1 Department of Medical Microbiology, University Medical Center Nijmegen, PO Box 9101, 6500 HB Nijmegen; 2 Nijmegen University Center for Infectious Diseases, Nijmegen; 3 Department of Medical Microbiology and Infectious Diseases, Canisius Wilhelmina Hospital, Nijmegen, The Netherlands
Received 13 December 2002; returned 9 March 2003; revised 14 April 2003; accepted 14 April 2003
![]() |
Abstract |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Keywords: PAFE, zygomycetes, amphotericin B, nystatin
![]() |
Introduction |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Treatment of zygomycosis requires surgical intervention, antifungal therapy and resolution of the underlying immunocompromised condition. Amphotericin B remains the first-line choice of treatment for infections due to zygomycetes. However, the clinical response is poor, especially in patients with disseminated disease.2 Triazoles and allylamines exhibit some in vitro activity against this class of fungi,4 but these agents are not used clinically. Nystatin exhibits good in vitro activity, but no clinical data are available to confirm in vivo activity.
Post-drug exposure effects are important to understand and optimize drug efficacy in vivo. We have developed an in vitro model that enables the study of post-antifungal effects (PAFEs) in filamentous fungi.5 The aim of the present study was to evaluate the PAFE induced by the polyenes amphotericin B and nystatin against zygomycetes and to compare the PAFE in two different media.
![]() |
Materials and methods |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Thirty strains from our private collection were evaluated: A. corymbifera (AZN 24, AZN 319, AZN 911, AZN 1184, AZN 2134, AZN 2543, AZN 3113, AZN 3114, AZN 4095, AZN 6429); Rhizopus oryzae (AZN 593, AZN 1523, AZN 3440, AZN5618, AZN 6142, AZN 6373, AZN 1925); Rhizopus microsporus (AZN 23, AZN 190, AZN 410, AZN 1185, AZN 5005, AZN 5816, AZN 8894); Rhizomucor miehei AZN 4839; Rhizomucor pusillus AZN 22; Mucor hiemalis (AZN 21, AZN 175, AZN 1379) and Mucor rouxii AZN 1183.
Antifungal agents
Amphotericin B (Bristol-Myers Squibb, Woerden, The Netherlands) and Nystatin (Gist-Brocades, Delft, The Netherlands) were utilized for MIC determinations and PAFE studies. The drugs were dissolved in dimethyl sulphoxide (DMSO) and aliquots of the stock solution were stored at 70°C until use. Then they were diluted in RPMI-1640 medium (with L-glutamine, without bicarbonate) (Gibco BRL, Life Technologies, Woerden, The Netherlands) and Antibiotic Medium 3 (AM3) (BBL/Becton Dickinson, Cockeysville, MD, USA), both buffered to pH 7.0 with 0.165 M MOPS (SigmaAldrich Chemie GmbH, Steinheim, Germany).
Antifungal susceptibility testing
The isolates were passaged twice at an interval of 57 days at 28°C by subculturing onto Sabouraud glucose agar (SGA) to obtain adequate sporulation. Spores were collected with a cotton swab and suspended in saline with 0.01% Tween 80. The resulting spore suspensions were counted with a haemocytometer and diluted in RPMI-1640 or AM3 1:100 in order to obtain a final inoculum of 15 x 104 spores per mL. The viability was confirmed by plating serial dilutions onto SGA plates.
Amphotericin B and nystatin were dissolved in DMSO at concentrations of 3200 mg/L. Two-fold serial dilutions of the drugs were made in RPMI-1640 and AM3 medium in order to obtain final concentrations of both drugs that ranged from 0.015 to 16 mg/L. A drug-free well containing 0.01% DMSO in the medium served as the growth control. The tests were carried out in 96-well flat-bottomed microtitration plates (Corning), which were kept at 70°C until the day of testing. After the inoculation, the microtitration plates were incubated at 35°C for 48 h. The MICs were read by spectrophotometric reader (Rosys Anthos ht3, Anthos Labtex Instruments GmbH, Salzburg, Austria). Background optical density (OD) was measured spectrophotometrically in non-inoculated wells processed in the same way as the inoculated wells. The relative ODs for each well based on measurements at 405 nm were calculated (as percentages) based on the following equation: [(OD of drug-containing well background OD)/(OD of drug-free well background OD)] x 100%. The MIC of both drugs was defined as the lowest concentration of the drug that showed at least 95% reduction of growth compared with that of the growth control (MIC-0).
