Community-acquired pneumonia (CAP) remains a significant cause of childhood deaths in developing countries.1 Moreover, it is a common cause of hospitalization world wide, which is an economic burden for the healthcare system.2 Use of antibiotics is the main strategy used to overcome children's morbidity and mortality in such circumstances.3 Mortality from CAP in children dramatically decreased in the United States when penicillin was introduced into daily practice in comparison with the pre-antibiotic era.4 In order to control the situation in developing countries, the World Health Organization (WHO) proposed standardized procedures to diagnose and treat children with CAP.5 In such an algorithm, it is recommended that penicillin G is given to children hospitalized with severe CAP.6 The rationale for such a choice in treating bacterial CAP is the presence of Streptococcus pneumoniae, which is the main target.7 Nevertheless, the use of combination therapy, by adding an antibiotic from another class to beta-lactams, has been advocated as a better option for treating pneumococcal severe CAP.8 In addition, different medical societies have recommended the empirical use of other beta-lactams besides penicillin G for treating children with severe CAP.9,10

In this context, we aimed to describe the evolution and outcome of the illness in children aged ≥2 months hospitalized with radiographically diagnosed CAP treated with intravenous aqueous penicillin G at the daily dose of 200,000 IU/kg.

This was a retrospective cohort of CAP cases treated in the university hospital, from October 2002 to October 2005. Based on the hospital admittance log book, the same researcher identified each child hospitalized with CAP. The inclusion criteria comprised children aged ≥2 months hospitalized with CAP treated intravenously with 200,000 IU/kg/day of aqueous penicillin G for at least 48 h and with readable chest x-ray results. The exclusion criteria were underlying debilitating conditions such as heart disease with hemodynamic repercussion, chronic lung disease except asthma, including chronic pulmonary infections, primary or secondary immunodeficiency, nosocomial pneumonia from another hospital or transfer to another hospital during penicillin G treatment.

A pediatric radiologist, a member of this research project team, read the chest x-ray findings blind to the clinical information. The final radiographic diagnosis of pneumonia was based on the presence of pulmonary infiltrate or pleural effusion on the chest x-ray taken on admission after considering the standardized interpretation previously published.11 Data on demographics, clinical history and physical examination on admission, treatment, daily evolution during the first 7 days of treatment and outcome were collected from the medical chart and recorded on a standardized form. For axillary temperature and respiratory rate (RR), the highest grade recorded on the medical chart was collected. Fever was defined as an axillary temperature >37.5°C,12 and tachypnea as RR ≥50 breaths/min in children aged 2–11 months and RR ≥40 breaths/min in children from ≥12 months.13 Nutritional evaluation was performed using the software Anthro, version 1.02 (CDC and WHO) and severe malnutrition was defined as a Z-score for weight-for-age index under −3.00 using the National Centre for Health Statistics (NCHS-USA) standard.14 CAP was classified as non-severe, severe or very severe according to WHO guidelines: patients with chest indrawing were classified as severe CAP and patients with somnolence, seizures, grunting when calm, nasal flaring, cyanosis, or inability to drink were classified as very severe CAP.13 CAP severity was assessed according to the British Thoracic Society (BTS) guidelines: RR >70 breaths/min for infants, RR >50 breaths/min for older children, difficulty in breathing, dehydration, or axillary temperature >39°C classified the case as severe CAP.10

The results are described by reporting the distribution. Categorical variables between different groups of patients were compared using χ2 or Fisher's exact test, as appropriate. Continuous variables were compared using Student t test or Mann–Whitney U test, as appropriate and the mean difference with the respective 95% confidence interval was calculated. The daily frequency of clinical findings was compared using McNemar test. The statistical tests were two tailed, with a significance level of 0.05. The statistical software SPSS (version 9.0) was used for analysis. The study was approved by the ethics committee.

A total of 456 children were examined. Exclusion was due to underlying chronic debilitating conditions (n = 86) or nosocomial pneumonia from another hospital (n = 16). Among the other 354 cases, pneumonia was radiographically confirmed in 154 (43.5%). The flow chart of the study is shown in Figure 1. None of the enrolled cases died. The study group comprised 154 patients who received 200,000 IU/kg/day of aqueous penicillin G divided into 4 daily doses. Besides the included patients, 27 patients aged < 2 months and 43 patients aged ≥ 2months receiving other antimicrobial agents were hospitalized with radiographically confirmed pneumonia in the study period.

Figure 1.

Flow chart of the study group enrollment for the community-acquired pneumonia retrospective longitudinal study in Salvador, Northeast Brazi. CAP, community-acquired pneumonia; CXR, chest x-ray.

