Risk Factors for Colonization and Infection in a Hospital Outbreak ...

JOURNAL OF CLINICAL MICROBIOLOGY, Sept. 2004, p. 4242–4249 0095-1137/04/$08.00⫹0 DOI: 10.1128/JCM.42.9.4242–4249.2004 Copyright © 2004, American Society for Microbiology. All Rights Reserved.

Vol. 42, No. 9

Risk Factors for Colonization and Infection in a Hospital Outbreak Caused by a Strain of Klebsiella pneumoniae with Reduced Susceptibility to Expanded-Spectrum Cephalosporins Monica Cartelle,1 Maria del Mar Tomas,1 Sonia Pertega,2 Alejandro Beceiro,1 M. Angeles Dominguez,3 David Velasco,1 Francisca Molina,1 Rosa Villanueva,1 and German Bou1* Servicio de Microbiología1 and Unidad de Epidemiologia Clinica,2 Complejo Hospitalario, Universitario Juan Canalejo, La Corun ˜a, and Servicio de Microbiología, Hospital de Bellvitge, Barcelona,3 Spain Received 24 December 2003/Returned for modification 4 April 2004/Accepted 29 April 2004

Between February 2001 and January 2002, an increase in the number of Klebsiella pneumoniae isolates with reduced susceptibility to expanded-spectrum cephalosporins (RSKp) was detected in the neonatal unit of the Juan Canalejo Hospital, and 21 patients were either colonized or infected by the bacterial isolates. The current “gold standard” method for typing K. pneumoniae isolates is pulsed-field gel electrophoresis. However, this technique is expensive and time-consuming. In a search for faster and accurate alternatives to this method, we investigated PCR-based fingerprinting techniques (enterobacterial repetitive intergenic consensus sequence PCR [ERIC-PCR], repetitive extragenic palindromic sequence-based PCR [REP-PCR], and RAPD [randomly amplified polymorphic DNA]) for their ability to characterize K. pneumoniae isolates. The causal agent of the nosocomial outbreak was characterized by these techniques and was found to be a single epidemic strain (RSKp). A multiple regression logistic model was developed to identify potential independent factors associated with colonization and/or infection by RSKp. Logistic regression analysis was applied to all significant variables (P < 0.05) in the univariate analysis, and it was revealed that intubation (odds ratio [OR], 27.0; 95% confidence interval [95%CI], 5.39 to 135.14) and prematurity (OR, 4.4; 95%CI, 0.89 to 21.89) were such independent factors. Moreover, oxime cephalosporins did not appear to be statistically significant. Overall, the results showed that PCR-based techniques are expeditious and useful methods for typing K. pneumoniae isolates. Of the techniques studied, ERIC-PCR showed the highest discriminatory index (D ⴝ 0.828), followed by RAPD (D ⴝ 0.826) and REP-PCR (D ⴝ 0.773) Klebsiella pneumoniae has previously been reported to be associated with 2 to 5% of nosocomial infections, particularly those involving the lower respiratory and urinary tracts (8, 16, 22, 25). Resistance of this species to expanded-spectrum cephalosporins was first described in the early 1980s, and an increase in resistance has occurred since 1986 (3, 7, 8, 18, 22). Resistant isolates probably acquire their resistance by producing extended-spectrum ␤-lactamases (ESBLs) (22). The epidemiology of ESBL has previously been investigated, and several studies have described the potential risk factors associated with colonization or infection with multiresistant K. pneumoniae isolates (1, 28). The present study describes a nosocomial outbreak caused by a K. pneumoniae strain that showed reduced sensitivity to expanded-spectrum cephalosporins. Pulsed-field gel electrophoresis (PFGE) analysis of genome macrorestriction fragments has been shown to be a discriminatory technique for typing different microorganisms (2, 10, 11, 12); however, it is technically demanding and time-consuming and requires specific equipment. Other PCR-based typing techniques, such as randomly amplified polymorphic DNA (RAPD) analysis, are faster and easier to perform. In recent

