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ABSTRACT |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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In order to investigate the role of bacteria, including Mycoplasma pneumoniae and especially Chlamydia pneumoniae in acute purulent exacerbations of chronic obstructive pulmonary disease (COPD),
we examined sputum specimens and acute and convalescent sera taken 26 d apart from 49 outpatients experiencing an acute purulent exacerbation of COPD. The sera were tested for antibodies to
C. pneumoniae with the microimmunofluorescence test, and for antibodies to M. pneumoniae with
the indirect fluorescence antibody test. Routine microbiologic culture of sputum yielded potentially pathogenic microorganisms in 12 of the 49 patients (24%). Three patients (6%) showed serologic
evidence of recent M. pneumoniae infection. Seven patients showed high IgG titers of 
1:1,024 to
C. pneumoniae, and an additional four had a fourfold increase in IgG titer, suggesting reinfection with
C. pneumoniae. Sputum from two of these 11 patients also grew Streptococcus pneumoniae, and one
grew Moraxella catarrhalis. Patients with and without serologic evidence of current C. pneumoniae infection showed no significant differences in clinical features or pulmonary function. The high incidence of infection with C. pneumoniae (the sole causal agent in 16% of cases, and the causal agent
with other agents in 6%) provides insight into the importance of this organism among agents leading to exacerbations of COPD in Turkey.
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INTRODUCTION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Chronic obstructive pulmonary disease (COPD) is a lifelong disease with significant cost and morbidity. In patients with COPD, acute bacterial infections of the respiratory tree are common and have a negative impact on quality of life and on the progression of the disease, particularly in more severely affected patients (1, 2). However, causal infective agents may not be isolated from up to 50% of purulent sputum samples from these patients (3). Although Haemophilus influenzae, Streptococcus pneumoniae, and Moraxella catarrhalis are traditionally recognized as major pathogens (4), recent studies have considered the possibility that Chlamydia pneumoniae is also involved in some exacerbations of COPD (4 to 16%) in both nonhospitalized and hospitalized patients (5). Because C. pneumoniae may contribute to disease progression through its toxic effect on bronchial epithelial cells, with ciliostasis, it seems increasingly important to detect infection by this organism (8). This prompted us to conduct a prospective study to investigate the incidence of bacteria, including Mycoplasma pneumoniae, and especially C. pneumoniae, in acute purulent exacerbations of COPD in nonhospitalized patients attending the outpatient clinic at a university hospital in Turkey.
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METHODS |
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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Patient Selection
Inclusion criteria for the study were: (1) ambulatory status; (2) a history of COPD according to previously defined criteria (9); (3) an Anthonisen type-1 exacerbation (10); (4) purulent sputum, as defined by a Gram stain showing > 25 polymorphonuclear leukocytes and < 10 squamous epithelial cells per low-power field (lpf); and (5) written informed consent. Exclusion criteria were: (1) hospitalized status; (2) treatment with any antibiotic for 24 h or longer within 72 h before the baseline visit; (3) absence of an adequate sputum specimen as determined by Gram stain; (4) evidence of bronchiectasis and/or pneumonia; and (5) malignancy or severe immunosuppression. The first consecutive 49 patients who fully met these criteria, from among approximately 200 COPD patients attending the university hospital's clinics between November 1996 and September 1997, were included. After a thorough history and examination, including chest radiography, patients underwent baseline pulmonary function tests. Hematologic, microbiologic, and serologic investigations were done on the same day. Patients were treated with either oral ciprofloxacin, 500 mg twice daily, or oral trovafloxacin, 200 mg twice daily, for 10 d. All patients were reassessed clinically, hematologically, and bacteriologically at the end of treatment (Day 11) and at follow-up assessment (Day 26). According to clinical response on Day 11, eight patients additionally received oral amoxicillin, 500 mg thrice daily for 10 d. A further serum specimen for detection of Chlamydia species and antibodies to M. pneumoniae was collected on Day 26. Serologic and hematologic analyses, together with bacteriologic confirmation, were performed in the same reference laboratory in Switzerland. All patients who were enrolled in the study completed it.
Laboratory Investigations
Bacteriology. Sputum samples were plated on blood and chocolate agar and incubated at 37° C for both 24 and 48 h. All microorganisms isolated were identified through standard laboratory methods (11).
Serology. All sera were investigated for the presence of IgG, IgM,
and IgA antibodies to Chlamydia species (C. pneumoniae, C. trachomatis, and C. psittaci) with the microimmunofluorescence (MIF) test
(MRL Diagnostics, Cypress, CA; the source of C. pneumoniae antigen
was the English strain IOL-207). Serum antibodies against C. pneumoniae elementary bodies were detected with fluorescein-conjugated monoclonal goat antihuman Ig-subclass antibodies. Measurements of
IgA were made after absorption with human IgG inactivation reagent.
