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Journal of Clinical Microbiology, November 2000, p. 4086-4095, Vol. 38, No. 11
0095-1137/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Emergence and Rapid Spread of Carbapenem Resistance during a
Large and Sustained Hospital Outbreak of Multiresistant
Acinetobacter baumannii
Xavier
Corbella,1,*
Abelardo
Montero,1
Miquel
Pujol,1
M.
Angeles
Domínguez,2
Josefina
Ayats,2
M. José
Argerich,1
Frederic
Garrigosa,3
Javier
Ariza,1 and
Francesc
Gudiol1
Departments of Infectious Diseases,1
Microbiology,2 and Intensive Care
Medicine,3 Hospital de Bellvitge, University
of Barcelona, Barcelona, Spain
Received 28 April 2000/Returned for modification 2 June
2000/Accepted 31 July 2000
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ABSTRACT |
Beginning in 1992, a sustained outbreak of multiresistant
Acinetobacter baumannii infections was noted in our
1,000-bed hospital in Barcelona, Spain, resulting in considerable
overuse of imipenem, to which the organisms were uniformly
susceptible. In January 1997, carbapenem-resistant (CR)
A. baumannii strains emerged and rapidly
disseminated in the intensive care units (ICUs), prompting us to
conduct a prospective investigation. It was an 18-month longitudinal
intervention study aimed at the identification of the clinical and
microbiological epidemiology of the outbreak and its response to a
multicomponent infection control strategy. From January 1997 to June
1998, clinical samples from 153 (8%) of 1,836 consecutive ICU patients
were found to contain CR A. baumannii. Isolates
were verified to be A. baumannii by restriction analysis of the 16S-23S ribosomal genes and the intergenic spacer region. Molecular typing by repetitive extragenic palindromic sequence-based PCR and pulsed-field gel electrophoresis showed that the
emergence of carbapenem resistance was not by the selection of resistant mutants but was by the introduction of two new epidemic clones that were different from those responsible for the endemic. Multivariate regression analysis selected those patients with previous carriage of CR A. baumannii
(relative risk [RR], 35.3; 95% confidence interval [CI], 7.2 to
173.1), those patients who had previously received therapy with
carbapenems (RR, 4.6; 95% CI, 1.3 to 15.6), or those who
were admitted into a ward with a high density of patients infected with
CR A. baumannii (RR, 1.7; 95% CI, 1.2 to 2.5)
to be at a significantly greater risk for the development of clinical
colonization or infection with CR A. baumannii strains. In accordance, a combined infection
control strategy was designed and implemented, including the
sequential closure of all ICUs for decontamination, strict compliance
with cross-transmission prevention protocols, and a program that
restricted the use of carbapenem. Subsequently, a sharp
reduction in the incidence rates of infection or
colonization with A. baumannii, whether resistant
or susceptible to carbapenems, was shown,
although an alarming dominance of the carbapenem-resistant
clones was shown at the end of the study.
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INTRODUCTION |
Initial concern about multiresistant,
carbapenem-resistant (CR) Acinetobacter
baumannii infections began when the first hospital-wide outbreak occurred in New York City in 1991 (31, 69). Since then, reports of CR A. baumannii have been
accumulating from other parts of the world, such as Argentina, Belgium,
Brazil, Cuba, England, France, Hong Kong, Kuwait, Singapore, and Spain
(3, 9, 10, 22, 53, 66). Currently, the spread of hospital populations of resistant microorganisms is of great concern worldwide, raising the idea that we may be approaching the postantimicrobial era
(2, 4, 16, 33, 52, 68). Although methicillin-resistant staphylococci and vancomycin-resistant enterococci have been the focus
of much of this attention to date (32, 39, 46, 48, 54, 78),
in recent years, emerging gram-negative organisms such as A. baumannii have provided the same challenge with regard to
multiple-antibiotic resistance (7, 8, 21, 38, 55, 72, 73).
In September 1992, an outbreak of infections due to multiresistant
A. baumannii began in the intensive care units
(ICUs) of our institution. Although infection control measures based on strict barrier precautions were instituted, A. baumannii spread throughout the hospital. Since then, more
than 1,400 patients have been colonized or infected, 60 to 70% of them
during an ICU stay. The incidence rates of new colonized or infected
patients ranged from 6.3 cases/100 ICU admissions in 1992 to 14 cases/100 ICU admissions in 1996. Currently, A. baumannii constitutes the most common cause of infection
among ICU patients. Numerous efforts were conducted in our institution
to investigate the epidemiology of the outbreak (5, 18, 20).
Results indicated that colonized patients and environmental
contamination might act as the major epidemiological reservoirs for
infection. Inadequate prevention of cross-transmission is the main
determinant for A. baumannii persistence. Control
measures were repeatedly reinforced during this time, but only a
transitory decrease in the incidence of A. baumannii
infection or colonization was observed following each reinforcement.