PAFE assay
The method used to determine PAFE was recently described for Aspergillus spp.5 Amphotericin B and nystatin were dissolved in DMSO at initial concentrations of 400 mg/L and aliquots of the stock solution were stored at 70°C until use. Then they were diluted 50 times in RPMI-1640 (with L-glutamine without bicarbonate) or AM3 medium buffered to pH 7.0 with 0.165 M MOPS. Serial dilutions of the drugs were made in both media in order to obtain final concentrations of 4, 1 and 0.5 times the corresponding MIC. Control spore suspensions were made in RPMI-1640 and AM3 without drug. The isolates were passaged twice at an interval of 57 days at 28°C by subculturing onto SGA to obtain adequate sporulation. Spores were collected with a cotton swab and suspended in saline with 0.01% Tween 80. After the heavy particles had been allowed to settle, the supernatant was transferred to another tube, vortexed for 10 s, and 10 and 100 times dilutions were made. The concentration of spores was established microscopically using haemocytometer Burker Turk chambers. Then, the concentration was adjusted to obtain 4 x 105 spores/mL. One millilitre of this suspension was added to tubes containing 9 mL of RPMI-1640 or AM3 alone (control) or with amphotericin B or nystatin in concentrations mentioned above resulting in a final volume of 10 mL. The final inoculum therefore was 4 x 104 cfu/mL. Following this procedure, each strain was incubated for 4 or 1 h with continuous shaking at 37°C.
After incubation, the spores were washed with saline plus 0.01% Tween 80 and centrifuged at 3500g for 15 min. After three wash cycles, 98% of the supernatant was completely decanted and the pellets were resuspended in a final volume of 10 mL of RPMI-1640 or AM3 with 0.01% Tween 80. Following this step, 100 µL of sample was diluted 10-fold in sterile water and 30 µL aliquots were plated onto SGA plates for colony count determination, and incubated at 37°C for 24 h. The concentration of viable cfu/mL for exposed spores was determined in order to verify the concentration of viable spores post-drug exposure and to allow adjustment of the inoculum, if necessary, to match that of controls. From the resuspended suspension, 200 µL was placed in microtitration plates and incubated at 37°C in a computerized spectrophotometric reader (Rosys Anthos ht3). Any growth was automatically monitored in terms of change in turbidity at 405 nm, at 10 min intervals for 48 h. All assays were carried out in duplicate.
Data analysis
The repetitive OD measurements for each well resulted in the growth curve. PAFE was determined by comparing the growth curve of the exposed spores with that of the controls. The first increase in OD (OD0) was used to calculate PAFE as previously described,5 by using the formula PAFE = T C, where T was the time of the first significant increase in OD0 of the exposed spores after removal of the drug and C was the time of the first significant increase in OD0 of the control. Thus, PAFE was defined as the difference in time (t) between exposed and controls to reach the defined point in the growth curve and was expressed in hours. The time to reach this chosen point, OD0, of at least eight controls for each species was calculated and the mean, range, upper 95% confidence interval (CI) and the coefficient of variance were calculated in order to determine the reproducibility of the control curves at that point and to establish the reproducibility of the experiments. For each species, the upper 95% CI of the controls was chosen as the cut-off level that distinguished between the presence or absence of PAFE. When re-growth of the exposed isolates occurred within the upper 95% CI time-frame of the controls, PAFE was considered to be absent. Alternatively, if re-growth was delayed following drug exposure and the lower 95% CI of the exposed isolates was delayed until beyond the upper 95% CI of the controls, PAFE was considered to be present. Growth curves of each exposed isolate were compared only with pooled controls from that same isolate.
Comparisons of PAFE between both media and both drugs were analysed by analysis of variance for repeated observations followed by Bonferronis Multiple Comparison Tests. P values of <0.05 were considered statistically significant.
![]() |
Results |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
For AM3 the MICs of amphotericin B ranged from 0.063 to 2 mg/L (A. corymbifera 0.1251 mg/L; R. oryzae 0.52 mg/L; R. microsporus 0.252 mg/L; R. miehei 0.063 mg/L; R. pusillus 0.125 mg/L; M. hiemalis 0.250.5 mg/L and M. rouxii 0.063 mg/L) and for nystatin from 0.5 to 4 mg/L (A. corymbifera 0.52 mg/L; R. oryzae 14 mg/L; R. microsporus 12 mg/L; R. miehei 0.5 mg/L; R. pusillus 1 mg/L; M. hiemalis 0.51 mg/L and M. rouxii 0.5 mg/L).
