphal fragments. The diluted (2x) inoculum sizes ranged from 0.9 x 104 to 4.7 x 104 CFU/ml, as demonstrated by a quantitative colony count on Sabouraud dextrose agar. The same inoculum was used for broth and agar methods.
The broth microdilution test was done in accordance with CLSI guidelines for conidium filamentous fungi (CLSI document M38-A) (9). Posaconazole was obtained from the Schering-Plough Research Institute (Kenilworth, N.J.), and it was dissolved in 100% dimethyl sulfoxide. The MICs were determined after 48 h of incubation. The MIC endpoints were evaluated for the lowest drug concentration that showed a prominent reduction of the growth control in the control well (50% or MIC-2) and the lowest drug concentration that showed absence of growth or complete growth inhibition (100% inhibition or MIC-0) (5).
The procedure for the disk diffusion method was mainly that of CLSI document M44-A (10). Posaconazole disks (5 μg, Oxoid) were used. The following culture media were tested: RPMI agar with 2% glucose (RPMI-G; Izasa, Spain) and Mueller-Hinton agar (Difco) supplemented with 2% glucose and methylene blue (0.5 mg/ml) (MHB) (10). The plates were incubated at 35°C and read at 24 and 48 h. The inhibition zones (IZs, in millimeters) were read at the point of marked decrease in fungal density (IZ-2) and the point of complete inhibition of growth (IZ-0).
A. fumigatus ATCC 204305, A. flavus ATCC 204304, Candida parapsilosis 22019, and Candida krusei 6258 were included in each susceptibility test for quality control and assessment of reproducibility.
For analysis of the results, geometric means (GM) and ranges of MICs and arithmetic means and ranges of IZ were calculated. To determine the correlation between the disk diffusion method and the microdilution method, the IZs were plotted against their respective MICs. Pearson's correlation coefficient was used to calculate a regression line for each comparison.
Table 1 shows the results of microdilution at 48 h and disk diffusion at 24 h except for Scedosporium spp., whose disk diffusion test results could be not interpreted at 24 h because of poor growth. Disk diffusion test results for Mucorales could not be interpreted in RPMI agar and MHB at 48 h because they showed overgrowth, and no inhibition zone was observed. For Aspergillus spp., Fusarium spp., and S. prolificans, the MIC-0 and the IZ-0 were in agreement with the MIC-2 and IZ-2, respectively, while for Mucorales, a difference of 2 to 10 mm between the IZ-0 and IZ-2 was observed. The GM of the MICs were low for Aspergillus spp. and Mucorales (0.31 μg/ml) and for S. apiospermum (1); for Fusarium spp. and S. prolificans, the GM of the MICs were high (8 μg/ml). The MIC results for control strains that were obtained by the microdilution method at 48 h were 0.03 μg/ml for C. parapsilosis 22019, 0.25 μg/ml for C. krusei 6258, 0.06 μg/ml for A. fumigatus ATCC 204305, and 0.06 μg/ml for A. flavus ATCC 204304. These results are within the MIC range limits recommended by the M38-A document (9). The respective MIC results that were obtained by the disk diffusion method at 24 h in two media, RPMI-G and MHB, were 34 and 30 mm for C. parapsilosis 22019, 32 and 27 mm for C. krusei 6258, 27 and 30 mm for A. fumigatus ATCC 204305, and 27 and 30 mm for A. flavus ATCC 204304. The respective results obtained at 48 h were 33 and 30 mm for C. parapsilosis 22019, 30 and 24 mm for C. krusei 6258, 25 and 29 mm for A. fumigatus ATCC 204305, and 25 and 29 mm for A. flavus ATCC 204304. The regression statistics are shown in Fig. 1 through 4, which demonstrate the excellent correlation between the 24- and 48-h IZ-0 results relative to the 48-h MIC-0 results. When all strains were considered together, the results for IZ-0 that were obtained with the two media were not significantly different. The results for IZ-0 that were obtained by disk diffusion showed an inverse correlation with those that were obtained with MICs by the microdilution method. (Values for R [Pearson's correlation] are as follows: RPMI-G 24 [correlation between 24-h zones of inhibition {mm} determined by RPMI-G with 48-h MICs by microdilution method], –0.690; RPMI-G 48, –0.803; MHB 24, –0.722; MHB 48, –0.746.) Similarly, no differences were found between the IZ-0 results that were obtained with MHB when each species was studied separately, except for Scedosporium spp., which showed no growth at 24 h in RPMI-G but showed a good growth in MHB. For Aspergillus isolates, lower MICs correlated with the production of measurable IZs-0 around the posaconazole disks. No diameter pattern was observed to differentiate the Aspergillus species. For Fusarium spp. and S. prolificans, the comparison of the results that were obtained by the microdilution and disk diffusion assays showed that the high MICs obtained by the microdilution method correlated very well with the absence of IZs on disk diffusion agar plates in both media.
To our knowledge, this is the first report that uses the disk diffusion assay for susceptibility testing of posaconazole against filamentous fungi isolates and which compares the results with the microdilution method. For this reason, our results are difficult to compare with those of other authors who also tested filamentous fungi, because they used other drugs. Although the CLSI recommends using Mueller-Hinton medium for the agar test to yeasts, there is no agreement on the medium to use for filamentous fungi and as a consequence, in this work, we have evaluated two media. The disk diffusion results in RPMI-G and MHB showed a good correlation with those obtained by the CLSI method. Similar results were obtained for voriconazole against Aspergillus spp. by Serrano et al. (13) with MHB. The disk diffusion method is less labor intensive than the broth microdilution method and it is an attractive alternative for determining susceptibility to posaconazole because of its simplicity and low cost. Besides, it allows us to obtain the results earlier because it is possible to do the reading at 24 h of incubation. However the inability of RPMI-G to determine the susceptibility test result at 24 h for Scedosporium spp. appears to be a limitation of this medium. Additional studies with a higher number of strains are needed.