From 1992 to 1996, annual susceptibility summaries showed that all
A. baumannii epidemic or endemic isolates were
resistant to two or more antibiotic groups, which uniformly included
-lactams and gentamicin, and were susceptible only to
carbapenems, sulbactam, and colistin. However, on the basis
of the variable susceptibilities to tobramycin, amikacin,
ciprofloxacin, and tetracycline, three major antibiotic susceptibility
patterns among the A. baumannii population could be
defined. Continued surveillance of A. baumannii isolates by molecular typing procedures showed three main clonal types
that corresponded to the three major antibiotic susceptibility patterns
detected during the outbreak: clone A, 71%; clone B, 7%; clone C,
14%; and sporadic clones, 8% (M. A. Dominguez, J. Ayats, C. Ardanuy, X. Corbella, J. Liñares, and R. Martin, Abstr. 38th
Intersci. Conf. Antimicrob. Agents Chemother., abstr. K-124, 1998).
During this time, although yearly total antibiotic consumption decreased following a vigorous antibiotic use policy (from 60 daily
definite doses [DDDs]/100 ICU hospitalization days in 1992 to 49.9 DDDs/100 ICU hospitalization days in 1996), the inability to control
the outbreak indicated that the use of imipenem, the only recognized
antibiotic alternative for treatment of infections, remained high, from
12.8 (21.3%) to 13.2 (26.5%) DDDs/100 ICU hospitalization days.
On January 4, 1997, a 75-year-old man who was admitted to our hospital
with extensive cerebral infarction developed aspirate pneumonia
requiring mechanical ventilation and ICU admission. Imipenem at 500 mg
every 6 h was started, but the pneumonia progressed after 9 days
of treatment. Respiratory specimens obtained by fiberoptic bronchoscopy
with a protected specimen brush yielded A. baumannii with intermediate resistance to imipenem (MIC, 8 mg/liter). On day 12, the imipenem dosage was increased to 1 g every 6 h, but the
patient died 24 h later. After that time, carbapenem
resistance among A. baumannii isolates rapidly
spread throughout the ICUs, prompting us to conduct a prospective investigation.
The emergence and spread of carbapenem resistance were
managed from a combined laboratory-epidemiology point of view. Our aims
were to identify the complexity of factors contributing to the clinical
and microbiological epidemiology of such infections and to determine
the effectiveness of a combination of infection control strategies.
(The work was presented in part at the 38th Interscience Conference on
Antimicrobial Agents and Chemotherapy, 24 to 27 September 1998, San
Diego, Calif.).
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MATERIALS AND METHODS |
Study design.
(i) Setting. The Hospital de
Bellvitge is a 1,000-bed tertiary-care teaching hospital for adults in
Barcelona, Spain. It provides acute medical and surgical care to a
population of 1.5 million persons, excluding pediatrics, obstetrics,
and burns, with about 26,000 patient admissions per year. It has four
ICUs, with a total of 46 beds and about 1,200 patient admissions per year. One nurse cares for each two ICU patients; transplant recipients, however, are managed by only one nurse. Selective digestive
decontamination is not applied to patients.
(ii) Objectives. The objectives of the study were (i) to
identify risk factors for the development of clinical colonization or
infection due to CR A. baumannii, (ii) to
characterize molecularly the organisms and clones involved, and (iii)
to evaluate the efficacy of a multicomponent intervention program.
(iii) Design. The study was an 18-month prospective
longitudinal intervention investigation and was centered in the
ICUs.
From January 1997 to June 1998, all ICU patients harboring
A. baumannii in clinical samples entered into a specially
designed
computer-assisted protocol. During the first 6-month period
before
intervention (January to June 1997), potential risk factors for
the development of CR
A. baumannii-positive clinical
samples were
identified by comparing demographic, clinical, and
epidemiological
data between CR
A. baumannii-positive and carbapenem-susceptible
(CS)
A. baumannii-positive groups. Since we had
observed that
the previous carriage of
A. baumannii
at different body sites,
such as the digestive tract, was a major
attribute for the subsequent
development of
A. baumannii-positive clinical samples in our ICU
setting
(
5,
18), rectal swab specimens were prospectively
obtained
upon ICU admission and weekly thereafter until ICU discharge
or death
for screening of
A. baumannii carriers during this
first
6-month study period. According to the risk factors identified,
a
combination of infection control measures was carefully designed
and
implemented in the ICUs in July 1997. The response to the
intervention
was evaluated during the subsequent 12-month period
(July 1997 to June
1998) by comparing the incidence rates of new
A. baumannii cases of the pre- and postintervention study
periods.
Definitions.