Viability of the spores
Exposure of spores for 1 to 4 h to the concentrations of amphotericin B and nystatin used had no effect on the viability of the A. corymbifera isolates, but for the other genera tested both drugs induced fungicidal activity after 4 or 1 h of incubation at a concentration of four times the MIC (Figure 1). Therefore, PAFE was determined for 1 h exposure at 1 and 0.5 times the corresponding MIC for these genera. Under these conditions, killing was not observed for the concentration and exposure time chosen based on subculture of serial two-fold dilutions (data not shown).
|
By using a haemocytometer chamber, a limited range of 2 to 4 x 104 viable cfu/mL was achieved.
PAFE assay
All growth curves were reproducible among the replicates. For the same species, the shape of the growth curve of the control was identical to that of the exposed strains. When PAFE was present the growth curve of the exposed spores was shifted to the right compared with that of the control. Examples of growth curves for A. corymbifera and R. oryzae are shown in Figure 2.
|
Microscopic examination of the spores before and after drug exposure showed that germination did not occur within the maximal exposure period of 4 h for Absidia and 1 h for the other species in both media. In RPMI-1640 even after 5 h of incubation germination had not occurred for control or exposed spores for any of the genera. However, in AM3, spores of Rhizopus started to germinate after 3 h, and after 5 h 100% of spores had germinated. For Absidia 80% of spores had germinated after 5 h of incubation. Germination of controls and drug exposed spores occurred at the same time and to the same extent in those strains where PAFE was not present. When PAFE was present, germination of spores was further delayed.
Microscopic examination of the moulds at different time intervals post-drug exposure revealed that increase in OD correlated with the development of hyphae as described previously.6 No differences in morphology were noted between exposed and non-exposed fungi.
The variability in OD among the control and exposed isolates, expressed as coefficient of variation (CV), was <13%.
PAFE was induced by both drugs in both media for all strains tested with the exception of Rhizomucor spp. (Table 1). PAFE was induced by amphotericin B after 4 or 1 h of exposure for the 10 A. corymbifera and for the seven R. oryzae strains for all the conditions tested (Table 1).
|
In general, amphotericin B induced longer PAFE compared with nystatin: 4.6 h for amphotericin B versus 2.9 h for nystatin in RPMI-1640 (P < 0.05), and 4.3 h versus 3 h for amphotericin B and nystatin, respectively, in AM3 (P < 0.05). No statistically significant difference was observed for amphotericin B and nystatin between both media (P > 0.05), with the exception of low concentrations of nystatin (Table 2).
|
All A. corymbifera strains displayed PAFE for both drugs at 4 x and 1 x MIC after 4 h exposure in the same medium. However, for nystatin, longer PAFEs in AM3 were seen for both concentrations compared with RPMI-1640 (Table 1). PAFE was not induced by amphotericin B or nystatin after 1 h exposure (data not shown). For Rhizopus spp. no differences in PAFE values were seen when both drugs were compared. Both drugs tended to induce longer PAFE in R. oryzae compared with R. microsporus (Table 1). For Mucor spp. nystatin tended to induce longer PAFE values than with amphotericin B in the same medium. This observation was only found for this genus. Both amphotericin B and nystatin failed to induce PAFE in Rhizomucor strains.
Sub-MIC exposure
A. corymbifera did not display any PAFE in contrast to the other genera where most showed significant PAFE values. For amphotericin B, Rhizopus spp. and Mucor spp. displayed PAFE in RPMI-1640, but in AM3 only Mucor spp. did not show the effect.
For nystatin, Rhizopus spp. and Mucor spp. displayed PAFE in RPMI-1640, but in AM3 only R. microsporus did not show the effect.
![]() |
Discussion |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
The exposure of Absidia spores to amphotericin B or nystatin did not affect the viability of the spores at any of the concentrations or incubation periods tested. This finding was similar to that observed for Aspergillus species, where viability was not affected by exposure of the conidia to amphotericin B.5 However, exposure of the other genera of zygomycetes at concentrations above the MIC resulted in a significant decrease in viability indicating rapid fungicidal activity. Rapid fungicidal activity was observed previously for Candida at concentrations of amphotericin B above the MIC.7
Post-antibiotic effects have been found to be dependent on several factors such as the concentration of the antibiotic, exposure time, media used and pH.8 In zygomycetes, PAFE appears also to depend on the class of drugs, concentration and duration of exposure, as was previously described for Candida and Aspergillus species.5,9
The nutrient medium is a major factor that influences the results of in vitro susceptibility tests.10 RPMI-1640 has been evaluated extensively for in vitro susceptibility testing of yeasts and moulds and has been shown to give reproducible results.1113 AM3 has been shown to discriminate better between Candida strains susceptible and resistant to amphotericin B,14 although there are no data that show that this is also the case for zygomycetes. Since batch-to-batch variation was described for the in vitro testing of antifungal agents with AM3, a single batch was used in the present study. In our evaluation PAFE was observed for both media, indicating that the effect was not dependent on the media used.
