INTRODUCTION
A universal tendency to bacterial resistance to antimicrobials has been observed since the beginning of antibiotic therapy. Pseudomonas aeruginosa is a microorganism that is particularly difficult to control because it causes opportunistic and nosocomial infections, it is non-susceptible to several antimicrobials and it develops progressive resistance to new drugs1. Over the last few years, carbapenemic drugs have become important therapeutic resources for the control of P. aeruginosa infections. However, growing resistance to imipenem and other carbapenems has been observed, and multidrug-resistance has become more common2,3.
A therapeutic strategy against P. aeruginosa is the use of antimicrobial combinations to delay the selection of resistant bacterial clones and to obtain a synergistic antibacterial action4. The combination of beta-lactam antibiotics and aminoglycosides has been recommended for the treatment of infected patients. Antimicrobials are also combined as a method to recover the efficacy of drugs to which P. aeruginosa has become resistant. When the interaction is synergistic, reductions of the minimum inhibitory concentrations (MICs) of both antimicrobials occur, eventually rendering the microorganism susceptible to the levels of antimicrobials found in the blood and tissues5.
This investigation was motivated by the high frequency of nosocomial infections caused by multidrug-resistant P. aeruginosa in a Brazilian emergency and trauma care hospital. The objective was to evaluate the in vitro susceptibility of P. aeruginosa by testing antimicrobials that are known to combat P. aeruginosa, combined with other potentially active drugs, particularly fosfomycin and rifampin.
METHODS
Pseudomonas aeruginosa was isolated from the blood (n=3) and urine (n=1) of patients who were admitted to the Emergency Unit of the University Hospital, Faculty of Medicine of Ribeirão Preto, University of São Paulo, Ribeirão Preto, SP, Brazil. The isolates were selected at random among other clinical isolates and were identified by the automated microbiology system Vitek (Biomérieux, Jacarepaguá, Brazil). Two isolates (8S and 34S) were susceptible to imipenem and to several other antimicrobials, while the other two isolates (46R and 72R) were imipenem and multidrug resistant. The four strains were subcultured in brain heart infusion broth (Oxoid, Hampshire, England), plated on Müeller Hinton agar (Oxoid, Hampshire, England) and then stored at -70°C in soy trypticase broth with 15% glycerol. Aliquots for the tests were removed from this stock, and bacterial growth was recovered by subculture in brain heart infusion broth for 24 hours.
Antimicrobial drugs
Imipenem, gentamicin, fosfomycin and polymyxin B powder were obtained from Sigma, USA(St. Louis, MO, USA) and were diluted in sterile water for the preparation of the stock solutions. Stock solutions of other drugs were prepared by dilution in sterilized water from the following commercially available medications: ceftazidime (Kefadin, ABL, São Paulo, Brazil), piperacillin-tazobactam (Taz-Pen, Cellofarm, Brazil), cefepime (ABL, São Paulo, Brazil), tobramycin (Tobramina, ABL, São Paulo, Brazil), ciprofloxacin (Ciprobacter/Isofarma, Ceará, Brazil) and rifampin (Rifaldin/Sanofi-Aventis, Paris, France). The stock solutions were stored at -70°C, except for imipenem, which was prepared immediately before use. The various drug concentrations were obtained by successive two-fold dilutions in sterile water. The antimicrobial solutions were validated by determination of the respective MICs against P. aeruginosa ATCC 27853.
Broth microdilution susceptibility test
The method standardized by the Clinical and Laboratory Standards Institute (CLSI)6 was used to determine the MICs of the antimicrobials for the selected clinical isolates and for P. aeruginosa ATCC 27853.
Briefly, Müeller Hinton broth that was adjusted for cations (Oxoid, Hampshire, England) was added to the wells of microtiter plates (TPP, Zellkultur, Trasadingen, Switzerland). Solutions with serial dilutions of antimicrobial concentrations were added at variable ranges according to the drug and isolate tested. Finally, P. aeruginosa from a 24-hour subculture in Müeller Hinton broth (Oxoid) was adjusted for a turbidity equivalent to 0.5 on the McFarland scale and then diluted to obtain a final inoculum of 2 x 105colony-forming units (CFU)/mL. The plates were covered with plastic film, and after 24 hours of incubation at 35°C, the absorbance of each well of the microtiter plate was measured with a microplate reader that was adjusted for a wavelength of 490nm.