CR A. baumannii-positive and
CS A. baumannii-positive patients were defined as
those patients admitted to the ICUs from whom at least one clinical
sample recovered during the ICU stay contained CR or CS A. baumannii (rectal swab specimens were not considered clinical samples). Clinical episodes of colonization or infection were
considered acquired in the ICU if they appeared 72 h after ICU
admission. Standard Centers for Disease Control and Prevention (CDC)
criteria were carefully used to define nosocomial infections (28).
Chronic health status was classified into three groups according to the
McCabe classification: group 1 includes chronic or
curable disease,
group 2 includes malignancy or any other disease
that results in a life
expectancy of less than 5 years, and group
3 includes diseases that
result in a life expectancy of less than
1 year (
44). The
severity of illness was calculated by means
of evaluation of the
Simplified Acute Physiologic Score (SAPS)
measured at ICU admission
(
40). SAPS is a validated severity-of-disease
scoring system
that uses age and 13 physiological parameters to
generate a score from
0 to 56 by increasing severity of
illness.
Immunosuppressed patients included those with nonneoplastic
immunosuppressive diseases or those who had used glucocorticoids,
cyclosporine, cyclophosphamide, methotrexate, or azathioprine
in the 2 weeks prior to the first episode of clinical colonization
or infection
due to
A. baumannii. A urinary catheter,
intravascular
catheterization, parenteral alimentation, mechanical
ventilation
or tracheostomy, and antibiotic therapy were considered if
they
had been in use for more than 48 h from ICU admission to the
day
of the ICU stay that
A. baumannii was detected
in clinical samples.
The term "previous CR
A. baumannii carriage" was defined as the
presence of CR
A. baumannii in one or more fecal samples, before
the detection of the first
A. baumannii clinical
isolate (either
CR or CS
A. baumannii). The
term "concentration of CR
A. baumannii-positive
patients" was defined as the mean number of patients per day who
were
known to harbor CR
A. baumannii and who were
admitted to
the same ICU ward during the week before the patient
developed
the first
A. baumannii clinical
colonization or
infection.
Infection control intervention.
Multicomponent intervention
included the sequential closure of all ICUs for extensive
decontamination; partial structural redesign of the units with
placement of hand-washing facilities within the rooms; continued ICU
personnel educational programs; rigorous open surveillance of adequate
compliance with barrier precautions, cleaning protocols, and
housekeeping procedures; and restriction of carbapenem use.
Adequate compliance with the control program was supervised by two
specially designated members of the infection control team (one
physician and one nurse), who attended to the ICUs daily after the
implementation of the intervention program in July 1997. Furthermore,
since the ability of A. baumannii to survive in the
hospital environment is well known (77), an environmental
survey was conducted on the basis of the weekly performance of
environmental sampling. A previously reported modification of the swab
technique, which involved the use of sterile gauze rather than cotton
applicator swabs, was used (20). The focus was on those ICU
items that should have been free of contamination under adequate
compliance with cleaning procedures and barrier precautions. During the
12-month postintervention study periods, continuous feedback
information that comprised data on outbreak evolution, environmental
contamination, and carbapenem consumption was provided.
During carbapenem restriction use, a
"fourth-generation" cephalosporin (cefepime) or an
antipseudomonas penicillin plus a
-lactamase inhibitor
(piperacillin-tazobactam), preferably in
combination with an
aminoglycoside, was recommended as a broad-spectrum
empirical regimen
for ICU patients. On the basis of both susceptibility
tests and
previous published experiences (
34-36), 1 to 2 g of
intravenous
sulbactam alone every 6 to 8 h (
19), with
or without tobramycin,
or polymyxin E (colistimethate) administered at
recommended doses
(
12,
37,
74,
80), either parenterally,
intrathecally,
topically, or aerosolized, was used as an alternative to
imipenem
against
A. baumannii strains, when
indicated.
Microbiology procedures.
A. baumannii
isolates were identified by the microbiology laboratory by using
standard biochemical reactions (24) and its ability to grow
at 37, 41, and 44°C. Confirmation of the identification as A. baumannii (either CS or CR A. baumannii) was verified by restriction analysis of the
16S-23S ribosomal genes and the intergenic spacer sequence
(27) from representative isolates.
The antibiotic susceptibility of
A. baumannii was
determined by the microdilution method (MicroScan; NegCombo Type 6I
plates;
Dade International Inc., West Sacramento, Calif.).
Susceptibility
to the following antibiotics was determined: ampicillin,
ticarcillin,
piperacillin, ceftazidime, cefepime, imipenem, meropenem,
gentamicin,
tobramycin, amikacin, ciprofloxacin, and tetracycline.