In general, PAFE was similar in RPMI-1640 and AM3 for both drugs with the exception of A. corymbifera for which nystatin tended to induce longer PAFE in AM3 than in RPMI-1640.
Amphotericin B and nystatin belong to the polyenes, which have a broad fungicidal spectrum in vitro. As a result of problems of solubilization and toxicity, parenteral administration of nystatin is not used for systemic treatment.15 However, the incorporation of this drug in liposomes reduced toxicity and preserved antifungal activity.16 Intravenous liposomal nystatin studied in rabbits displayed non-linear pharmacokinetics, potentially therapeutic peak plasma concentrations and substantial penetration in tissues. After multiple dosing over 15 days, the maximum concentrations in µg/g (mean) were: in lung (72.84); liver (41.26); spleen (46.57); kidney (22.85) with a plasma concentration of 34.74 mg/L.17
When studying the relationship between drug concentration and antimicrobial effect, the time course of antifungal activity of polyenes is characterized by concentration-dependent killing, i.e. enhanced microbial killing by increasing drug levels, and long PAFE.18 Although this relationship was studied with conventional amphotericin B, it has been demonstrated with antibacterial drugs that specific pharmacodynamic parameters predictive of activity vary for different drug classes but not for drugs within a class.18 This was confirmed in the present study where amphotericin B and nystatin, both polyenes, showed comparable PAFE characteristics against zygomycetes. It can be assumed that the same is true for lipid-formulations of amphotericin B since the active compound is amphotericin B.
The interpretation of our results can only be meaningful if drug levels that induce PAFE in vitro are within the range achievable in humans. Although serum concentrations of conventional amphotericin B are generally below 2 mg/L, higher levels have been found at the site of infection.19,20 The association between dosing of conventional amphotericin B and treatment effect is best described by the pharmacodynamic parameter peak level/MIC, indicating that the peak concentration achieved in the tissues is a major factor in relation to efficacy.18,21 The drug levels of the lipid formulations of amphotericin B are higher than those of conventional amphotericin B, although the pharmacodynamic properties of the individual lipid formulations differ significantly.22 Also, for some isolates even sub-MIC concentrations induced PAFE.
The strains tested in this study had a maximum MIC of 8 mg/L for nystatin and 4 mg/L for amphotericin B, indicating that when testing the PAFE by using 4 x MIC, the maximum concentration is 32 or 16 mg/L respectively, values that are achievable in tissues.
For both drugs, PAFE was observed, however amphotericin B displayed longer values compared with nystatin.
PAFE displayed by amphotericin B and nystatin were concentration-dependent. This is consistent with previous studies with Aspergillus and Candida where longer PAFEs were found following exposure to amphotericin B or nystatin at higher concentrations.5,7,9
The mean PAFE values found in our study for all zygomycetes were similar to those described for Aspergillus species previously tested although amphotericin B induced longer PAFE against A. fumigatus (mean PAFE = 9.94 h).5 For nystatin, similar PAFEs were found for Candida albicans (mean = 6.85 h) whereas Candida non-albicans species presented longer PAFE.23
In conclusion, amphotericin B and nystatin induced PAFE in zygomycetes but lower PAFE values were observed with nystatin. In general, the media used did not significantly influence the effect. Determination of PAFE could be useful as an in vitro tool together with in vitro susceptibility testing to give a better understanding of the activity of antifungal agents. There are no data available for in vivo studies of PAFE for zygomycetes that could support any theory about the importance of this effect as a predictor of therapy failure. For this reason, further studies are warranted, including in vivo experiments, to study the impact of PAFE in zygomycetes on dosing regimens of amphotericin B or nystatin and the usefulness of this assay to assist in predicting clinical outcome.
![]() |
Acknowledgements |
---|
![]() |
Footnotes |
---|
![]() |
References |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
2
.
Ribes, J. A., Vanover-Sams, C. L. & Baker, D. J. (2000). Zygomycetes in human disease. Clinical Microbiology Reviews 13, 236301.
3 . Sugar, A. M. (1992). Mucormycosis. Clinical Infectious Diseases 14, Suppl. 1, S1269.[ISI][Medline]
4
.