studies, RAPD analysis has been successfully used to type diverse microorganisms (6, 11, 15, 25, 30). Moreover, repetitive extragenic palindromic sequencebased PCR (REP-PCR) and enterobacterial repetitive intergenic consensus sequence PCR (ERIC-PCR) have also been successfully used for typing K. pneumoniae isolates (4, 7, 8, 13, 16). However, the comparative typing ability, reproducibility, discriminatory power, and efficiency of these methods were not fully investigated in all of these studies. Therefore, although these PCR-based methods are widely used and reported in the medical literature, it remains to be determined which is the most discriminatory and reproducible PCR-based method for typing K. pneumoniae isolates in an outbreak setting. We sought to do this in the present study. K. pneumoniae is an important hospital-acquired pathogen with the potential to cause severe morbidity and mortality in pediatric patients. Several outbreaks of infection caused by K. pneumoniae isolates that are simultaneously resistant to broadspectrum cephalosporins and aminoglycosides have been reported (1, 3, 18, 22). The risk factors associated with colonization or infection by epidemic strains harboring ESBL and showing high expanded-spectrum cephalosporin MICs have already been clearly demonstrated (1). However, the risk factors associated with infection or colonization by bacterial strains for which the expanded-spectrum cephalosporin MICs are not high (or low), i.e., strains that are categorized as susceptible according to NC-

* Corresponding author. Mailing address: Servicio de Microbiologia, Complejo Hospitalario Juan Canalejo, C/As Xubias 84, 15006 La Corun ˜a, Spain. Phone: 34-981-178000, ext. 21144. Fax: 34-981-178216. E-mail: [email protected]. 4242

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CLS criteria but show reduced susceptibility to expanded-spectrum cephalosporins, remain unknown. In summary, we report the molecular characterization of a nosocomial outbreak caused by an epidemic strain of K. pneumoniae (RSKp) with reduced susceptibility to expanded-spectrum cephalosporins. In addition, we also report the risk factors associated with infection or colonization by this bacterial strain. (Part of this study was presented previously [M. Cartelle, A. Beceiro, E. Gil, M. Dominguez, F. Molina, J. M. Eiros, and G. Bou, 42nd Intersci. Conf. Antimicrob. Agents Chemother., abstr. 1438, p. 143, 2002].) MATERIALS AND METHODS Microbiological studies. (i) PFGE. Macrorestriction analysis of chromosomal DNA with XbaI (New England Biolabs, Boston, Mass.) was carried out by PFGE according to published procedures (12). PFGE was performed by using a CHEFDRIII apparatus (Bio-Rad Laboratories, Richmond, Calif.), with pulses ranging from 0.5 to 15 s and at a voltage of 6 V/cm, at 14°C for 20 h. Products were detected after ethidium bromide staining (50 mg/liter) and photographed with Polaroid type 665 film. The interpretation of PFGE patterns was according to the method of Tenover et al. (27). (ii) PCR typing methods. Chromosomal DNA of the K. pneumoniae isolates was obtained according to standard protocols (24). For REP-PCR and ERICPCR, 500 ng of the chromosomal template was used, and the reactions were carried out with oligonucleotides, as previously reported (29). Aliquots (20 ␮l) of each sample were subjected to electrophoresis on 1.0% agarose gels. Isolates belonging to the same genotypes assigned according to the PCR band pattern showed identical or highly similar profiles (up to two bands different). The REP-PCR was performed as follows: denaturation for 10 min at 94°C; amplification for 1 min at 94°C, 1 min at 45°C, and 2 min at 72°C for 30 cycles; and elongation for 16 min at 72°C. The ERIC-PCR was performed as follows: denaturation for 10 min at 94°C; amplification for 1 min at 94°C, 1 min at 52°C, and 2 min at 72°C for 30 cycles; and then elongation for 16 min at 72°C. The RAPD analysis was performed according to the manufacturer’s instructions (Ready-To-Go RAPD analysis beads; Amersham Pharmacia Biotech, ICN). Aliquots (20 ␮l) of each sample were subjected to electrophoresis on 2.0% agarose gels. Amplified products were detected after ethidium bromide staining (50 mg/liter) and photographed with Polaroid type 665 film. Isolates belonging to the same genotypes were grouped according to the PCR band pattern (up to two bands different). (iii) Reproducibility and discriminatory index. Reproducibility was measured as the ability of a technique to yield identical results with testing of the same strain on three different experiments with different DNA preparations, and it was expressed as the percentage of strains that gave the same profile in the three separate experiments (⫹⫹⫹, ⬎75%; ⫹⫹, 50 to 75%; ⫹, ⬍50%). The discriminatory index was calculated according to the method of Hunter and Gaston (14). We studied a set of K. pneumoniae isolates associated with outbreak of infection that were genetically related; therefore, we modified the method accordingly. For PCR-based methods, we maintained the same number of strains in all cases and evaluated the differences in genotypes. To consider the presence of subtypes among a specific genotype, we introduced a correcting factor in the equation of Hunter and Gaston by adding the number of strains with different subtypes belonging to a specific genotype. This correction may improve, at least in part, some of the limitations of this index. Fifty isolates of K. pneumoniae (including forty-three clinical and seven American Type Culture Collection [ATCC] isolates) were used to determine the reproducibility and discriminatory index of the different techniques. (iv) Strains. Clinical isolates of K. pneumoniae were identified by API 20E (bioMe´rieux) and MicroScan (Walkaway-96). In genotypic studies and for comparative purposes, seven different isolates of K. pneumoniae were used as controls (ATCC 7761, ATCC 10031, ATCC 13883, ATCC 27736, ATCC 29995, ATCC 29665, and ATCC 9621). Forty-three clinical isolates of K. pneumoniae were used for genotypic studies. Of these, 33 were isolated from 21 newborns, and they showed a phenotype of reduced susceptibility to expanded-spectrum cephalosporins and aztreonam (ESBL phenotype). The remaining 10 clinical isolates of K. pneumoniae were isolated from 10 different patients during the outbreak, and they were probably not related to the outbreak-associated strains (non-ESBL phenotype). For comparative purposes and to facilitate interpretation of the results, the DNA band patterns of 31 K. pneumoniae strains isolated from 31 different patients are