Imipenem
resistance was confirmed by the E-test (AB Biodisk, Solna,
Sweden)
and the agar dilution method. Results were interpreted
according
to National Committee for Clinical Laboratory Standards
(NCCLS)
criteria (
51). Susceptibilities to sulbactam and
colistin were
tested by the disk diffusion method with use of
10/10-µg ampicillin-sulbactam
disks and 10-µg colistin disks
(Becton Dickinson, Sparks, Md.),
and isolates were considered
susceptible if the inhibition zones
were
15 and
11 mm,
respectively. Sulbactam and colistin MICs
were studied by the agar
dilution method (
50) with Mueller-Hinton
agar (Oxoid,
Basingstoke, United Kingdom). The breakpoints for
sulbactam were those
of NCCLS for ampicillin-sulbactam (
51).
Breakpoints for
colistin were those defined by the French Society
for Microbiology
(
1,
65); thus, isolates were considered
susceptible to
colistin if the MIC was
2 mg/liter.
Since all multiresistant
A. baumannii strains,
either CR or CS
A. baumannii strains, isolated from
clinical specimens during
the outbreak were uniformly found to be
gentamicin resistant,
this antibiotic was selected for the screening of
rectal and environmental
specimens. Rectal swabs and environmental
cultures were sampled
on MacConkey agar plates (supplemented with 6 µg of gentamicin
per ml) and 5% sheep blood agar plates. The plates
were incubated
at 37°C for 48
h.
Molecular typing studies.
Genotyping was performed by the
repetitive extragenic palindromic PCR (REP-PCR) and by pulsed-field gel
electrophoresis (PFGE). For the present study we selected 77 CR
A. baumannii strains isolated in 1997 from 45 patients. Sixty-one CR A. baumannii isolates were selected from 29 consecutive patients colonized or infected during the
first 6-month period before the intervention (January to June 1997); of
those isolates, 16 CR A. baumannii strains, were
isolated from rectal swabs and 45 were isolated from clinical specimens (respiratory tract, n = 17; blood, n = 7; urine, n = 7; catheter sites, n = 5;
and other, n = 9). The remaining 16 clinical strains (respiratory tract, n = 6; blood, n = 2; wound, n = 2; and other, n = 6)
belonged to 16 CR A. baumannii-colonized or
-infected patients selected at random during the second 6-month period
following the intervention (July to December 1997). In addition, five
environmental CR A. baumannii strains isolated from
ICU items were available for genotyping.
REP-PCR was performed with the primers and under the conditions
described elsewhere (
71). For PFGE, DNA extraction and
purification
were carried out as described previously (
43,
61). For this
analysis, two low-frequency restriction enzymes,
SmaI and
ApaI,
were used separately, following
the manufacturer's specifications
(New England BioLabs, Beverly,
Mass.). DNA restriction fragments
were separated in a CHEF-DR III unit
(Bio-Rad, Hercules, Calif.)
for 20 h at 200 V, with pulse times
ranging from 1 to 30 s when
SmaI was used for
restriction and from 0.5 to 15 s when
ApaI was
used for
restriction.
Statistical analysis.
Potential risk factors were compared
between the CR and CS A. baumannii groups by
chi-square, Fisher's exact, or Student's t test, when
appropriate. For the purpose of statistical analysis, all those
patients who harbored both CR and CS A. baumannii
during their ICU stay were considered to be two patients. All variables with a two-tailed P value of 0.05 in the univariate
analysis were considered statistically significant and were included in logistic regression modeling. Multivariate analysis was done by logistic regression, with significant variables selected by a backward
stepwise procedure. To identify differences in the evolution of the
outbreak before and after the interventions, the study was divided in
three 6-month periods: period 1, preintervention (January to June
1997); period 2, early postintervention (July to December 1997); and
period 3, late postintervention (January to June 1998). Temporal trends
in incidence rates were evaluated before and after interventions by
comparing the mean numbers of new CR- or CS-A.
baumannii-colonized or -infected patients per 100 ICU
admissions among periods 1, 2, and 3 by using the Kruskal-Wallis one-way analysis of variance and the Mann-Whitney U Wilcoxon Rank Sum W
test. The impact of restricted use of carbapenem on the carbapenem resistance trend among periods was analyzed by
using linear trend analysis with proportions. Statistical analysis was performed by using the SPSS/PC (Microsoft Corp., Redmond, Wash.) and
the BMDP (BMDP Statistical Software, Cork, Ireland) statistical packages, and EPI Info software (version 6.04a; CDC, Atlanta, Ga.).
