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Epidemiology of hospitalised paediatric community-acquired pneumonia and bacterial pneumonia following the introduction of 13-valent pneumococcal conjugate vaccine in the national immunisation programme in Japan

Published online by Cambridge University Press:  17 April 2020

N. Takeuchi
Affiliation:
Department of Infectious Diseases, Medical Mycology Research Centre, Chiba University, Chiba, Japan
S. Naito
Affiliation:
Department of Paediatrics, Chiba University Hospital, Chiba, Japan
M. Ohkusu
Affiliation:
Department of Infectious Diseases, Medical Mycology Research Centre, Chiba University, Chiba, Japan
K. Abe
Affiliation:
Department of Paediatrics, Chiba Kaihin Municipal Hospital, Chiba, Japan
K. Shizuno
Affiliation:
Department of Clinical Laboratory, Chiba Kaihin Municipal Hospital, Chiba, Japan
Y. Takahashi
Affiliation:
Department of Paediatrics, Seikeikai Chiba Medical Centre, Chiba, Japan
Y. Omata
Affiliation:
Department of Paediatrics, Seikeikai Chiba Medical Centre, Chiba, Japan
T. Nakazawa
Affiliation:
Department of Paediatrics, Seikeikai Chiba Medical Centre, Chiba, Japan
K. Takeshita
Affiliation:
Department of Paediatrics, Chiba University Hospital, Chiba, Japan
H. Hishiki
Affiliation:
Department of Paediatrics, Chiba University Hospital, Chiba, Japan
T. Hoshino
Affiliation:
Division of Infectious Diseases, Chiba Children's Hospital, Chiba, Japan
Y. Sato
Affiliation:
Department of Preventive Medicine and Public Health, Keio University School of Medicine, Shinjuku-ku, Japan
N. Ishiwada*
Affiliation:
Department of Infectious Diseases, Medical Mycology Research Centre, Chiba University, Chiba, Japan
*
Author for correspondence: N. Ishiwada, E-mail: [email protected]
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Abstract

Studies on community-acquired pneumonia (CAP) and pneumococcal pneumonia (PP) related to the 13-valent pneumococcal conjugate vaccine (PCV13) introduction in Asia are scarce. This study aimed to investigate the epidemiological and microbiological determinants of hospitalised CAP and PP after PCV13 was introduced in Japan. This observational hospital-based surveillance study included children aged ⩽15 years, admitted to hospitals in and around Chiba City, Japan. Participants had bacterial pneumonia based on a positive blood or sputum culture for bacterial pathogens. Serotype and antibiotic-susceptibility testing of Streptococcus pneumoniae and Haemophilus influenzae isolates from patients with bacterial pneumonia were assessed. The CAP hospitalisation rate per 1000 child-years was 17.7, 14.3 and 9.7 in children aged <5 years and 1.18, 2.64 and 0.69 in children aged 5–15 years in 2008, 2012 and 2018, respectively. There was a 45% and 41% reduction in CAP hospitalisation rates, between the pre-PCV7 and PCV13 periods, respectively. Significant reductions occurred in the proportion of CAP due to PP and PCV13 serotypes. Conversely, no change occurred in the proportion of CAP caused by H. influenzae. The incidence of hospitalised CAP in children aged ⩽15 years was significantly reduced after the introduction of PCV13 in Japan. Continuous surveillance is necessary to detect emerging PP serotypes.

Type
Original Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press

Introduction

Streptococcus pneumoniae is one of the leading causes of community-acquired pneumonia (CAP) in children. After the introduction of heptavalent pneumococcal conjugate vaccine (PCV7), the incidence of paediatric CAP decreased in many countries [Reference Grijalva1Reference Jardine, Menzies and McIntyre3]. The 13-valent pneumococcal conjugate vaccine (PCV13) against paediatric CAP, as reported recently, is effective in several countries [Reference Hortal4Reference Mackenzie7]. In the USA, PCV7 and PCV13 were introduced in 2000 and 2010, respectively. Griffin et al. [Reference Griffin8] reported that all-cause pneumonia hospitalisations in children aged <2 years declined by an additional 27%, between 2010 and 2012 in the USA following the introduction of PCV13. The reduction in all-cause pneumonia admissions in children provides an estimate of the proportion of paediatric pneumococcal pneumonia (PP); however, little is known about the incidence of pneumonia attributable to S. pneumoniae and individual serotypes.

According to the review on paediatric pneumonia hospitalisation incidence rates in developed countries, the incidence of pneumonia hospitalisations in Japan was higher than that of other developed countries before the introduction of PCV [Reference Madhi9]. PCV7 was introduced in Japan in February 2010 as a voluntary vaccination. One year later, the Japanese government subsidised the vaccination. Most of the children <5 years of age were able to receive the PCV7 immunisation free of charge. The estimated immunisation coverage increased rapidly to >95% and high immunisation coverage was maintained. PCV7, included in the routine vaccination programme in April 2013 was changed to PCV13 in November 2013 [Reference Ishiwada10]. The schedule for PCV13 vaccination in Japan is three doses, administered at the ages of 2, 3 and 4 months, followed by a booster dose at 12–15 months. Both the subsidised vaccination and routine vaccination have the same schedule in Japan. However, compensation for vaccine-related health damage differs.