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shown (Table 1); 21 of these patients were either colonized or infected by strain RSKp (showing an ESBL phenotype), and the remaining 10 were colonized or infected by K. pneumoniae isolates not showing an ESBL phenotype and probably not associated with the outbreak of infection. Also, the interpretation of the band pattern of the seven ATCC K. pneumoniae isolates is shown (Table 1). To localize the source of the RSKp strain that caused the nosocomial outbreak of infection or colonization, samples were collected from different areas of the neonatal unit. Samples were analyzed by ERIC-PCR to test for any genetic relationship with the RSKp epidemic strain. (v) Antimicrobial susceptibility pattern. The pattern of antibiotic susceptibility was determined by disk diffusion according to NCCLS criteria (20). MICs were confirmed by E-test (AB Biodisk, Solna, Sweden) according to the manufacturer’s directions. Subjects and methods used in the clinical epidemiological study: risk factors involved in acquiring strain RSKp. (i) Setting. The present study was carried out in the neonatal unit of the Juan Canalejo Hospital Complex in La Corun ˜a, Spain. This is a 1,200-bed university tertiary-level medical center that serves a population of 516,000 people. (ii) Patients. In February 2001, the Department of Microbiology in the hospital complex reported the occurrence of a cluster of K. pneumoniae isolates with reduced susceptibility to expanded-spectrum cephalosporins (RSKp) in the neonatal unit. The infection control personnel were immediately engaged in investigation of the outbreak. In addition to clinical samples, screening samples were obtained twice a week from all patients admitted to the neonatal unit. Screening samples were obtained from pharynx and rectum. A total of 21 newborns were infected or colonized by RSKp. Several patients were selected to take part in case-control studies aimed at detecting the risk factors associated with colonization or infection by RSKp strains. A case study patient was defined as a patient who was admitted to the neonatal unit during the period from 1 February 2001 to 29 February 2002 and then became either clinically infected or colonized by RSKp. A control patient was defined as a patient admitted to the neonatal unit between 1 February 2001 and 29 February 2002 whose screening cultures were all negative for RSKp. These patients were retrospectively selected. A total of 21 case patients and 44 control patients were thus considered in the study. Clinical and epidemiological data were collected from the medical records of all patients admitted to the unit during the period under study. The potential risk factors studied are discussed below (see Tables 4 and 5). (iii) Study design. This case-control study compared the frequency of exposure and the features of case patients with those of control patients in order to identify and quantify potential independent risk factors associated with colonization and/or infection by RSKp. (iv) Statistical analysis. Univariate analysis was carried out for determination of variables significantly associated with colonization or infection by RSKp. Contingency tables were analyzed by two-tailed ␹2 test or by Fisher exact test. Quantitative variable differences between case and control patients were compared by using the Student t test or Mann-Whitney test when appropriate. The Kolmogorov-Smirnov test was used to assess normality. A multiple-regression logistic model was developed to identify the potential independent factors associated with colonization and/or infection by RSKp. We followed a forward stepwise strategy, adjusting for all variables that were statistically significant in the univariate analysis or that were clinically relevant. Ninety-five percent confidence intervals (95%CIs) were calculated as estimators. Two-sided tests were used for all analyses. The results were considered statistically significant at a P of ⬍0.05. The data were stored and analyzed by using SPSS 11.5. Description of the outbreak and control measures taken. The strain of RSKp index case of the outbreak was first isolated in cultures of a conjunctival infection from a 7-day-old infant on 5 February 2001. The diagnosis in this case was conjunctival infection, and this patient was considered the index case of the outbreak. This patient remained in the neonatal unit until her health status improved and left the hospital 8 days after admission. During the following year (February 2001 to February 2002), 20 newborns admitted to the same neonatal unit were infected or colonized by a strain of K. pneumoniae (Table 1) showing the same phenotype of reduced susceptibility (RSKp) to expanded-spectrum cephalosporins. The MICs for the RSKp strain are shown in Table 2. Environmental samples were collected and analyzed for the presence of the RSKp strain. Cultures yielded a positive result for RSKp isolates in some cases, suggesting the involvement of an environment reservoir in the dissemination of the epidemic strains. The outbreak was controlled by implementation of certain measures: the relevant patients were either isolated in single cots (whenever possible) or grouped together, and the standard and contact isolation precautions were strengthened. All surfaces of the different intensive care units and departments were also cleaned. Health care

