Outbreak of Carbapenem-Resistant Pseudomonas aeruginosa Producing VIM-8, a Novel Metallo-{beta}-Lactamase, in a Tertiary Care Center in Cali, Colombia

The prevalence of imipenem resistance among Pseudomonas aeruginosaisolates at a 195-bed tertiary care medical center in Cali,Colombia, rose from 2% in 1996 to 28% in 1997 and to over 40%in 2003. Many isolates showed high-level multiresistance, andphenotypic characterization suggested the spread of a predominantstrain with minor variants. Sixty-six resistant isolates collectedbetween February 1999 and July 2003 from hospitalized patients(n = 54) and environmental samples (n = 12) were subjected toa fuller analysis. Genetic fingerprints were compared by pulsed-fieldgel electrophoresis (PFGE) of SpeI-digested genomic DNA, andbla_IMP and bla_VIM genes were sought by PCR. PFGE and serotypingindicated that 52 of the 66 isolates belonged to a single strain,with 82% similarity; the PFGE pattern for this organism wasdesignated pattern A. Two further pairs of isolates representedsingle strains; the remaining nine isolates were unique, andin the case of one isolate, no satisfactory PFGE profile couldbe obtained. The pattern A isolates were mostly of serotypeO12 and were highly resistant to imipenem (MICs, 32 to >256µg/ml), with this resistance decreased eightfold or morein the presence of EDTA. They yielded amplicons with bla_VIM-specificprimers, and sequencing of DNA from a representative isolaterevealed bla_VIM-8, a novel allele with three polymorphisms comparedwith the sequence of bla_VIM-2. Two of these nucleotide changeswere silent, but the third determined a Thr139Ala substitution.Only 4 of 13 resistant isolates (2 clinical isolates and 2 environmentalisolates) assigned to other PFGE types carried bla_VIM alleles,whereas the others were less multiresistant and mostly had lowerlevels of imipenem resistance (MICs, $≤$ 32 µg/ml) which wasnot significantly reduced by EDTA. No bla_IMP alleles were detected.During 2003, when the environmental study was undertaken, serotypeO12 isolates with bla_VIM were recovered from sinks and stethoscopesin the most-affected units, although not from the hands of staff;the problem declined once these reservoirs were disinfectedand hygienic precautions were reinforced.

INTRODUCTION

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Introduction

Pseudomonas aeruginosa is a frequent nosocomial pathogen thatcauses severe disease in many settings, particularly in compromisedpatients, including those with cancer, burns, and cystic fibrosis.Infections are frequently severe, and two recent studies indicatedthat the rate of mortality attributable to P. aeruginosa bacteremiais approximately 34% (10, 28). Many virulence factors may contributeto pathogenicity, including biofilm formation and the expressionof adhesins, endotoxin, and hydrolytic exotoxins, which causetissue destruction. Therapy is complicated by the organism'spotent ability for adaptation, mutation, and gene acquisition.Resistance to antipseudomonal ß-lactams may arisevia hyperproduction of a chromosomal AmpC ß-lactamase,acquisition of secondary ß-lactamases, and/or upregulatedefflux or impermeability (6, 12, 15, 17). Most carbapenem resistanceis due to impermeability, which arises via the loss of the OprD(D2) porin, but carbapenem-hydrolyzing metallo-ß-lactamases(MBLs) of the IMP, VIM, and SPM families are increasingly reported,with some of them coming from strains that have caused largeoutbreaks (8, 18, 19, 23, 31).

At present, 17 IMP ß-lactamase variants, 10 VIM types,and 1 SPM have been catalogued, with most of the recorded MBLproducers being P. aeruginosa or Acinetobacter spp. from EastAsia or Europe (5, 30, 32, 33, 35). MBL producers are also emergingin the Americas, where SENTRY program data for Latin Americanin 2002 indicated 18% carbapenem resistance among Pseudomonasand Acinetobacter spp. and where it was estimated that 2% ofall P. aeruginosa isolates from participating hospitals wereMBL producers (M. Castanheria, R. E. Mendes, T. Murphy, M. Toleman,H. S. Sader, R. N. Jones, and T. R. Walsh, Abstr. 43rd Intersci.Conf. Antimicrob. Agents Chemother., abstr. 2023, 2003). Sofar, five MBL types have been detected in the Americas: IMP-1,IMP-7, IMP-16, VIM-2, and SPM-1. The last four of these haveexclusively been reported in P. aeruginosa. The only major outbreakof producers so far recorded in South America was in Brazil,where a P. aeruginosa strain with the SPM-1 enzyme spread amonghospitals (7). We describe here an outbreak caused by a VIM-8-producingP. aeruginosa strain that lasted for 6 years in a 195-bed tertiarycare medical center in Cali, Colombia.