The criterion used for MIC determination was the lowest antimicrobial concentration with absorbance corresponding to ≤ 20% of the mean absorbance of the control bacterial growth wells (without the addition of the antimicrobial). CLSI-determined breakpoints7 were used to evaluate the bacterial susceptibility to antimicrobials, with the exception of fosfomycin. Susceptibility to this drug was analyzed according to the European Committee on Antimicrobial Susceptibility Testing (EUCAST) criterion for Enterobacteriaceae8.
Susceptibility test to combined drugs
The checkerboard method9 was used to assess the eventual synergy between antimicrobials against the two imipenem-susceptible and the two multidrug-resistant P. aeruginosa isolates. Each drug combination was evaluated in duplicate with each bacterial isolate. The MIC of each separate drug was determined on different sides of the same plate. Wells were used for positive controls (only bacterial inoculum and Müeller Hinton broth) and for negative controls (only combined and separate antimicrobials and Müeller Hinton broth). The combined drugs were tested at different concentrations inside the microplate. A Pseudomonas aeruginosa subculture in Müller Hinton broth was adjusted to obtain a final inoculum of 2 x 105 CFU/mL in the well. The plates were covered and incubated at 35°C for 24 hours, and the absorbance of each well was then measured with a microplate reader adjusted for a wavelength of 490 nm. The MIC of the separate or combined antimicrobials was defined as the lowest concentration of the drugs with an absorbance that was ≤ 20% of the mean absorbance of the bacterial growth in the control wells.
Analysis of antimicrobial interaction
Interaction was analyzed separately for each antimicrobial combination (drugs A and B) and bacterial isolate. The fractional inhibitory concentration of drug A (FIC[A]) was calculated as the following ratio: MIC obtained with drug A combined with the second drug/MIC of drug A alone. FIC[B] was obtained using a similar calculation. The FIC(A) + FIC(B) sum resulted in the FIC index (FICI), representative of the interaction of the two antimicrobials. The following criteria were adopted when the MIC value exceeded the standardized range of drug concentrations: 1) for an MIC above the range limit, the FIC was calculated with the next highest drug concentration, estimated by successive two-fold dilutions; and 2) when the MIC was equal to or below the lowest drug concentration evaluated, this value was used to calculate the FIC. The following criteria of interpretation were adopted: 1) FICI ≤ 0.5 indicates synergy between the two antimicrobials; 2) FICI > 0.5 and ≤ 4.0 indicates indifference; and 3) FICI >4 indicates antagonism9. The lowest FICI value obtained in the checkerboard test was considered to be representative of the interaction of the two antimicrobials against the respective P. aeruginosa isolate, regardless of the concentrations of the two drugs.
RESULTS
The two imipenem-susceptible strains (8S and 34S) exhibited susceptibility to other anti-Pseudomonasdrugs but were resistant to fosfomycin and rifampin. The two imipenem-resistant isolates (46R and 72R) were also resistant to all antimicrobials evaluated (the MIC of the 46R strain was near the breakpoint with respect to ceftazidime and piperacillin-tazobactam). The four P. aeruginosa isolates were all susceptible to polymyxin B (MIC= 1 to 2µg/mL).
The FICI for the various drug combinations indicated synergic or indifferent activity, with no antagonism being observed. The MIC value of an antimicrobial generally decreased when a second drug was present in subinhibitory concentrations, but in general, the MIC reductions were discrete. For the synergic antimicrobial combinations, the initial and the lowest MIC values obtained in the presence of another drug acting jointly are listed in Table 1 (imipenem-susceptible isolates) and Table 2 (imipenem-resistant isolates). Some drug combinations led to a great MIC reduction, such that the new MIC of both drugs was reduced below the respective breakpoint. Table 3 shows that there was synergy in 46% of the combinations of all drugs for the four isolates tested. Tobramycin (65%) and fosfomycin (57%) were more effective as the second drug of the combinations than gentamicin (25%) and rifampin (36%) in terms of synergistic action against P. aeruginosa. Synergy with these drugs was obtained more frequently when imipenem, piperacillin-tazobactam and ceftazidime were used as the first anti-Pseudomonas drugs (p < 0.05). The rate of synergy obtained with all antimicrobial combinations for isolates 8S, 34S, 46R and 72R reached 20.8% (5/24), 50% (12/24), 62.5% (15/24) and 50% (12/24), respectively (p < 0.05).