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RESULTS |
Risk factors for clinical colonization or infection due to CR
A. baumannii.
From January to June 1997, 106 (15.7%) of the 676 consecutive patients admitted to the ICUs developed
clinical colonization or infection due to multiresistant A. baumannii: 22 (20.7%) due to CR A. baumannii, 67 (63.3%) due to CS A. baumannii, and 17 (16%) due to both CR and CS A. baumannii (Fig. 1). Risk
factors were compared between the 39 CR A. baumannii-infected or -colonized patients and the 84 CS
A. baumannii-infected or -colonized patients (Table
1), with no differences in terms of sex,
underlying diseases, severity of illness at admission, type of ICU
ward, mean number of days in an ICU prior to colonization or infection,
and prior number of days with invasive devices or antibiotics being
found. In contrast, patients infected or colonized with CR A. baumannii isolates were younger than those infected or
colonized with CS A. baumannii isolates and belonged
to group 1 of the McCabe classification (chronic or curable diseases)
in a significantly greater proportion. Moreover, a higher proportion of
CR A. baumannii-infected or -colonized patients had
undergone major digestive surgery, had received parenteral nutrition or
prior therapy with carbapenems, had been admitted into a
ward with a high density of CR A. baumannii-infected
or -colonized patients, and were more frequently previous fecal
carriers of CR A. baumannii. Results of the logistic
regression analysis are shown in Table 2
and identified the previous state of CR A. baumannii
carriage, the previous use of imipenem, and the presence of a higher
concentration of CR A. baumannii-infected or
-colonized patients in the same ICU ward to be the independent risk
factors for the development of clinical colonization or infection due to CR A. baumannii.
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FIG. 1.
Temporal trends in incidence of new patients colonized
or infected with CR A. baumannii (CR-Ab) and CS
A. baumannii (CS-Ab) and carbapenem
consumption from January 1997 to June 1998.
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TABLE 1.
Potential risk factors for ICU patients with clinical
colonization or infection with CR A. baumannii
compared with those for ICU patients with clinical colonization or
infection with CS A. baumanniia
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TABLE 2.
Multivariate relative risks for potential variables
independently associated with infection or colonization with a CR
strain
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Over the entire 18-month study period, 262 (14%) of a total of 1,836 consecutive patients admitted to our ICUs had clinical
samples positive
for multiresistant
A. baumannii: 109 (42%) due
to
CS
A. baumannii, 102 (39%) due to CR
A. baumannii, and 51 (19%)
due to both CS and CR
A. baumannii (Fig.
1). Of the total of 153
patients from whom
clinical samples harbored CR
A. baumannii,
90 (59%)
met the CDC criteria for infection and 63 (41%) met the
CDC criteria
for clinical colonization; similarly, 99 (62%) of
160 CS
A. baumannii-infected or -colonized patients met the CDC
criteria for infection. A comparison of the characteristics of
patients
with CR and CS
A. baumannii infections revealed no
statistical
differences between the groups in terms of sex, age,
severity
of disease, chronic health status, or prevalence and type of
underlying
diseases. The clinical characteristics of patients with
infections
and the mortality rates are shown in Table
3 and do not reveal
major differences
when patients infected or colonized with CR
A. baumannii are compared with those infected or colonized
with
CS
A. baumannii. Intubation-associated
respiratory tract infections,
catheter-related bacteremia, and surgical
wound infections were
the most common infections found among members of
both groups.
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TABLE 3.
Characteristics of ICU patients with infection due to
CR A. baumannii compared with those with
infection due to CS A. baumanniia
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Microbiology results.
Restriction analysis of the 16S-23S
ribosomal operon was performed with representative strains of the CS
and CR A. baumannii genotypes found during this
study. This analysis confirmed the biochemical results and identified
all the strains as belonging to DNA group 2, named A. baumannii. Results of the antibiotic susceptibility tests
for the A. baumannii strains isolated during the
study period are summarized in Table 4.
The antibiotic susceptibility patterns among the CS A. baumannii isolates (susceptible only to
carbapenems, sulbactam, and colistin) were consistent with those obtained by PFGE in previous studies (5, 18) and
pertained to clone A, the major CS A. baumannii
clone isolated during the outbreak. Among CR A. baumannii isolates, we found two antibiotic susceptibility
patterns that corresponded to two new A. baumannii genotypes by REP-PCR and PFGE (named D and E). Clone D was susceptible to sulbactam (MIC, 4 mg/liter) and colistin (MIC, 0.5 to 1 mg/liter) and was intermediate to tobramycin (MIC, 8 mg/liter) and imipenem (MIC,
8 mg/liter). Imipenem MICs were confirmed both by the E-test and the
agar dilution method to avoid false imipenem resistance due to
degradation of the drug during storage of the MicroScan panels. Clone E
was only susceptible to colistin (MIC, 0.5 to 1 mg/liter),
intermediate or highly resistant to tobramycin (MIC, 8 to >128
mg/liter), and highly resistant to imipenem (MIC, >32 mg/liter).
Neither clone D nor clone E seemed to be related to previous clones
isolated during the outbreak (Fig. 2).
The results obtained by PFGE reaffirmed those obtained by REP-PCR
analysis, which also identified two new clones among the CR A. baumannii strains (Fig. 3).
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FIG. 2.