MATERIALS AND METHODS

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Materials and Methods

Epidemiological and clinical data. The study was conducted at a 195-bed tertiary care center inCali, southwest Colombia. This establishment is the medicalreference center for the region, with 95 beds in adult, pediatric,and neonatal intensive care units (ICUs). Its transplantationunit undertakes kidney, liver, and heart transplants.

A total of 727 imipenem-resistant isolates of P. aeruginosawere identified from 422 patients between February 1997 andJuly 2003, based on routine identification and susceptibilitytests performed with the MicroScan AutoScan system (Dade MicroScanInc., Sacramento, Calif.) and the Kirby-Bauer disk diffusionmethod. Most of these isolates were multiresistant to extended-spectrumcephalosporins, including cefepime, aminoglycosides, and fluoroquinolones,but many were susceptible or only intermediately resistant toaztreonam and piperacillin. Sixty-six of these imipenem-resistantisolates were selected for detailed study. These comprised 36clinical isolates collected between 1997 and 2003, which wereanalyzed retrospectively, and a further 18 clinical isolatesand 12 environmental isolates collected prospectively in 2003.

Information on the patients and isolates was collected fromclinical records and from the local Infectious Disease Committee'sdatabase. The data collected included the patient's age, sex,duration of ICU stay until isolation of imipenem-resistant P.aeruginosa, the source of the isolate, underlying disease, previousantibiotic treatment, type of infection, and clinical outcome.Patients were classified as infected or colonized accordingto the presence or absence of clinical symptoms.

Bacterial identification and antimicrobial susceptibility. Bacterial identification was performed with a MicroScan AutoScansystem (Dade MicroScan), according to the instructions of themanufacturer. The imipenem-EDTA disk method (36) was used toscreen isolates for MBLs, taking an increase in zone diameterof more than 5 mm in the presence of EDTA as a predictor oflikely MBL production. MBL Etests (AB Biodisk, Solna, Sweden)were used as a further test of MBL production, with MIC ratios(MIC of imipenem alone/MIC of imipenem plus EDTA) $≥$ 8 taken asprima facie evidence of MBL production.

MICs initially were determined by broth microdilution assayon the MicroScan system and were interpreted according to thecriteria of the NCCLS (22). The antimicrobials tested were amikacin,aztreonam, ceftazidime, cefepime, ciprofloxacin, gentamicin,imipenem, meropenem, and piperacillin. Since the MicroScan systemrecorded carbapenem MICs only up to 4 µg/ml, isolateswith greater resistance were reexamined by agar dilution onMueller-Hinton medium (Oxoid, Basingstoke, United Kingdom) witha final inoculum of 10⁴ CFU/spot. Imipenem was obtained fromMerck Sharp & Dohme (Hoddesdon, United Kingdom). Carbapenemresistance was further confirmed by the Kirby-Bauer agar diskdiffusion method with imipenem (10 µg; Oxoid) and meropenem(10 µg; Becton Dickinson, Sparks, Md.) disks. P. aeruginosaATCC 27853 was used as a control throughout.

Carbapenemase identification. PCR amplification was performed with universal bla_VIM and bla_IMPprimers (23). The isolates were also tested by PCR with primersspecific for bla_VIM-l-like or bla_VIM-2-like subtypes (35). Aselected bla_VIM allele, amplified with subtype-specific primers,was sequenced on a CEQ8000 analyzer (Beckman Coulter, High Wycombe,United Kingdom) (18, 35).

Strain typing. Isolates were compared by pulsed-field gel electrophoresis (PFGE)of SpeI-digested genomic DNA (3); banding patterns were analyzedwith BioNumerics software (Applied Maths, Sint-Martens-Latem,Belgium). The O serotypes of the isolates were determined bythe slide agglutination method by comparison with InternationalAntigenic Typing Scheme type strains (25).