To assess the direct impact of PCV against paediatric CAP, we implemented a surveillance system before the introduction of PCV7 in Chiba City, Japan. Based on this surveillance system, we determined the hospitalised paediatric CAP incidence for children <5 years of age, which showed that PP decreased significantly [Reference Tanaka11, Reference Naito12].

Here we report the incidence of hospitalised CAP after the introduction of PCV13 in the national immunisation programme in Japan, based on this surveillance system [Reference Tanaka11, Reference Naito12]. We also described the serotype, sequence type (ST) and antimicrobial susceptibility of S. pneumoniae isolated from patients with PP after the introduction of PCV13. To date, detailed reports on the aetiology of CAP related to the PCV13 era in Asian and Western Pacific countries are scarce. Such information, which would enable an estimate of the impact of PCV13 against CAP in children, is essential in these countries where pneumonia is the leading cause of death in children [Reference Nguyen, Tran and Roberts13].

Methods

Study design, study setting and participants

The incidence of hospitalised CAP was calculated based on an observational surveillance study in Chiba City, the capital of Chiba Prefecture, in central Japan. According to the Japanese census data, the total population of Chiba City was 969 544 (about 0.8% of the population of Japan) [14] and the population of children aged <5 years and 5–15 years in Chiba City was 35 885 and 92 281, respectively, in September 2018 [14]. A questionnaire was sent to 15 hospitals with paediatric wards in and around Chiba City. The study occurred from April 2016 to March 2019 (Japanese fiscal year 2016–2018). Children aged 1 month to 15 years who lived in Chiba City and were admitted to hospital with CAP were included in this study. The number of hospitalised CAP cases covered the entire Chiba City and the entire region, including residents only.

The 15 hospitals are located in and around Chiba City. There is little possibility of admitting paediatric CAP patients who are resident in Chiba City, other than in the 15 hospitals. The numbers of hospital admissions due to pneumonia and blood culture-positive pneumonia patients were estimated to cover all inhabitants of Chiba City aged ⩽15 years whose data were obtained from all hospital clinical records.

The incidence of hospitalised CAP in Chiba City

The incidence of hospitalised CAP in this study period was compared with that reported in our previous studies from April 2008 to March 2009 (2008) and from April 2012 to March 2013 (2012) [Reference Tanaka11, Reference Naito12]. The number of hospitals targeted in this surveillance was lower than that in our previous studies [Reference Tanaka11, Reference Naito12]. In Japan, some hospitals closed the paediatric wards as the number of children decreased. In this study, we included all seven hospitals with a paediatric ward in Chiba City and eight nearby hospitals with paediatric wards. Therefore, the 15 hospitals included in this study covered almost all hospitalised children who were residents in Chiba City. To calculate the annual hospitalised CAP incidence in Chiba City for those < 5 years of age and those aged 5–15 years in 2016–18, the number of hospitalised CAP cases was divided by the total number of inhabitants pertaining to the two age groups (obtained from Japanese census data). Person-years were based on mid-year population estimates. There are six health care centres in Chiba City. Health care centres only care for healthy children in Japanese health system. In general, radiological diagnosis of pneumonia is done by a paediatrician not by radiologists, in Japan. In this study, abnormal shadows in chest radiographs were confirmed by at least two paediatricians. Pneumonia was diagnosed based on at least one of the following abnormal clinical findings on chest radiograph: fever, cough, rapid breathing, difficulty in breathing, or crackles on auscultation of the lungs. The same doctors in each hospital read the chest radiographs and made the diagnosis of pneumonia. In each hospital, the member of senior medical staff did not change compared to our previous studies. Furthermore, the accuracy of the radiological diagnosis of pneumonia in this study remained similar to that of our previous studies.

Diagnosis of bacterial pneumonia

Blood cultures and sputum samples were collected from the patients on admission. Bacterial pneumonia was diagnosed based on a positive blood culture or the isolation of microorganisms from washed sputum samples. Sputum samples were collected from children as described previously [Reference Cao15]. Collected sputum samples were washed with sterilised saline solution. A small purulent portion of the washed sputum was smeared onto glass slides. Valid Gram-stained smears for sputum culture samples were according to Geckler's classification four or five. This method effectively isolated the pathogenic bacteria (e.g. S. pneumoniae, H. influenzae and Moraxella catarrhalis) and reduced contamination by oral flora. Washed sputum samples were cultured in each hospital and pathogens accounting for >50% of the colonies in the culture, or presenting as >1 × 107 cfu/ml were regarded as pathogenic. In order to diagnose M. catarrhalis pneumonia, leukocyte phagocytosis of bacteria was detected in Gram-stained samples [Reference Uehara16].