Patterns obtained by PFGE for A. baumannii after digestion with SmaI. Lanes 1 to
4, CS isolates belonging to clone A (lane 1), clone B (lanes 2 and 3),
and clone C (lane 4); lanes 5 to 12, CR isolates belonging to clone D
(lanes 5 to 10) and clone E (lanes 11 and 12); lanes mm, molecular size
marker.
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FIG. 3.
Repetitive PCR patterns for A. baumannii. Lanes 1 and 2, CS isolates of clone A; lanes 3 and 4, other CS sporadic clones previously isolated during the endemic;
lanes 5 to 10, CR isolates of clone D (lanes 7 and 8) and clone E
(lanes 5, 6, 9, and 10); lane mm, 100-bp molecular size marker.
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Genotyping of CR
A. baumannii isolates from patients
colonized or infected during the first 6 months before intervention
(January
to June 1997) showed a dominance of clone D over clone E: 25 of
the 29 patients studied harbored clone D, while the remaining
4 patients harbored clone E. Identical genotypes were found for
paired
isolates (fecal swabs and clinical samples) from the 16
patients from
whom both isolates were available. Among the 16
CR
A. baumannii-colonized or -infected patients selected at
random
during the second period following intervention, clone D was
found
in 4 patients and clone E was found in 12
patients.
In view of the molecular typing results, the first CR
A. baumannii isolate noted to have occurred in January 1997 was a clone
D isolate. The first clone E strain was noted to have
occurred
in May 1997 and was isolated from the urinary tract of a
45-year-old
polytraumatic man who had been transferred to our ICU from
a hospital
in Madrid, where he had been colonized with CR
A. baumannii strain
with susceptibility pattern identical to
that of the clone E
strain.
From January 1997 to June 1998, a total of 1,164 cultures of
environmental samples were performed, showing a significant decrease
in
the rates of contamination with either CS or CR
A. baumannii after the intervention (Fig.
4). Five of the environmental isolates
studied were clone D and clone E isolates (two and three isolates,
respectively). These CR
A. baumannii strains had the
same antibiotypes
described for the clinical isolates. On the basis of
antibiotic
susceptibility, CR
A. baumannii
environmental isolates had the
same clonal distribution throughout the
study period as that documented
for clinical samples containing CR
A. baumannii strains.
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FIG. 4.
Temporal trends in environmental contamination with
A. baumannii clones before and after
interventions.
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Response to infection control intervention program.
The
incidence rate of new patients with clinical samples positive for CR
A. baumannii reached its peak in July 1997, with 18 new CR A. baumannii-positive patients per 100 ICU
admissions (Fig. 1). This represented a prevalence of 20 new CR
A. baumannii-positive patients, or 60% of all those
ICU patients with new clinical isolates that were multiresistant
A. baumannii. The implementation of the multicomponent intervention in late July l997 resulted in a sharp reduction in the incidence rate of new A. baumannii
infection or colonization, either CR or CS A. baumannii, from 30.6 cases per 100 ICU admissions in that
month to 6.3 cases per 100 ICU admissions in December 1997. The
incidence rates then remained at a constant, moderate level until the
end of the study. The comparison of the mean incidence rates among
periods 1, 2, and 3 is shown in Table 5
and indicates a relevant reduction between periods 1 and 3 that reached
statistical significance.
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TABLE 5.
Temporal trends in incidence of new ICU patients
colonized or infected with CR and CS A. baumannii
strains: differences before and after
interventionsa
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The mean level of monthly carbapenem consumption was
reduced 85% between the periods before (period 1) and early after
implementation
of restricted use of carbapenem (period 2),
from 11.6 to 1.8 DDDs/100
ICU hospitalization days (Fig.
1). Afterward,
low levels of monthly
carbapenem consumption were
maintained until the end of the study
(period 3). Subsequently, the
progressive dominance of CR
A. baumannii in relation
to CS
A. baumannii was observed before the
intervention
was stopped (Fig.
5).
Comparison of periods 1 and 2 and periods
1 and 3 showed differences
that reached statistical significance.
Of great concern was the fact
that although the rates of CR and
CS
A. baumannii
infection and colonization were similar for periods
2 and 3 (linear
trend analysis between periods 2 and 3 showed
nonsignificant
differences), molecular typing of the CR
A. baumannii isolates revealed an alarming dominance of clone
E at the end
of the study.
View larger version (68K):
[in this window]
[in a new window]
|
FIG. 5.