Environmental screening. From May to June 2003, environmental surveillance swab specimens(n = 70) were collected from nebulizers, ventilators, tubingdevices, stethoscopes, and sink surfaces in each patient's room.Fingerprints from the hands of health care workers (n = 10)in the affected units, and particularly those in the ICUs, weresampled twice per day, at the beginning and the end of workshifts, before the final hand washing. Swab samples were takenfrom sinks in the morning to maximize bacterial recovery. Allthe swabs were inoculated into nutrient broth supplemented with0.03% cetrimide (cetyltrimethyl ammonium bromide) and incubatedat 37°C for 24 h. Subcultures were then performed on nutrientagar with 0.02% cetrimide, and the plates were incubated for48 h at 37°C (based on the advice of Tyrone Pitt [HealthProtection Agency], personal communication). Colonies producinga blue-green pigment were checked for oxidase reaction, andoxidase-positive isolates were subjected to identification andsusceptibility testing with the MicroScan system, PFGE and serotypingwere performed as described above, and bla_VIM was sought byPCR.

Nucleotide sequence accession number. The bla_VIM allele hasbeen deposited in the GenBank database under accession numberAY524987.

RESULTS

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Results

Description of outbreak. The overall prevalence of imipenem resistance among P. aeruginosaisolates in the hospital from 1997 to 2003 was 38%. Prevalencerates in individual years were as follows: 1997, 28%; 1998,34%; 1999, 38%; 2000, 37%; 2001, 42%; 2002, 49%; and 2003, 37%.The prevalence rate was only 2% in 1996. The most striking risewas from 5% in February 1997 to 32% in March 1997; and duringthe next several years, resistant isolates were detected inmultiple ICUs, although they were particularly detected in theadult unit. Their incidence peaked in February 2002, with 46isolates from 26 patients (Fig. 1). This peak and a subsequentdecline matched the peak and decline in imipenem usage (Fig.1), but, more generally, the relationships between imipenemuse and isolation of resistant P. aeruginosa were weak.

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FIG. 1. Isolation of imipenem-resistant P. aeruginosa isolates from 1997 to 2003: ${blacksquare}$ , total number of imipenem-resistant P. aeruginosa isolates per month; ${diamondsuit}$ , total number of infected patients per month; ${circ}$ , imipenem use defined as daily dose per 100 patient-days.

In total, 727 imipenem-resistant P. aeruginosa isolates werecultured from various specimens and sites (Table 1), includingrespiratory tract specimens (n = 165; 22.7%), abdominal swabs(n = 122; 16.8%), catheters (n = 110; 15.1%), abscesses (n =100; 15%), blood (n = 105; 14.4%), urine (n = 46; 6.3%), surgicalwounds (n = 32; 4.4%), and other specimens (n = 47; 5.3%). Theadult ICU accounted for 40.3% of the isolates, the neonatalICU accounted for 10.4%, and the pediatric ICU accounted for4.7%; other adult medical wards accounted for 24.5%, the pediatricmedical ward accounted for 6.6%, the emergency unit accountedfor 4.4%, and other units accounted for 9.1%.

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TABLE 1. Characteristics of 54 P. aeruginosa clinical isolates from Cali, Colombia, 1999 to 2003^a

A total of 128 different antibiotic resistance phenotypes wereseen among the imipenem-resistant isolates, although many ofthese were minor variants. Six phenotypes were predominant,as follows: phenotype 1, resistant to imipenem, meropenem, ceftazidime,aminoglycosides, and quinolones but susceptible to aztreonamand piperacillin (32.5%); phenotype 2, similar to phenotype1 but resistant also to aztreonam and piperacillin (7.9%); phenotype3, resistant only to imipenem (3.9%); phenotype 4, similar tophenotype 1 but susceptible only to piperacillin (10.5%); phenotype5, resistant to imipenem and meropenem but susceptible to theother antimicrobials tested (2.7%); and phenotype 6, similarto phenotype 1 but susceptible also to cefepime (2.7%). Theremaining 122 phenotypes accounted for 39.8% of the imipenem-resistantisolates.