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The median age (months) was 24 months (mean 32±25 months, range 68 days–11.5 years) and 38 (24.7%) patients were younger than 1 year. There were 92 (59.7%) males. According to WHO criteria, severe and very severe CAP was present in 46 (29.9%) and 19 (12.3%) cases, respectively. The frequency of the severity criteria items was: chest indrawing (29.9%), nasal flaring (9.1%), grunting (3.9%), somnolence (1.3%), seizure (0.6%), cyanosis (0.6%). Nobody was unable to drink. According to BTS criteria, severe CAP occurred in 107 (69.5%) patients and the frequency of the additional items was: RR >70 breaths/min for infants (21.1%), RR >50 breaths/min for older children (38.3%), difficulty breathing (48.1%), axillary temperature >39°C (9.2%). On admission, the most common complaints were cough (99.2%), fever (97.2%), difficulty in breathing (56.5%), and findings were tachypnea (75.2%), fever (49.7%) and crackles (33.8%). Severe malnutrition was diagnosed in 6 (3.9%) cases. Pulmonary infiltrate and pleural effusion were detected in 123 (80.0%) and 40 (26.0%) cases, respectively; pulmonary infiltrate was categorized as alveolar (95.1%), interstitial (1.6%) or alveolar–interstitial (3.3%); other radiographic findings were peri-bronchial thickening (5.8%) and atelectasis (4.5%). There was no abscess, hyperinflation, pneumothorax, or pneumatocele.

Overall, the duration of hospitalization (days), median (25th–75th percentile) and mean ± standard deviation, were 8 (5–11) and 9±6 (range 2–31), respectively. The median (25th–75th percentile) duration of penicillin administration was 4 (3–7) days (mean 5±3, range 2–17). A rapid-acting inhaled bronchodilator (63.0%), short course of systemic corticosteroids (24.0%), intravenous hydration (saline solution plus 5% dextrose in water (1:4)) (66.2%) and oxygen (6.5%) were also given on admission.

Table 1 shows an assessment of the frequency of overall clinical findings during the first 2 days of penicillin G treatment. Nobody presented seizure. Oxygen was provided during the evolution to 16 (11.1%) patients of 144 admitted without initial oxygen supplement requirement. Penicillin G was substituted by other antibiotics in 28 (18.2%) patients, among whom the median (25th–75th percentile) duration of penicillin G administration was 3.5 (2-4) days (mean 4±2). The subsequent antimicrobial agents were oxacillin plus ceftriaxone (n = 11), ceftriaxone (n = 11), erythromycin and oxacillin (n = 3 each). Patients treated with other antimicrobial agents stayed longer in the hospital than those treated solely with penicillin G (16±6 vs. 8±4 days, p<0.001, mean difference (95% confidence interval): 8 (6-10]). Oxygen supplement during evolution was more common among patients in whom substitution for penicillin G occurred (26.9% vs. 7.6%, p = 0.01).

Comparison of the daily frequency of clinical findings in this group showed that the only significant difference was tachypnea from the first to second day of treatment (86.4% vs. 50.0%, p = 0.008). Among patients receiving only penicillin G during the whole treatment, significant differences were found between admission and first day of treatment: fever (46.4% vs. 26.3%, p = 0.002), tachypnea (73.6% vs. 59.4%, p = 0.003), chest indrawing (29.4% vs. 12.7%, p<0.001) and nasal flaring (10.2% vs. 1.6%, p = 0.001). Differences were also found in the frequency of fever between the second and third day (26.8% vs. 13.7%, p = 0.001) and between the fourth and fifth day (17.8% vs. 10.3%, p = 0.006). Figures 2A and 2B present the daily evolution of clinical findings in the groups of patients without and with penicillin G substitution after 48 h of treatment. Antibiotic change was not associated with pleural effusion (25.0% vs. 15.8%, p = 0.2), severe (19.6% vs. 17.6%, p = 0.8) or very severe (15.8% vs. 18.5%, p = 1) CAP according to WHO, severe CAP according to BTS (18.7% vs. 17.0%, p = 0.8), severe malnutrition (16.7% vs. 18.2%, p = 1) or age (38±29 vs. 30±24 months, p = 0.2).

Figure 2A.

Daily evolution (%) of (A) 126 children hospitalized with community-acquired pneumonia treated exclusively with penicillin G and (B) 28 children hospitalized with community-acquired pneumonia in whom penicillin G was substituted by other antimicrobial agents after 2 days of us.