Temporal trends in clonal spread of
carbapenem resistance among A. baumannii isolates by using molecular characterization of
epidemic and endemic clones. Differences before and after the
interventions were analyzed by comparing CR A. baumannii (clones D and E) and CS A. baumannii (clone A) groups for periods 1, 2, and 3 by
using linear trend analysis with proportions. Six levels of exposition
were selected per each period; these corresponded to months 1 to 6 for
each period compared. Differences reached significant differences when
periods 1 and 2 were compared (chi-square for linear trend, 6.14;
P = 0.013) and periods 1 and 3 were compared
(chi-square, 5.38; P = 0.02) but not when periods 2 and
3 were compared (chi-square, 1.13; P = 0.28).
|
|
| |
DISCUSSION |
Over the past two decades, the ability to control multiresistant
A. baumannii epidemic infections has differed widely
from one hospital to another, probably depending on several
epidemiological factors (6, 11, 13, 17, 26, 30, 49, 57, 60, 63,
70, 76). In some institutions, in which epidemic infections were
circumscribed to a sole ICU ward, a common contaminated object in the
environment could usually be identified as the source of infection. In
these cases, the implementation of isolation precautions and
modification of cleaning procedures resulted in the prompt eradication
of the outbreak. In contrast, in other hospitals, epidemic infections
have become endemic, and the clinical and microbiological
epidemiologies of these infections remain obscure.
It is of great concern that when directives regarding effective
infection control measures for large and sustained outbreaks due to
multiresistant A. baumannii were still not well
defined, resistance involved carbapenems in our outbreak
setting. Although resistance emerged after considerable pressure from
imipenem use, a molecular typing approach showed that this was not due
to the acquisition of resistance mechanisms by the clones responsible for the outbreak but, rather, was due to the sequential introduction of
two new clones. After detection of the first CR A. baumannii infection, a dramatic increase in the incidence
rate of new ICU patients infected or colonized with
carbapenem-resistant isolates was observed. CR A. baumannii strains initially showed intermediate resistance
to imipenem (clone D), but afterward a new, different clone (clone E)
highly resistant to all commercially available antibiotics except
polymyxins appeared and became dominant.
The risk factors associated with the development of A. baumannii infections have raised controversy. In most
studies, the risk factors identified were in accordance with those
associated with other nosocomial infections, such as the severity of
illness, the prior use of antibiotics, or the previous number of days
with invasive devices in place (41, 47, 75). However, when
prospective screening for colonized patients was done by body site, we
previously observed that a large proportion of ICU patients became
secondarily colonized with A. baumannii at different
body sites, similar to that which occurs in patients infected or
colonized with other nosocomial pathogens (64). This
previous state of A. baumannii carriage was a major
attribute for the subsequent development of A. baumannii infections (18, 20). Under special
epidemiological circumstances such as those noted in our ICUs, the
inadequate prevention of cross-transmission determined that A. baumannii carriage occurred very early during ICU
admission. In the present study our aim was not to again identify
potential attributes for A. baumannii colonization
of body sites for our ICU population but, rather, those risk factors
particularly associated with the development of clinical episodes of CR
A. baumannii colonization or infection among those
patients harboring clinical A. baumannii isolates.
The logistic regression analysis selected the previous state of CR
A. baumannii carriage and the presence of a larger proportion of CR A. baumannii-infected or -colonized
patients in the same ICU ward as statistically significant risk factors with regard to other classical risk factors for nosocomial infections, such as the severity of illness or the previous number of days an
invasive device was in place. These results reaffirmed some of our
previous observations regarding the epidemiology of A. baumannii and demonstrate the important role of horizontal
transmission in the acquisition of A. baumannii
organisms (either CR or CS strains). In such circumstances, exposure to
carbapenems may provide a selective advantage for CR
A. baumannii colonizing clones competing with CS
A. baumannii clones.
Before the emergence of CR A. baumannii, the
outbreak was never under control, although measures including strict
attention to cleaning procedures and barrier precautions were
repeatedly implemented. The urgent need for control of the outbreak
increased definitively when our ability to treat A. baumannii infections became severely threatened by the
spread of carbapenem resistance. With the risk factors
mentioned above kept in mind, this spread was attacked by a complex
combination of procedures that did not include the topical
administration of antibiotics for decontamination of patients. Although
selective intestinal decontamination might be considered a reasonable
additional measure for control (58), in view of the high
rates of fecal carriage observed in A. baumannii outbreaks (18, 67), in our ICU setting, several
arguments discouraged us from using it during the study. These reasons
were the possible exogenous route of the origin of such infections, either from the inanimate environment or from other concomitantly colonized body sites such as the skin, and the extremely
narrow range of therapeutic options for our A. baumannii-infected patient population.
Multiple-antibiotic resistance casts doubt on the real
efficacy of digestive decontamination, since many strains were
highly resistant to aminoglycosides (a family of antibiotics usually
included in decontamination schedules, along with polymyxins). Taking all these factors into account, we believed that there was a
true risk not only of failure from the use of monotherapy but also of
the emergence of more resistant A. baumannii strains.