Typing of clinical isolates. Fifty-four imipenem-resistant clinical isolates were retainedfor analysis. These isolates were collected in the followingyears: 1999, 13 isolates; 2000, 2 isolates; 2002, 25 isolates;2003, 13 isolates; and unknown, 1 isolate. They included representativesof phenotypes 1 (predominantly), 2, 4, and 6, as well as minortypes. Of these 54 isolates, 42 clustered as the same type,designated type A, with >82% similarity by PFGE (Fig. 2).All 42 of these isolates were of serotype O12, and the combinationof imipenem and EDTA exhibited synergy against these isolates,with imipenem MICs reduced eightfold or more by the presenceof EDTA. All these isolates were positive for bla_VIM by PCRbut were negative for bla_IMP. More than 90% of the isolateswere multiresistant to ß-lactam antimicrobials exceptaztreonam and piperacillin, to which 63.6 and 98% of the isolates,respectively, appeared to be susceptible on the basis of thecriteria of the NCCLS (22). For many of the isolates (ca. 40%)piperacillin MICs were $≤$ 16 µg/ml, and thus, they wouldbe considered susceptible on the basis of, for example, thecriteria of the British Society for Antimicrobial Chemotherapy(1, 2), which are stricter than those of the NCCLS (susceptibleMIC $≤$ 64 µg/ml).

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FIG. 2. Dendrogram of PFGE data (SpeI digests) showing the relatedness of P. aeruginosa isolates. Fifty-two isolates belonged to the type A strain and carried bla_VIM. Four other isolates also produced a VIM carbapenemase; +, bla_VIM present; –, bla_VIM absent.

The remaining 12 clinical isolates yielded nine different profilesby PFGE, belonged to various serotypes, and included 1 isolatefor which no satisfactory profile could be obtained. Two werepositive for bla_VIM, but the remainder were negative. The latterisolates were much less multiresistant than type A isolatesto non-ß-lactam antibiotics, including gentamicinand ciprofloxacin (7% resistant versus 70% resistant in strainA to both these antimicrobials).

Identification of VIM-type enzymes. Sequencing of the bla_VIM allele from a representative PFGE typeA isolate revealed a bla_{VIM- 2} gene variant, designated bla_VIM-8(the number was allocated by G. Jacoby, personal communication).The novel gene differed from bla_VIM-2 by an A-to-G polymorphismat nucleotide 4.5, giving a threonine-to-alanine substitutionat amino acid 139. The bla_VIM-8 allele also had two silent polymorphisms,A492 to G492 and G693 to A693.

Morbidity and mortality of patients harboring type A strain isolates. Case notes were reviewed for 40 patients from whom type A strainisolates were obtained. These comprised adults in the adultICU (n = 20), infants in the neonatal ICU (n = 6), childrenin the pediatric ICU (2), children in the pediatric medicalward (n = 2), and patients in other adult wards (n = 10). Thelargest groups were those aged >60 years (n = 11) or <1year (n = 8). Thirty-one patients were considered to be infected,whereas nine were considered colonized. The most common isolationsites were blood (n = 12), respiratory secretions (n = 8), centralvenous catheters (n = 7), urinary tract infections (n = 6),peritoneal fluid samples (n = 5), and surgical wounds (n = 4).Multiple isolates were obtained from three patients with septicemia:simultaneously from the blood and feces from one patient andthe blood and respiratory tract from the other two patients.The average hospital stay to the time of isolation was 57 days,and 35 of the isolates were recovered from patients who hadbeen hospitalized for 40 days or longer. Of these 40 patients,33 (82.5%) were undergoing mechanical ventilation, 35 (87.5%)had previously received antibiotics, 9 (22.5%) had receivedimipenem therapy for 2 to 15 days in the previous 8 to 21 days,and 13 (32.5%) had previously received meropenem therapy; 1patient had received both of these carbapenems. The most frequentunderlying conditions or histories were trauma, cirrhosis, transplantation,chronic renal insufficiency, lupus, and peritonitis. Thirteen(37.5%) of the 31 infected patients died, with P. aeruginosainfection judged to have contributed to death in 10 cases. Threecolonized patients also died, and one of them was coinfectedwith a non-type A P. aeruginosa strain.

Patients infected with the type A strain were variously givenhigh doses of meropenem together with an aminoglycoside (generallygentamicin) or were given piperacillin-tazobactam (4.5 g every8 h [q8h]) plus an aminoglycoside. Later, piperacillin-tazobactam(4.5 g q8h) plus aztreonam (2 g q8h) was the therapy used. Theinfections were insidious, and isolates of the type A strainshowed minor variations in susceptibilities in vitro; moreover,the general health and nutrition of the patients improved withantimicrobial therapy, precluding a rigorous outcome analysisin relation to therapy.