Dannaoui, E., Afeltra, J., Meis, J. F. et al. (2002). In vitro susceptibilities of zygomycetes to combinations of antimicrobial agents. Antimicrobial Agents and Chemotherapy 46, 270811.
5
.
Vitale, R. G., Mouton, J. W., Afeltra, J. et al. (2002). Method for measuring postantifungal effect in Aspergillus species. Antimicrobial Agents and Chemotherapy 46, 19605.
6
.
Meletiadis, J., Meis, J. F., Mouton, J. W. et al. (2001). Analysis of growth characteristics of filamentous fungi in different nutrient media. Journal of Clinical Microbiology 39, 47884.
7
.
Gunderson, S. M., Hoffman, H., Ernst, E. J. et al. (2000). In vitro pharmacodynamic characteristics of nystatin including time-kill and postantifungal effect. Antimicrobial Agents and Chemotherapy 44, 288790.
8 . Odenholt, I. (2001). Pharmacodynamic effects of subinhibitory antibiotic concentrations. International Journal of Antimicrobial Agents 17, 18.[CrossRef][ISI][Medline]
9
.
Ernst, E. J., Klepser, M. E. & Pfaller, M. A. (2000). Postantifungal effects of echinocandin, azole, and polyene antifungal agents against Candida albicans and Cryptococcus neoformans. Antimicrobial Agents and Chemotherapy 44, 110811.
10 . Espinel-Ingroff, A., Barchiesi, F., Hazen, K. C. et al. (1998). Standardization of antifungal susceptibility testing and clinical relevance. Medical Mycology 36, 6878.[ISI][Medline]
11 . Cormican, M. G. & Pfaller, M. A. (1996). Standardization of antifungal susceptibility testing. Journal of Medical Microbiology 38, 56178.
12 . Pfaller, M. A., Rinaldi, M. G., Galgiani, J. N. et al. (1990). Collaborative investigation of variables in susceptibility testing of yeasts. Antimicrobial Agents and Chemotherapy 34, 164854.[ISI][Medline]
13 . National Committee for Clinical Laboratory Standards. (1998). Reference Method for Broth Dilution Antifungal Susceptibility Testing of Conidium-forming Filamentous Fungi: Approved Standard M-38A. NCCLS, Wayne, PA, USA.
14 . Rex, J. H., Cooper, C. R., Jr, Merz, W. G. et al. (1995). Detection of amphotericin B-resistant Candida isolates in a broth-based system. Antimicrobial Agents and Chemotherapy 39, 9069.[Abstract]
15 . Hamilton-Miller, J. M. (1973). Chemistry and biology of the polyene macrolide antibiotics. Bacteriological Reviews 37, 16696.
16 . Mehta, R. T., Hopfer, R. L., Gunner, L. A. et al. (1987). Formulation, toxicity, and antifungal activity in vitro of liposome-encapsulated nystatin as therapeutic agent for systemic candidiasis. Antimicrobial Agents and Chemotherapy 31, 1897900.[ISI][Medline]
17
.
Groll, A. H., Mickiene, D., Werner, K. et al. (2000). Compartmental pharmacokinetics and tissue distribution of multilamellar liposomal nystatin in rabbits. Antimicrobial Agents and Chemotherapy 44, 9507.
18
.
Andes, D. (2003). In vivo pharmacodynamics of antifungal drugs in treatment of candidiasis. Antimicrobial Agents and Chemotherapy 47, 117986.
19 . Khoo, S. H., Bond, J. & Denning, D. W. (1994). Administering amphotericin Ba practical approach. Journal of Antimicrobial Chemotherapy 33, 20313.[Abstract]
20 . Collette, N., van der Auwera, P., Lopez, A. P. et al. (1989). Tissue concentrations and bioactivity of amphotericin B in cancer patients treated with amphotericin B-deoxycholate. Antimicrobial Agents and Chemotherapy 33, 3628.[ISI][Medline]
21
.
Andes, D., Stamsted, T. & Conklin, R. (2001). Pharmacodynamics of amphotericin B in a neutropenic-mouse disseminated-candidiasis model. Antimicrobial Agents and Chemotherapy 45, 9226.
22
.
Dupont, B. (2002). Overview of the lipid formulations of amphotericin B. Journal of Antimicrobial Chemotherapy 49, Suppl. 1, 316.
23 . Ellepola, A. N. & Samaranayake, L. P. (1999). The in vitro post-antifungal effect of nystatin on Candida species of oral origin. Journal of Oral Pathology and Medicine 28, 1126.[Medline]