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TABLE 1. Patients infected or colonized by the RSKp strains and those included in the genotypic study Patient dataa Wardb

Type of infection or colonizationc

Sample typed

Hospital stay (days)

Previous treatmente

A, To A, To, Mp A-Clav, Ce A, To Ce, Te, Azt A, To A, To, Te A, To, Te A, To, Mz A, To, Gn A, To, Te, Caz Te, Ctx, Me, A, To, Mp A, To A, To, Cf, Gn A, To, Me Tc, Caz, Me A, To Me, Te, Caz, A, To Te, Ctx, Me, Co, To, Azt, Ce, Ak A A, To, Te

Sex

Date of isolation

1 2 3 4 5 6 7 8 9 10 11 12

F M M F F M F M F F F M

2.5.01 2.7.01 2.19.01 2.19.01 2.19.01 2.20.01 2.23.01 3.10.01 4.4.01 4.10.01 4.20.01 4.30.01

P-ICU N-Dep N-Dep N-Dep N-Dep N-Dep N-ICU N-ICU P-ICU P-ICU N-Dep N-Dep

CoI Ent Colonization Ent Colonization Col Ent CaI Ent UTI UTI Sepsis

Co.Ex. Stool End.Tube Stool End.Tube Co.Ex. Stool Cateter Stool Urine Urine Blood