Seropositivity was defined as a titer of 1:64 for IgG and IgA, and of
1:20 for IgM for all Chlamydia species. An isolated IgM titer of 1:20 was considered to be evidence of primary C. pneumoniae infection. An IgG titer of 1:1,024 or a fourfold change in titer of IgG,
IgM, or IgA was considered to be an indicator of reinfection. An IgG
titer of 1:512 was regarded as suggestive of reinfection with C. pneumoniae. Past C. pneumoniae infection (chronic or preexisting antibody) was defined as an IgG titer of 1:64 to 1:256.
The presence of circulating IgG and IgM antibodies to M. pneumoniae was detected with an indirect fluorescence antibody (IFA) system (Zeus Scientific, Inc., Raritan, NJ). A fourfold change in titer
of IgG or IgM, or an isolated IgG titer of 1:256 or IgM titer of 1:16,
was considered evidence of recent infection.
Statistical Analyses
Statistical analyses were performed with the SPSS/PC + package, version 5.0.2 (SPSS Inc., Chicago, IL). For normally distributed data, analysis of variance (ANOVA) was used to compare group means; otherwise the Mann-Whitney U test was applied. Response to treatment was analyzed with the Pearson's chi-square test. Values are expressed as means ± SD, and a statistical significance level of 0.05 was used.
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RESULTS |
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INTRODUCTION
METHODS
RESULTS
DISCUSSION
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The clinical characteristics of the patients are summarized in Table 1.
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Bacteriologic Results
Potentially pathogenic microorganisms (PPMs), which are recognized as agents causing respiratory infections whether or not they belong to the oropharyngeal or gastrointestinal flora (12), were identified in 12 (24%) of the 49 patients. They consisted of S. pneumoniae (33.3% of PPMs), H. influenzae (33.3% of PPMs), Haemophilus parainfluenzae (8.4% of PPMs), and M. catarrhalis (25% of PPMs). Non-PPMs, which belong to the oropharyngeal or gastrointestinal flora not usually involved in respiratory infections in immunocompetent patients (12), were found in the remaining 37 (76%) patients (Table 2).
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Serologic Results
Antibodies to C. pneumoniae. Forty-one of the 49 patients
(83.7%) had specific IgG titers of 1:64. None of the patients developed IgM antibodies.
Twenty-eight (57%) patients who had specific IgG titers to
C. pneumoniae of 1:64 to 1:256 in paired sera were regarded as having had previous C. pneumoniae infection. Four patients
showed a fourfold seroconversion to C. pneumoniae infection
in the IgG antibody class, one of whom showed a simultaneous fourfold change in the IgA antibody class, indicating reinfection. IgG titers of 1:1,024 were found in seven patients.
Two patients had IgG titers of 1:512.
Twenty of the patients with past C. pneumoniae infection had a low IgA titer, and eight patients showed an increased IgA titer at presentation, with fluctuating high titers in paired sera in only one patient. Nine of the 11 patients with serologic features of reinfection had a simultaneously increased IgA titer at presentation, with fluctuating high titers in paired sera in seven of these patients. Patients who had no seroconversion to IgG also had no increase in IgA titers (Table 3).
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Antibodies to other Chlamydia species. Antibodies to C. trachomatis or C. psittaci were found in three patients at lower titers evidencing a cross-reaction.
Antibodies to M. pneumoniae. A fourfold increase in IgG
titer to M. pneumoniae was found in two patients, with an IgG
titer of 1:256 in one indicating recent M. pneumoniae infection (6%). None of these patients had antibodies to C. pneumoniae. Five patients showed an IgG titer of 1:128 to M. pneumoniae, suggesting previous infection.
Serologic Results in Patients According to Bacteriologic Culture Status
In this study, of the 12 patients whose sputum yielded PPMs, three (6%) were seropositive and nine (18%) were seronegative for C. pneumoniae. Of the 37 patients whose sputum failed to yield a PPM on culture, eight (16%) showed evidence of reinfection with C. pneumoniae, three (6%) had serologic levels consistent with recent M. pneumoniae infection, and the remaining 26 were negative for both C. pneumoniae and M. pneumoniae (Table 4).
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There was no statistically significant difference in lung function or leukocyte count of patients with and without evidence of C. pneumoniae infection (Table 5). There was also no statistically significant difference in duration of acute symptoms; fever; pulse rate; respiratory rate; severity of cough, dyspnea, wheezing; or increased sputum production according to etiologic agent (p > 0.05 in the two groups for all parameters applying the Mann-Whitney U test). All patients who were considered to represent failures of clinical treatment had serologic evidence of reinfection with C. pneumoniae (p < 0.001 applying Pearson's chi-square test).