In this study, we obtained a good correlation between both methods. However, the utility of the disk diffusion method will depend on the MIC breakpoints that are selected and their corresponding diameter zone ranges. Further studies would be necessary to determine the interpretive criteria for both methods and to establish the correlation with in vivo response.
EFERENCES
Cacciapuoti, A., D. Loebenberg, E. Corcoran, F. Menzel, Jr., E. L. Moss, Jr., C. Norris, M. Michalski, K. Raynor, J. Halpern, C. Mendrick, B. Arnold, B. Antonacci, R. Parmegiani, T. Yarosh-Tomaine, G. H. Miller, and R. S. Hare. 2000. In vitro and in vivo activities of SCH 56592 (posaconazole), a new triazole antifungal agent, against Aspergillus and Candida. Antimicrob. Agents Chemother. 44:2017-2022.
Denning, D. W., A. Marinas, J. Cohen, D. Spence, R. Herbrecht, L. Pagano, C. Kibbler, V. Kcrmery, F. Offner, C. Cordonnier, U. Jehn, M. Ellis, L. Collete, R. Sylvester, et al. 1998. An EORTC multicentre prospective survey of invasive aspergillosis in haematological patients: diagnosis and therapeutic outcome. J. Infect. 37:173-180.
Espinel-Ingroff, A. 1998. Comparison of in vitro activities of the new triazole SCH56592 and the echinocandins MK-0991 (L-743,872) and LY303366 against opportunistic filamentous and dimorphic fungi and yeasts. J. Clin. Microbiol. 36:2950-2956.
Espinel-Ingroff, A., and A. Rezusta. 2002. E-test method for testing susceptibilities of Aspergillus spp. to new triazoles voriconazole and posaconazole and to established antifungal agents: comparison with the NCCLS broth microdilution method. J. Clin. Microbiol. 40:2101-2107.
Espinel-Ingroff, A., M. Barlett, V. Chaturvedi, M. Ghannoum, K. C. Hazen, M. A. Pfaller, M. Rinaldi, and T. J. Walsh. 2001. Optimal susceptibility testing conditions for detection of azole resistance in Aspergillus spp: NCCLS collaborative evaluation. Antimicrob. Agents Chemother. 45:1828-1835.
Groll, A. H., and T. J. Walsh. 2001. Uncommon opportunistic fungi: new nosocomial threats. Clin. Microbiol. Infect. 7(Suppl. 2):8-24.
Marr, K. A., R. A. Carter, F. Crippa, A. Wald, and L. Corey. 2002. Epidemiology and outcome of mould infections in hematopoietic stem cell transplant recipients. Clin. Infect. Dis. 34:909-917.
McNeil, M. M., S. L. Nash, R. A. Hajjeh, M. A. Phelan, L. A. Conn, B. D. Plikalytin, and D. W. Warnock. 2001. Trends in mortality due to invasive mycotic diseases in the United States, 1980-1997. Clin. Infect. Dis. 33:641-647.
National Committee for Clinical Laboratory Standards. 2002. Reference method for broth dilution antifungal susceptibility testing of filamentous fungi. Approved standard M38-A. National Committee for Clinical Laboratory Standards, Wayne, Pa.
National Committee for Clinical Laboratory Standards. 2004. Method for antifungal disk diffusion susceptibility testing of yeasts: NCCLS document M44-A. National Committee for Clinical Laboratory Standards, Wayne, Pa.
Oakley, K. L., C. B. Moore, and D. W. Denning. 1997. In vitro activity of SCH56592 and comparison with activities of amphotericin B and itraconazole against Aspergillus spp. Antimicrob. Agents Chemother. 41:1124-1126.
Pfaller, M. A., S. A. Messer, L. Boyken, R. J. Hollis, and D. J. Dikema. 2003. In vitro susceptibility testing of filamentous fungi: comparison of E-test and reference M38-A microdilution methods for determining posaconazole MICs. Diagn. Microbiol. Infect. Dis. 45:241-244.
Serrano, M. C., M. Ramírez, D. Morilla, A. Valverde, M. Chavez, A. Espinel-Ingroff, R. Claro, A. Fernandez, C. Almeida, and E. Martín Mazuelos. 2004. A comparative study of the disc diffusion method with the broth microdilution and Etest methods for voriconazole susceptibility testing of Aspergillus spp. J. Antimicrob. Chemother. 53:739-742.
Singh, N., and D. L. Paterson. 2005. Aspergillus infections in transplant recipients. Clin. Microbiol. Rev. 18:44-69.
Sun, Q. N., L. K. Najvar, R. Bocanegra, D. Lobennerg, and J. R. Graybill. 2002. In vivo activity of posaconazole against Mucor spp. in an immunosuppressed-mouse model. Antimicrob. Agents Chemother. 46:2310-2312.
S. Microbiología,S. Bioestadística, U. Investigacion, Valme University Hospital, Seville, Spain, La Fe University Hospital, Valencia, Spain.(E. Lopez-Oviedo, A. I. Al)