Environmental screening. In May and June 2003, screening of the hospital environmentfor imipenem-resistant P. aeruginosa isolates was undertakenin the most-affected areas, comprising the adult, neonatal,and pediatric ICUs. Samples were also taken from operating rooms.In total, 70 culture swab specimens were taken: 33 from sinks,5 from stethoscopes, 22 from tubing devices, and 10 from thehands of health care workers. The stethoscope samples were takenfrom inside the metallic inner ring by using swabs prerinsedin cetrimide broth medium.

Twelve samples were positive for imipenem-resistant P. aeruginosa:nine isolates were recovered from the adult ICU, eight of whichwere from sinks and one of which was from a stethoscope, andthree isolates were recovered from sinks in the neonatal ICU.Imipenem and EDTA were synergistic against these 12 isolatesby the disk method, and the isolates were positive for bla_VIMby PCR; 10 clustered with the type A strain (Fig. 2), althoughone of these did not agglutinate with type O12 antiserum; onewas serotype O12 but did not have the PFGE pattern typical oftype A; and the last one was distinct both by its PFGE patternand by its serotype (Table 2). No carriers were found amonghealth care workers, and no imipenem-resistant P. aeruginosastrains were recovered from environmental samples from the operatingroom or the pediatric ICU.

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TABLE 2. Characteristics of imipenem-resistant P aeruginosa isolates from environmental sources^a

Infection control measures. Inspection revealed that the design of the sinks was not appropriate;in particular, their joints to the walls were not sealed, facilitatingcolonization with and the persistence of P. aeruginosa. Controlmeasures were taken to eradicate the strain. First, the ICUswere intensively cleaned with hypochlorite, with overnight treatmentof the sinks and their drains; moreover, use of these sinkswas restricted pending replacement. Stethoscopes were disassembledand cleaned with 70% ethanol, this being the standard procedure.

All ICU staff were strongly reminded to follow isolation proceduresand to wash their hands with alcohol glycerol. Follow-up studiesin September 2003 reisolated imipenem-resistant P. aeruginosaisolates from only two of nine of the sinks previously foundto be contaminated. The water supply into these sinks was thensuspended, preventing their further use. Subsequent testingin November 2003 did not reveal the environmental presence ofthe epidemic strain; nevertheless, the strain continued to beisolated from patients, although more often as a colonist thanas a pathogen. Its isolation remains related to very long stays,surgical procedures, peritonitis, and extensive prior antimicrobialtherapy.

DISCUSSION

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Discussion

Carbapenems are potent agents against multiresistant gram-negativebacilli, including P. aeruginosa, but survey data show emergingresistance, principally in nonfermenters (9, 10, 34; M. D. Obritsch,D. N. Fish, R. MacLaren, and R. Jung, Abstr. 43rd Intersci.Conf. Antimicrob. Agents Chemother., abstr. 1970, 2003; M. K.Weaver, D. Styers, M. E. Jones, C. Thornsberry, and D. F. Sahm,Abstr. 43rd Intersci. Conf. Antimicrob. Agents Chemother., abstr.1962, 2003). In the case of P. aeruginosa, the most frequentmechanism of resistance is loss of the porin OprD (24), butcarbapenem-hydrolyzing ß-lactamases are increasinglyreported. They spread first in Japan and Korea and more recentlyin Europe (4, 26, 27) and the Americas (7, 11). Large outbreaksby MBL-producing P. aeruginosa strains have been described inhospitals in Italy, Greece, and Korea (4, 14, 16, 18, 20, 29),as well as in Latin America, notably, including one caused bya P. aeruginosa strain with an SPM-1 ß-lactamase inBrazil (7). The SENTRY surveillance program for 1999 to 2002reported MBLs in P. aeruginosa and/or Acinetobacter spp. fromArgentina, Chile, Brazil, and Venezuela, but not Colombia (8);nevertheless, the prevalence of imipenem resistance among P.aeruginosa isolates at the hospital in Cali described in thepresent study rose from 2% in 1996 to 28% in 1997 and 49% in2002. At least from 1998 onwards, this rise in resistance wassubstantially due to the type A outbreak-related P. aeruginosastrain, which produced bla_VIM-8. Retrospective analysis suggestedthat the possible source of this strain was a patient transferredfrom another hospital in 1997. The isolates obtained from thispatient in the adult ICU were highly resistant to ceftazidime,imipenem, and meropenem, as were most of the subsequent outbreakisolates. Unfortunately, these isolates were not recoverablefor analysis in the present study.