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES
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This first prospective surveillance report of a serologic evaluation for C. pneumoniae infection in acute purulent exacerbations of ambulatory COPD in patients in Turkey has shown that 57% of patients had serologic evidence of past C. pneumoniae infection. This is comparable to the prevalence of C. pneumoniae infection found in healthy blood donors of similar age and sex of the same institution, in Izmir, Turkey (61%) (13), and indicates a prevalence of the organism no higher than in certain other European countries such as The Netherlands (14), Finland (15), and Italy (16). Acute C. pneumoniae infection was demonstrated in 11 (22%) cases. The absence of an increase in IgM suggests reinfection rather than primary infection. This finding supports the concept that C. pneumoniae is an increasingly frequent cause of exacerbations of severe COPD even in nonhospitalized patients. However, in three patients, C. pneumoniae was associated with other PPMs: S. pneumoniae in two patients and M. catarrhalis in another. The frequent occurrence of coinfection could be explained by C. pneumoniae inducing ciliostasis, which then predisposes to infection with other respiratory pathogens (6, 8). All of the 11 patients were treated with either ciprofloxacin or trovafloxacin for 10 d. In addition, five of the 11 patients received amoxicillin for 10 d after completion of the first therapy (Table 2).
An interesting feature of our study was that high IgA titers at presentation were found in the vast majority of patients considered to have had reinfection with C. pneumoniae. None of the patients who were seronegative for C. pneumoniae had increased IgA titers. Surprisingly, 78% of patients with high IgA titers had fluctuating rather than stable IgA titers in paired sera, which may be considered evidence of reinfection, in addition to high IgG titers (Table 3). However, persistence of stable, elevated titers of IgA has been previously suggested to be an appropriate marker of an active, recurrent, or chronic carrier state (15, 17, 18).
Past studies evaluating the role of C. pneumoniae in COPD have shown an incidence of infection with the organism of 4% and 16% in nonhospitalized and hospitalized patients, respectively (5, 7).
Although there was no statistically significant difference in the clinical characteristics of patients with C. pneumoniae infection and those without (Table 5), other authors have linked more severe COPD or pneumonia to higher geometric mean titers of IgG and IgA (6). We have found a similar severity of clinically apparent bronchospasm in approximately similar proportions of patients with C. pneumoniae, those with other infectious agents, and those remaining seronegative and culture negative, suggesting that the presence and severity of wheezing are not helpful in differentiating C. pneumoniae infections from others.
Information about the role of M. pneumoniae in patients with exacerbations of COPD is scarce. Our data showed that M. pneumoniae (6%) might have a role in this setting. This differs from reports in the recent literature, which failed to implicate this organism (5, 7).
The role of bacterial infection in COPD has been the subject of much debate. It is generally accepted that bacteria with or without copathogens are probably significant in producing exacerbations. The bacteria isolated in our study population were compatible with those isolated in other studies (4).
A diagnosis of acute C. pneumoniae infection is usually
based on serologic criteria that include the presence of IgM
antibodies and/or a fourfold rise in IgG antibody titers (19).
The frequent occurrence of C. pneumoniae-specific immunoglobulin in adults limits the value of IgG alone as a diagnostic
marker of acute infection. IgG titers of 1:512 may persist for
prolonged (> 1 yr) periods, and it has therefore been proposed that the arbitrary breakpoint of an IgG titer of 1:512
be replaced by a titer of 1:1,024 to indicate acute infection
(19, 20). We applied this revised level of 1:1,024 as indicative of reinfection to the paired sera in our study.
In summary, in a well-selected population with an acute purulent exacerbation of COPD, bacteria were cultured from 24% of patients and serologic studies showed M. pneumoniae infection in 6% and C. pneumoniae in 22%. Although we were unable to perform appropriate analyses to identify viral etiologic agents, it seems that C. pneumoniae is an important etiologic agent in exacerbations of COPD, being present in 16% of patients on its own and in 6% together with other infectious agents. We suggest that this finding be borne in mind when initiating antibiotic therapy. Studies addressing the isolation or demonstration of C. pneumoniae in the lung are likely to shed further light on the significance of acute infection and chronic carriage of this organism in COPD.
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Footnotes |
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Correspondence and requests for reprints should be addressed to Dr. Nesrin Mogulkoc, North West Lung Research Centre, Wythenshawe Hospital, Southmoor Road, Wythenshawe, Manchester M23 9LT, UK. E-mail: 100046.1102{at}compuserve.com
(Received in original form September 11, 1998 and in revised form January 19, 1999).
Acknowledgments: The authors thank all the subjects who participated in this study.
Supported by the Pfizer International Pharmaceutical Group Foundation.
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References |
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METHODS
RESULTS
DISCUSSION
REFERENCES
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