8 5 5 2 78 7 10 14 44 22 35 28

13 14 15 16 17 18

M M F M M M

5.8.01 6.8.01 7.2.01 7.5.01 7.12.01 12.24.01

N-Dep N-Dep N-Dep N-Dep N-Dep N-Dep

Colonization Colonization CoI Sepsis UTI UTI

Stool End.Tube Co.Ex Blood Urine Urine

8 19 6 80 7 45

19

F

12.28.01 N-Dep

Sepsis

Blood

171

20 21 22 23

M M M F

2.12.02 2.16.02 1.16.01 12.6.01

N-Dep N-Dep PHC-C P-Dep

Sepsis Sepsis UTI Sepsis

Blood Blood Urine Blood

6 14 0 270

24 25 26 27 28 29 30 31 32 33 34 35 36 37 38

M F F F F M F M

2.8.01 2.8.01 2.20.01 3.5.01 4.9.01 5.1.01 5.2.01 6.1.01

M-ICU M-ICU PHC-C PHC-C M-ICU M-ICU SCI-ICU O-Dep

Wound infection Wound infection UTI UTI UTI UTI UTI Hearing infection

Wo.Ex. Wo.Ex. Urine Urine Urine Urine Urine Hear.Ex.

58 18 0 0 240 150 130 0

No.f

(7761) (10031) (13883) (27736) (29995) (29665) (9621)

A, To, Im, Mp, Va

A-Clav

Genotype as determined by: ESBL phenotype PFGE ERIC-PCR REP-PCR RAPD

Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes

I I I I I I I I I I I I

1 1 1 1 1 1 1 1 1 1 1 1

A.1 A.1 A.1 A.1 A.1 A.1 A.1 A.1 A.1 A.1 A.1 A.1

a.1 a.1 a.2 a.2 a.2 a.2 a.2 a.2 a.2 a.2 a.2 a.2

Yes Yes Yes Yes Yes Yes

I I I I I I

1 1 1 1 1 1

A.1 A.1 A.1 A.1 A.1 A.1

a.2 a.2 a.2 a.2 a.2 a.2

Yes

I

1

A.1

a.2

Yes Yes No No

I I II III

1 1 2 3

A.1 A.1 A.2 A.1

a.2 a.2 b c

No No No No No No No No

IV III V VI VII VIII IX X XI XII XIII XIV XV XVI XVII

4 3 5 6 7 8 9 10 11 12 13 14 15 16 17

B A.1 C D E F G H I.1 I.2 J K L LL M

d c e f g h i j k l ll m n n ˜ o

a

M, male; F, female. Date of isolation: month.day.year. Wards: N-Dep, neonatal unit; N-ICU, neonatal intensive care unit; P-Dep, pediatric department; P-ICU, pediatric ICU; M-ICU, medical ICU other than those for neonatal and pediatric patients; PHC-C, primary health care center; SCI-ICU, spinal cord injury ICU; O-Dep, otolaryngology department. c Col, conjunctival infection; Ent, enterocolitis; UTI, urinary tract infection; CaI, catheter infection. d Co.Ex., conjunctival exudate; Wo.Ex., wound exudate; End.Tube, endotracheal tube; Hear.Ex., hearing exudate. e A, ampicillin; To, tobramycin; Tc, ticarcillin; Caz, ceftazidime; Gn, gentamicin; Me, metronidazole; Mp, meropenem; A-Clav, amoxicillin-clavulanate; Ce, cephazoline; Co, colistin; Azt, aztreonam; Ctx, cefotaxime; Te, teicoplanin; Ak, amikacin; Im, imipenem; Va, vancomycin. f ATCC numbers are given in parentheses for nonclinical isolates. b

personnel were reminded to wash their hands carefully before and after contact with patients and to wear disposable gloves and gowns. Moreover, doctors were advised to use antibiotics with caution, particularly expanded-spectrum cephalosporins.