It is difficult to state whether the subsequent decrease in incidence
rates was the consequence of interventions in
Acinetobacter epidemics, since several confounding
factors such as seasonality are known to influence incidence rates
(56). In our case, the trend was slowed down and,
thereafter, was dramatically reversed during the late summer months,
the season in which Acinetobacter epidemics tend to rise
worldwide. Determination of the relative role of the different
interventions applied is problematic, because they concurred in time
and probably interacted with one another. However, we believe that the
fact that the proportions of A. baumannii isolates
were reduced similarly among the CR and CS A. baumannii groups (both clinical and environmental)
strongly reinforces the roles of adequate compliance with hand-washing
procedures, the use of barrier precautions, and cleaning procedures in
controlling A. baumannii outbreaks. On the other
hand, restriction of carbapenem use appeared to be useful
in delaying the progressive increase in the incidence of CR A. baumannii infections or colonizations in relation to the
incidence of CS A. baumannii infections or colonizations, although carbapenem resistance did not
revert to susceptibility after 1 year of restricted use.
Multiresistant, carbapenem-resistant A. baumannii outbreaks are now gradually posing a
threat to the hospitalized populations in some public tertiary-care
hospitals (14, 15, 31, 42, 59, 66). However, only very few
of these outbreaks, such as that described by Go et al.
(31), were managed from a combined clinical-microbiological
point of view (23, 45). In contrast to our results, those
investigators achieved not only a progressive decrease in the A. baumannii incidence rates but also a complete reversion of
carbapenem resistance. It is difficult to assess the extent
to which this different response may be due in part to the fact that in
the outbreak reported by Go et al. (31) imipenem resistance
developed from A. baumannii strains belonging to the
previous clones responsible for the endemic, while in our case, the
carbapenem resistance was due to the acquisition of two new
epidemic clones (clones D and E).
Similar to other multiresistant populations, for A. baumannii organisms it is difficult to separate resistance
from their clinical behavior (29). Prior to the spread of CR
A. baumannii, the clinical virulence of CS
A. baumannii had not been well defined, although it
was noted to be almost uniformly associated with high crude mortality
rates (about 40 to 50%) (6, 14, 25, 62). However, the facts
that the isolation of A. baumannii from clinical specimens may often reflect colonization rather than significant infection, that most isolates occur in severely ill ICU patients with
several underlying diseases, that a large proportion of infections are
polymicrobial, and that most infections are usually associated with
multiple invasive procedures make controlled investigations extremely
difficult. Therefore, in the immediate future, only clinical judgment
in the selection of the sort of patients who really need antibiotics
and animal models may provide an appropriate basis to assess the role
of CR A. baumannii in such infections and of
antibiotic alternatives in modifying the final outcomes for
patients (79).
This study has provided evidence that the fateful trend toward
antibiotic resistance in A. baumannii may finally
include carbapenems, the last recognized antibiotic
alternative for most strains isolated worldwide, during large and
sustained hospital outbreaks. Management of these emerging organisms is
complex and requires a combination of molecular typing techniques and
epidemiological studies. High-level and extended environmental
contamination, close contact between colonized patients and health care
workers, and widespread imipenem use were the main determinant factors
that promoted rapid clonal dissemination of CR A. baumannii throughout the hospital. Restriction of
carbapenem use and, probably more importantly, strict
compliance with basic infection control measures may have a strong
impact on controlling A. baumannii outbreaks,
although carbapenem resistance may not be eliminated. In
summary, to confront the imminent threat of untreatable A. baumannii infections, physicians should sharpen their good
clinical judgment when making antibiotic treatment decisions and should
strongly ensure strict compliance with basic control measures for the
containment of infection. Although controversial, other potential
measures, such as the use of selective decontamination programs that
prevent patient carriage, may be considered in addition to basic
infection control strategies when the "traditional" approach fails
to control an outbreak.
| |
ACKNOWLEDGMENTS |
We are indebted to the doctors and nurses from the Intensive Care
Medicine Service (Hospital de Bellvitge) who provided care for the
patients included in the study, Rafael Abós from the Unitat Clínico-Epidemiològica (Hospital de Bellvitge) for assistance with
statistical analysis, Mercedes Sora from the Pharmacy Department (Hospital de Bellvitge) for providing antibiotic consumption data, Isabel García-Arata from the Microbiology Laboratory (Hospital Ramon
y Cajal, Madrid, Spain) for ribotype analysis, and Amaya Virós for
helpful advice in manuscript preparation.
The study was supported by the Fondo de Investigaciones Sanitarias de
la Seguridad Social (grants 96-0674 and 98-0525) from the National
Health Service of Spain.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Infectious
Diseases Service, Hospital de Bellvitge, Feixa Llarga s/n, 08907 L'Hospitalet de Llobregat, Barcelona, Spain. Phone: 34-93-2607625. Fax: 34-93-2607637. E-mail: xcorbella{at}csub.scs.es.
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Journal of Clinical Microbiology, November 2000, p. 4086-4095, Vol. 38, No. 11
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Abstract
Introduction