Strain | MIC (µg/mL) | |||
---|---|---|---|---|
drugs (A/B) | alone (A/B) | combined (A/B) | FICI | |
8S | IPM/TOB | 2/0.5 | 0.5/0.13 | 0.500 |
8S | IPM/FOSF | 1/512 | ≤0.13/16 | 0.161 |
8S | IPM/RIF | 2/32 | 0.5/≤4 | 0.375 |
8S | PIP-T/TOB | 4/0.5 | 0.5/≤0.13 | 0.375 |
8S | PIP-T/FOSF | 4/512 | 1/16 | 0.281 |
34S | IPM/TOB | 2/1 | 0.5/0.25 | 0.500 |
34S | IPM/FOSF | 1/512 | 0.25/64 | 0.375 |
34S | IPM/RIF | 2/32 | 0.5/8 | 0.500 |
34S | PIP-T/GEN | 16/2 | 2/≤0.5 | 0.375 |
34S | PIP-T/TOB | 16/1 | ≤0.13/≤0.06 | 0.068 |
34S | PIP-T/FOSF | 8/512 | ≤0.13/64 | 0.141 |
34S | CEFTA/GEN | 4/2 | 0.25/0.5 | 0.313 |
34S | CEFTA/TOB | 4/2 | 1/≤0.5 | 0.500 |
34S | CEFTA/FOSF | 8/>512 | 1/32 | 0.156 |
34S | CEFTA/RIF | 8/64 | 1/≤8 | 0.250 |
34S | CIP/FOSF | 0.25/>512 | 0.06/16 | 0.256 |
34S | TOB/RIF | 2/64 | 0.5/16 | 0.500 |
IPM: imipenem; PIP-T: piperacillin-tazobactam; CEFTA: ceftazidime; TOB: tobramycin; GEN: gentamicin; CIP: ciprofloxacin; FOSF: fosfomycin; RIF: rifampin.
Strain | MIC (µg/mL) | |||
---|---|---|---|---|
dugs (A/B) | alone (A/B) | combined (A/B) | FICI | |
46R | IPM/TOB | 32/>256 | 2/64 | 0.188 |
46R | IMP/FOSF | 32/256 | 4/32 | 0.250 |
46R | PIP-T/GEN | 64/>512 | 16/256 | 0.500 |
46R | PIP-T/TOB | 128/256 | 4/≤8 | 0.063 |
46R | PIP-T/FOSF | 128/256 | 16/≤8 | 0.156 |
46R | PIP-T/RIF | 64/16 | 16/≤4 | 0.500 |
46R | CEFTA/TOB | 8/256 | 2/32 | 0.375 |
46R | CEFTA/FOSF | 16/512 | 4/64 | 0.375 |
46R | CEFTA/RIF | 16/32 | 4/≤8 | 0.500 |
46R | CPM/GEN | >512/512 | 32/≤8 | 0.047 |
46R | CPM/TOB | >512/256 | ≤1/≤8 | 0.033 |
46R | CPM/FOSF | 256/512 | ≤1/16 | 0.035 |
46R | CPM/RIF | >512/32 | 32/≤4 | 0.156 |
46R | TOB/FOSF | 512/>256 | 128/32 | 0.313 |
46R | TOB/RIF | 512/32 | 16/≤4 | 0.156 |
72R | IPM/GEN | 512/128 | 2/8 | 0.066 |
72R | IPM/FOSF | >512/128 | 256/32 | 0.500 |
72R | IPM/RIF | 512/32 | 128/≤4 | 0.375 |
72R | PIP-T/TOB | >512/256 | 64/32 | 0.188 |
72R | PIP-T/FOSF | >512/256 | 4/64 | 0.254 |
72R | CEFTA/TOB | >512/>256 | 128/32 | 0.188 |
72R | CEFTA/FOSF | >256/512 | 128/128 | 0.500 |
72R | CPM/TOB | 512/256 | 64/32 | 0.250 |
72R | CIP/TOB | 16/256 | 4/16 | 0.313 |
72R | CIP/FOSF | 16/256 | 2/16 | 0.188 |
72R | TOB/FOSF | >512/256 | 16/32 | 0.141 |
72R | TOB/RIF | 512/32 | 8/≤4 | 0.141 |
IPM: imipenem; PIP-T: piperacillin-tazobactam; CEFTA: ceftazidime; TOB: tobramycin; GEN: gentamicin; CIP: ciprofloxacin; FOSF: fosfomycin; RIF: rifampin.