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From the aforementioned data it can be seen that aqueous penicillin G successfully treated the great majority (82%) of the studied hospitalized children aged ≥2 months with radiographically confirmed CAP. This result is in accordance with the expected therapeutic success rate (80%).15

Among children receiving solely penicillin G, marked recovery occurred during the first 24 h of treatment. A rapid and uneventful improvement has been described among children hospitalized with CAP treated mainly with penicillin G in a developed country.16 Surprisingly, after the major impact of a decreased frequency of clinical findings from admission to the first day of treatment, further reduction of these clinical findings was slow in the same group of patients (Figure 2A). Based on expert consensus, if no improvement takes place within 2 days of treatment, the recommendation is to review the antibacterial treatment given.17 In the literature, there is no clear evidence-based definition of treatment failure among children with CAP, mainly for hospitalized patients.15 In a study enrolling patients with non-severe and severe CAP, in addition to deterioration, no improvement after 48 h of therapy was used as the definition of clinical failure.18 By applying such a definition to the patients in this investigation, the therapeutic failure rate of penicillin G would be much greater since on the fourth day of treatment over 40% presented tachypnea and around 20% presented fever (Figure 2A). Moreover, on the sixth day of treatment, over 30% still presented tachypnea (Figure 2A).

We found an association between the requirement for an oxygen supplement during treatment and penicillin G substitution. Therefore, the concept of deterioration was used by the pediatricians managing the studied patients. However, the concept of no improvement in the first 2 days of treatment was not used. By comparing the graphic evolution of children in whom penicillin G had been changed with the group receiving solely penicillin G (Figures 2A and B), it can be seen that fever and tachypnea were steadily present during the studied period in the former group. Despite the statistical significance found for the decrease of tachypnea from the first to the second day of treatment in the former group, the increased frequency of tachypnea on the third day of treatment is in accordance with the observation of a marked absence of improvement among those patients.

The absence of an association between change of penicillin G and baseline aspects of the patient, such as age, severe or very severe CAP or severe malnutrition, was noteworthy. Severity has been identified as a risk factor for treatment failure among adults with CAP.19 Nonetheless, this was not found in this study. Moreover, pleural effusion was not associated with change of penicillin G. The main cause of bacterial CAP, S pneumoniae, has been identified as the most common bacterium among children with CAP and pleural effusion.20 As a retrospective survey, this investigation was influenced by the way in which the pediatrician handled the patients. Penicillin G has been widely used in the setting in which this survey was carried out because of the previous use of an investigational protocol on the association of pneumococcal resistance in vitro with penicillin G failure in vivo (the CARIBE Study).21 Although the data for the latter protocol were collected between 1998 and 2000, data collection for our investigation included children hospitalized from 2002 to 2005. As the CARIBE Study concluded that there is no association between penicillin G therapeutic failure and pneumococcal minimal inhibitory concentration up to 4 μg/mL,22 pediatricians are probably confident about the success of penicillin G. By studying the pharmacokinetics of 200,000 IU/kg/day of penicillin G in children with CAP, serum penicillin G concentrations were >4 μg/mL for >40% of the interdose interval,23 which predicts therapeutic success in treating pulmonary infections caused by pneumococcal strains with minimal inhibitory concentration up to 4 μg/mL.24 In Brazil, up to the present, the highest minimal inhibitory concentration described for pneumococcal strains is 4 μg/mL, which is rare.25

Several methodological limitations should be recognized in this study: first, as data were collected retrospectively, there was no control on the measurement of the variables; second, as the patients were evaluated by different observers, standardization of the evaluations cannot be guaranteed; third, no attempt was made to determine the etiology and the causative agents of CAP were not known. Nevertheless, strict enrolment criteria were used, assuring that each included case had CAP defined by the “gold standard” parameter—chest x-ray diagnosis. Moreover, by taking into account that 26% of the cases presented pleural effusion and 98.4% of the pulmonary infiltrates were described as alveolar (95.1% as alveolar and 3.3% as interstitial–alveolar), the assumption was that the majority of the cases had a bacterial etiology.11 As the patients were hospitalized in a teaching hospital where several research projects on CAP have been conducted during the past 13 years,26 it is highly probable that standardized measures were used. In daily practice, an antibiotic is chosen empirically to treat children with CAP and etiology is rarely established.17 Therefore, the results presented herein may be generalized to similar situations.

In conclusion, penicillin G is highly effective in treating children hospitalized with CAP. Since patients' disease does not deteriorate during treatment, observation may continue for more than 48 h to document clinical improvement.