RESULTS REP-PCR, ERIC-PCR, and RAPD analysis of K. pneumoniae ATCC strains. K. pneumoniae strains ATCC 7761, ATCC 10031, ATCC 13883, ATCC 27736, ATCC 29995, ATCC 29665, and ATCC 9621 were used to test the capacity of typing of the PCR-based DNA fingerprinting techniques (strains 32 to 38 in Table 1). Analysis by PFGE of these strains showed

seven different genotypes according to the criteria of Tenover et al. (27 and data not shown). Using PCR-DNA techniques, seven different genotypes were obtained by ERIC-PCR and RAPD techniques, whereas six genotypes (one genotype had two subtypes) were detected by REP-PCR (data not shown). Overall, the results suggested that the PCR-based techniques were useful, particularly RAPD and ERIC-PCR. The next step was to extend the study to a set of clinical strains of K. pneumoniae putatively involved in a nosocomial outbreak of infection or colonization.

HOSPITAL OUTBREAK CAUSED BY K. PNEUMONIAE

VOL. 42, 2004 TABLE 2. Antibiotic MICs for the epidemic strain RSKp Antibiotic

MIC (mg/liter) for strain RSKp

Amoxicillin ...............................................................................⬎256 Amoxicillin-clavulanic acid .................................................... 12 Cephalothin.............................................................................. 128 Cefuroxime............................................................................... 24 Cefoxitin ................................................................................... 2 Cefotaxime ............................................................................... 0.5 Cefotaxime-clavulanic acid .................................................... 0.047 Ceftazidime .............................................................................. 2 Ceftazidime-clavulanic acid ................................................... 0.125 Aztreonam................................................................................ 2 Cefepime .................................................................................. 0.094 Imipenem ................................................................................. 0.19 Meropenem.............................................................................. 0.023 Amikacin .................................................................................. 16 Tobramycin .............................................................................. 8 Ciprofloxacin............................................................................ 0.023

Study of the nosocomial outbreak. (i) PFGE of the clinical strains. A total of 43 clinical strains of K. pneumoniae isolated from patients between February 2001 and February 2002 were used with two objectives: (i) to confirm the usefulness of the PCR-based typing methods and (ii) to characterize the nosocomial outbreak of infection. Thirty-three RSKp strains (isolated from 21 newborns) with the ESBL phenotype and probably related to the nosocomial outbreak of infection were tested by PFGE for genetic relationship. For comparative purposes, 10 clinical strains of K. pneumoniae not showing any ESBL phenotype and isolated at outbreak were used as controls. The results of PFGE of 31 representative strains of K. pneumoniae described in Table 1 are shown in Fig. 1A. Analysis by PFGE is considered the “gold standard” method for typing K. pneumoniae isolates, and therefore we used it first in our attempt to identify the genotypes of the RSKp strains. All strains with ESBL phenotype (MICs in Table 2) were not distinguished in epidemiological terms, and they were assigned to genotype I. Overall, 17 different genotypes, classified according to the criteria of Tenover et al. (27), were obtained by applying this technique to the representative K. pneumoniae strains (Table 1). (ii) ERIC-PCR, RAPD, and REP-PCR analysis of clinical strains. Strains identical to those analyzed by PFGE were tested by ERIC-PCR, RAPD, and REP-PCR. Using the ERIC-PCR technique, we detected a band pattern ranging from 0.2 to 3 kb (Fig. 1B). All of the RSKp strains showed the same band pattern, and they were assigned to genotype 1. Control strains 22 to 31 showed different band profiles, and they were assigned to genotypes 2 to 10. From all of the strains tested, a total of 17 different genotypes were obtained by ERIC-PCR (Table 1). The ERIC-PCR and PFGE techniques therefore showed similar discriminatory capacities. Using RAPD-PCR, we also obtained a band pattern from 0.2 to 3 kb (Fig. 1C). On the gels, a major DNA band was obtained with each different strain; with the epidemic RSKp strains; this band migrated to ca. 800 bp. Moreover, a few minor bands were obtained at lower molecular weights. The minor bands showed some degree of variability in different experiments in contrast to the main amplified bands, which remained quite stable in different experiments. All of the