The type A strain was mostly isolated from groups conventionallyseen as being at high risk for infection with multiresistantisolates, such as ICU patients, patients with long hospitalstays, patients of early or advanced age, and patients withsevere underlying conditions. An environmental reservoir wasfound, especially in the adult ICU, where several sinks werecontaminated. This contamination was exacerbated by design flawsin the sinks, and the outbreak was reduced following cleaningand decommissioning of these sinks. Contamination of stethoscopeswas also noted.

Isolates belonging to the type A strain showed minor phenotypicvariability but mostly had high-level multiresistance to ß-lactams,aminoglycosides, and fluoroquinolones, suggesting the presenceof aminoglycoside-modifying enzymes and DNA gyrase mutations,as well as the MBL. Many integrons determining the VIM or theIMP ß-lactamase also encode aminoglycoside-modifyingenzymes.

Many type A isolates appeared to be susceptible to piperacillin(with or without tazobactam) and aztreonam. Such susceptibilityhas been described in other VIM- and IMP-producing P. aeruginosastrains (5, 11, 35) and is not surprising in the case of aztreonam,which is stable to MBLs. The behavior of piperacillin partlyreflects the NCCLS's very high breakpoints (susceptible, MIC $≤$ 64 µg/ml), which are 16-fold above the modal MIC forsusceptible P. aeruginosa isolates and well within the rangeexpected for strains with acquired resistance. Nevertheless,it is surprising that nearly half of the isolates were susceptibleto piperacillin at the much lower breakpoints used in the UnitedKingdom and Europe (1). Combinations of aztreonam with piperacillin-tazobactamwere used clinically for the infected patients, many of whomrecovered. It was not, however, possible to identify the relativecombinations of therapy and general healthcare to the outcome.

This is the first evidence of a VIM-type enzyme in Colombiaand only the second account of a major outbreak caused by anMBL producer in South America. The enzyme, VIM-8, was a novelvariant, differing from VIM-2 only by a Thr139Ala substitution.Thr139 is also modified (to Ile) in VIM-9 (GenBank accessionnumber AY524988), a variant from P. aeruginosa in the UnitedKingdom (J. M. Coelho, N. Woodford, J. Turton, and D. Livermore,Abstr. 43rd Intersci. Conf. Antimicrob. Agents Chemother., abstr.1965, 2003). The producer strain belonged to serotype O12, anuncommon ( $≤$ 1%) serotype among P. aeruginosa isolates as a wholebut one that has a long-recognized association with multiresistance(23). Outbreaks of VIM ß-lactamase-producing, serotypeO12 P. aeruginosa strains have occurred in Italy (5), Greece(20, 32), and Korea (18). Fifteen years ago, O12 was the majorserotype of P. aeruginosa strains hosting the PSE-1 ß-lactamase,at least in Europe (26). It may be that serotype O12 strains,which form a tight cluster in terms of DNA relatedness (21,25), are particularly adept at acquiring or hosting the integronsthat encode the IMP, VIM, and PSE enzymes, but this hypothesisis speculative.

This study illustrates the importance of phenotypic and genotypicsurveillance to guide infection control. Initially, in 1997,the outbreak was attributed to the overuse of imipenem, andunsuccessful control measures whose aim was to replace imipenemuse with cefepime and piperacillin-tazobactam use were taken.Nevertheless, the rate of imipenem use rose (Fig. 1), and imipenem-resistantP. aeruginosa strains continued to be isolated, with littleobvious relationship to the rate of imipenem use (Fig. 1). Onlymuch later, when phenotypic surveillance and molecular typingwere performed, were appropriate infection control measurestaken, and these achieved a reduction in prevalence from thepeak in 2002 (Fig. 1). These environmental studies revealedpersistent contamination of the adult and neonatal ICUs by typeA strains. Although the affected patients were exposed to manyantibiotics, previous imipenem consumption was uncommon (onlynine patients). Similar findings were also reported in Japanand Italy, where IMP and VIM ß-lactamase-producingP. aeruginosa strains spread as hospital pathogens without specificselection by carbapenems (5, 18).

FOOTNOTES

* Corresponding author. Mailing address: Group of Medical Microbiology and Infectious Diseases, Universidad Santiago de Cali, Carrera 74 A # 11 A 17, Cali, Colombia. Phone: 572-3398410. Fax: 572-2731927. E-mail: macrespo{at}emcali.net.co.

REFERENCES

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