Drug B | Number of strains with synergy Drug A | Synergistic/all tests n (%) | |||||||
---|---|---|---|---|---|---|---|---|---|
IPM | PIP-T | CEFTA | CPM | CIP | GEN | TOB | |||
GEN | 1 | 2 | 1 | 1 | 0 | 5/20 | 25.0 | ||
TOB | 3 | 4 | 3 | 2 | 1 | 13/20 | 65.0 | ||
FOSF | 4 | 4 | 3 | 1 | 2 | 0 | 2 | 16/28 | 57.0 |
RIF | 3 | 1 | 2 | 1 | 0 | 0 | 3 | 10/28 | 36.0 |
Synergistic/all tests n (%) | 11/16 (69.0) | 11/16 (69.0) | 9/16 (56.0) | 5/16 (31.0) | 3/16 (19.0) | 0/8 (0.0) | 5/8 (63.0) | 44/96 | 46.0 |
IPM: imipenem; PIP-T: piperacillin/tazobactam; CEFTA: ceftazidime; CPM: cefepime; GEN: gentamicin; TOB: tobramycin; FOSF: fosfomycin; RIF: rifampin; CIP: ciprofloxacin. p<0.05
DISCUSSION
This study revealed that various antimicrobial combinations could act synergistically in vitro against multidrug-resistant Brazilian P. aeruginosa isolates. Polymyxins and fosfomycin are old antibiotics that have been retrieved in an attempt to control nosocomial infections caused by this microorganism10−11−12, but isolates with high MICs for these drugs have already been detected1−13−14. The increasing number of infections related to multidrug-resistant P. aeruginosa in different areas of the world4−15−16 has stimulated the investigation of the synergy of antimicrobial combinations. The checkerboard method is widely employed for this purpose and was modified in this study to measure the growth in microplates as absorbance units. The results obtained with this instrumental technique show a good correlation with the visual reading and provide a better, more objective definition of the intermediate zone of growth and therefore, more precise MIC determinations for combined drugs.
The overall rate of synergy observed in this study was 46%. The combinations of imipenem, piperacillin-tazobactam and ceftazidime with a second drug often resulted in synergy. Combinations of these antibiotics with tobramycin exhibited synergy in 83% of the tests performed with the four P. aeruginosaisolates. In another study assessing multidrug-resistant P. aeruginosa, ceftazidime plus tobramycin and piperacillin-tazobactam plus tobramycin combinations were evaluated, and synergy ratios of 67% and 50%, respectively, were observed17. With respect to fosfomycin, synergistic interactions with other antibacterial drugs were verified in 57% of the tests, a rate similar to that reported previously for multidrug-resistant P. aeruginosa18. Fosfomycin enhances the active transport of tobramycin in P.aeruginosa19; in vitro synergic actions were also demonstrated for polymyxin E10, imipenem20, ceftazidime20 and ciprofloxacin21. Previous studies showed that rifampin had in vitro synergism with other antimicrobials22−25, whereas in this investigation, synergism was more frequently demonstrated with imipenem and aminoglycosides.
The clinical application of the in vitro synergy results must be considered with caution in view of the variable susceptibilities of P. aeruginosa isolates to combined drugs and the pharmacokinetic characteristics of the antimicrobials. As observed in other studies26, 27, the rate of synergy of antibacterial combinations varies according to isolate and is not strictly associated with susceptibility or resistance to imipenem. Comparison of the two multidrug-resistant P. aeruginosa isolates revealed more frequent and significant drug MIC reductions for the 46R isolate than for the 72R isolate. Thus, it is advisable to test each multidrug-resistant isolate with the different drugs in combination17,28.
Among the synergy results, only a few antibacterial combinations have led to sufficient MIC reductions that reach the breakpoint and the usual plasma level of the drugs, which is essential if a synergistic action in a clinical setting is going to take place5,28. For the 72R isolate, the only antibacterial combinations that would likely be synergic in vivo are imipenem plus gentamicin, piperacillin-tazobactam plus fosfomycin, ciprofloxacin plus fosfomycin, tobramycin plus fosfomycin and tobramycin plus rifampin.
In conclusion, antimicrobial synergy was observed against clinical isolates of imipenem-susceptible or imipenem-resistant P. aeruginosa. Some drug combinations resulted in sufficient MIC reductions, which suggests that these combinations may be of clinical use for infections of multidrug-resistant P. aeruginosaas an alternative to antibiotic therapy with polymyxins.