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RSKp strains yielded an identical genotype (a.2 in Table 1). There was some degree of variability associated with this technique, as seen with strains 1 and 2 (Fig. 1C). For this reason these strains were categorized as subtypes of the main genotype. Overall, RAPD yielded 17 different genotypes with the K. pneumoniae strains studied. Using REP-PCR, we again observed a band profile ranging from 0.2 to 3 kb (Fig. 1D). All strains with the ESBL phenotype were also grouped with an identical genotype (pattern A.1 in Table 1). With the control strains of K. pneumoniae tested, 14 different genotypes and one different subtype were obtained; strain 22 showed only one band different from those of the strains associated with the nosocomial infection and was categorized with this technique as a subtype of the main genotype. Moreover, although the genotype of strain 23 was clearly differentiated from that of the RSKp strains by PFGE, ERIC-PCR, and RAPD, the results of the REP-PCR technique showed the genotype to be practically indistinguishable from that of the epidemic RSKp strain (only one minor band differed), thus revealing some limitations of this technique. Overall, REP-PCR yielded 14 genotypes among the strains analyzed. (iii) Reproducibility and discriminatory index of the PCRbased methods. The discriminatory index was calculated with the 43 clinical strains of K. pneumoniae and the 7 ATCC strains of K. pneumoniae as described in Materials and Methods. The overall results are shown in Table 3. The ERIC-PCR showed the best discriminatory capacity, followed by RAPD and REPPCR, respectively. As previously reported, RAPD showed the lowest degree of reproducibility. (iv) Risk factors for clinical colonization or infection by strain RSKp. From 1 February 2001 to 29 February 2002, 21 patients (cases) admitted to the neonatal unit became clinically colonized (n ⫽ 4) or infected (n ⫽ 17) by the RSKp strain. In the same period, 44 patients admitted to the unit were either infected or colonized by non-RSKp strains (controls). The clinical presentations in the infected newborns were as follows: sepsis, n ⫽ 5; urinary tract infection, n ⫽ 4; enterocolitis, n ⫽ 4; conjunctival infection, n ⫽ 3; and catheter infection, n ⫽ 1. Samples were taken from an endotracheal tube (n ⫽ 3) and stool (n ⫽ 1) of colonized patients (Table 1). In the univariate analysis, the differences between the 21 cases and the 44 controls are shown in Tables 4 and 5. The following factors were associated with strain RSKp: number of additional hours ⬎24 h before birth with rupture of amniotic sac (33.3% in cases versus 11.4% in controls), low birth weight (33.3% versus 6.8%), and prematurity (71.4% versus 15.9%). Parenteral nutrition (71.4% versus 15.9%), intubation (85.7% versus 11.4%), underlying disease (52.4% versus 13.6%), previous surgery (14.3% versus 0%), and the presence of intravascular catheter (71.4% versus 13.6%) were also more frequent in the infected or colonized group, as well as administration of antibiotics: ␤-lactam, aminoglycosides, or glycopeptides. There were also statistically significant differences between the number of days of stay in neonatal unit. The controls had lower numbers of days of intensive care unit stays than those infected or colonized by the RSKp strain (28.24 versus 3.02 days). Similarly, the number of days with nasogastric tube was higher for the case group (0.14 versus 0), as well as the number of days with vascular catheter (17.9 versus 1.39),

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FIG. 1. PFGE (A), ERIC-PCR (B), RAPD (C), and REP-PCR (D) band patterns obtained with the strain indicated above the gel and described in Table 1.

parenteral nutrition (10.09 versus 1.45), intubation (10.81 versus 0.48), and administration of antibiotics. The multiple-logistic-regression model (Table 6) revealed that the presence of intubation (odds ratio [OR], 27.0; 95%CI, 5.39 to 135.14) and prematurity (OR, 4.41; 95%CI, 0.89 to 21.89) were factors independently associated with RSKp infection and/or colonization. DISCUSSION In the past two decades, a significant number of nosocomial outbreaks of infection by K. pneumoniae have been reported (1, 18, 25), causing increasing concern in hospitals. In order to investigate the origin of the infection, the route of dissemination, and the prevalence of isolates in a bacterial population, several phenotypic and molecular typing methods have been described. Rapid and accurate identification of the strains in-

volved in an outbreak is important, both for limiting the severity of the outbreak and for tracing the source of the infecting organism. Although antibiotyping may sometimes be used to distinguish isolates with different antibiotic susceptibility patterns, distinction between strains with slight differences in resistance profiles may be difficult. Therefore, genotypic methods, including plasmid typing, ribotyping, PFGE of chromosomal DNA restriction fragments, and PCR fingerprinting have been used to investigate nosocomial K. pneumoniae strains (2, 4–6, 8, 9, 11–13, 15, 16, 30). The relative advantages and disadvantages of these methods have previously been reviewed (21). The REP-PCR, ERIC-PCR, and RAPD fingerprinting techniques have previously been used for typing K. pneumoniae strains (4, 5, 7, 8, 9, 13, 16, 30). However, these studies were performed with a small number of strains, and it was prob-

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FIG. 1—Continued.

ably assumed that these techniques worked well for typing K. pneumoniae strains, without confirmation of this by detailed comparison of the techniques for typing K. pneumoniae isolates. Indeed, there are no reports in the medical literature of a comparative study of the four methods used in the present study for typing K. pneumoniae isolates. TABLE 3. Discriminatory index (D) and reproducibility of the PCR typing methods studied Typing method

D

Reproducibility

ERIC-PCR REP-PCR RAPD

0.828 0.773 0.826

⫹⫹⫹ ⫹⫹⫹ ⫹⫹

Therefore, although the lack of reproducibility of the RAPD method has been demonstrated several times, the power of discrimination and reproducibility of the ERIC-PCR, REPPCR, and RAPD techniques remain unknown. Therefore, to assess the degree of usefulness of the PCR-based fingerprinting techniques (ERIC-PCR, RAPD, and REP-PCR) we carried out the present study with a set of control K. pneumoniae ATCC strains and also 43 K. pneumoniae clinical strains. All of the strains were previously tested with PFGE as the gold standard method. With the strains of K. pneumoniae shown in Table 1, 17 different genotypes were obtained by ERIC-PCR that were identical to those obtained by PFGE and RAPD, whereas only 14 genotypes were obtained by REP-PCR. These results revealed differences in the discrimination capacities of the PCR methods assayed.

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TABLE 4. Comparison of several qualitative variables with case-control patients prior to isolation Variable

Mother colonized with S. agalactiae Rupture of amniotic sac more than 24 h before birth Cesarean Sex Male Female Birth weight (⬍1,500 g) Underlying disease Previous surgery (7 days) High prematurity (28–30 wk) Presence of urinary catheter Presence of nasogastric tube Presence of intravascular catheter Parenteral nutrition Intubation Administration of ␤-lactam antibiotics Administration of aminoglycosides Administration of glycopeptides a b

Controls (n ⫽ 44)

Cases (n ⫽ 21)

Pb

OR (95%CI)

n

%

n

%

2 7 8

9.5 33.3 38.1

11 5 9

25 11.4 20.5

0.194 0.045 0.130

0.31 (0.06–1.58) 3.90 (1.06–14.31) 2.39 (0.76–7.52)

13 29 7 11 3 15 1 2 15 15 18 21 17 9

61.9 65.9 33.3 52.4 14.3 71.4 4.8 9.5 71.4 71.4 85.7 100 81 42.9

29 15 3 6 0 7 0 0 6 7 5 22 18 2

65.9 34.1 6.8 13.6 0 15.9 0 0 13.6 15.9 11.4 50 40.9 4.5

0.752

1.19 (0.40–3.50) 6.83 (1.55–30.09) 6.96 (2.07–23.46) NCa 13.21 (3.81–45.87) NC NC 15.83 (4.40–56.93) 13.21 (3.81–45.87) 46.80 (10.07–217.53) NC 6.14 (1.77–21.30) 15.75 (2.99–82.92)

0.010 0.001 0.030