Data on patients' backgrounds and clinical information were collected and recorded on a standard case report sheet. Administration of PCV7 and/or PCV13 was documented in the patient's medical record or in the maternal health record book that is used to document children's vaccination history in Japan. Vaccination status information was obtained from all patients in four hospitals. The number of hospitalised bacterial pneumonia in children aged ⩽15 years who were admitted to hospital with pneumonia was determined during the three vaccination periods in four hospitals in Chiba City. These four hospitals reported more than half of the hospitalised pneumonia patients in our previous studies [Reference Tanaka11, Reference Naito12].

The number of hospitals where bacterial analyses were performed were 6, 5 and 4 in 2008, 2012, 2016–18, respectively. Except in two hospitals, the number of the paediatricians decreased and doctors predominantly took care of outpatients during the study period. Therefore, we thought that the coverage of hospitalised CAP patients was similar in the three study periods.

Isolation of S. pneumonia strains

S. pneumoniae isolates from blood and washed sputum samples were collected from the four study hospitals. The strains were stored at −80 °C in each hospital and sent to the Medical Mycology Research Centre at Chiba University. This centre used the same methods and had the same skill of bacteriological analysis compared with that in our previous studies. Each isolate was grown on trypticase soy agar (TSA) with 5% sheep blood (Nippon Becton Dickinson Co. Ltd., Tokyo, Japan) for 24 h at 37 °C in 5% CO2. Each isolate was identified as S. pneumoniae using an optochin susceptibility test and a bile solubility test. Polymerase chain reaction (PCR) assays targeting the lytA gene, which encodes the major pneumococcal autolysin (LytA), were also used to identify S. pneumoniae. All strains were susceptible to optochin, bile-soluble and positive for the lytA gene and were therefore identified as S. pneumoniae.

Serotypes were determined using the slide agglutination reaction with the S. pneumoniae antisera using the Seiken set (Denka Seiken, Tokyo, Japan) and the Quellung reaction using pneumococcal antisera (Statens Serum Institut, Copenhagen, Denmark). The non-encapsulated strain was detected via the PCR method using primers for cpsA, the capsular polysaccharide biosynthesis gene.

Multilocus sequence typing (MLST) was performed as described previously [Reference Enright and Spratt17]. Sequence types (STs) were determined by comparing the derived sequences of each locus to all known alleles by reference to the MLST database (http://pubmlst.org/spneumoniae/). The STs were compared with 43 pneumococcal clones, which included 26 multidrug-resistant (MDR) clones, in the Pneumococcal Molecular Epidemiology Network (PMEN; http://www.sph. emory.edu/PMEN/). Strains were assigned to one clonal complex (CC) when five or six of the seven alleles were identical to those of another ST in the group of the relationships between the isolates were determined using goeBURST software, Version 1.2.1 (http://www.phyloviz.net/goeburst).

Antimicrobial susceptibilities of S. pneumoniae to penicillin G (PCG), ampicillin (ABPC), cefditoren (CDTR), cefotaxime (CTX), ceftriaxone (CTRX), meropenem (MEPM), panipenem (PAPM), tebipenem (TBPM), erythromycin (EM), clindamycin (CLDM), tosufloxacin (TFLX) and vancomycin (VCM) were analysed using the broth microdilution method according to the Clinical and Laboratory Standards Institute (CLSI) M07-A11 protocol. The minimal inhibitory concentration (MIC) breakpoints were defined according to the CLSI criteria (CLSI M100-S29).

Isolation of H. influenzae strains

H. influenzae isolates from blood and sputum samples were stored at −80 °C in each hospital and sent to the Medical Mycology Research Centre at Chiba University for further testing. The strains were stored immediately after isolation and then grown on Chocolate II Agar (Nippon Becton Dickinson Company, Tokyo, Japan). Strains were identified based on their growth requirements for hemin and nicotinamide adenine dinucleotide (X and V factors). They were also identified genetically by the PCR method as described previously, using the primers for sialic acid transporter gene (siaT) of H. influenzae [Reference Price18].

Serotyping was confirmed by PCR using primers for bexA and serotype-specific genes, as described previously [Reference Falla19]. Antimicrobial susceptibilities of H. influenzae to PCG, ABPC, CDTR, CTX, CTRX, MEPM, PAPM, TBPM, EM, CLDM, TFLX and VCM were analysed using the broth microdilution method according to the CLSI M07-A11 protocol. MIC breakpoints were defined according to the CLSI criteria (CLSI M100-S29). β-lactamase production was tested by cefinase disk (Nippon Becton Dickinson Company, Tokyo, Japan).

Statistical analysis

All data were analysed using JMP Pro Version 12 (SAS Institute, Cary, NC). Poisson regression was used to estimate incidence rates, incidence rate ratios and confidence intervals of CAP and PP. Between-group differences in patient characteristics were analysed using the Kruskal–Wallis test. Fisher's exact test was used to compare the coverage rate of PCV13 serotypes of S. pneumoniae isolated from PP patients before and after the introduction of PCV7/PCV13. All odds ratios, 95% confidence intervals (CIs) and P-values were estimated using logistic regression based on Firth's penalised likelihood estimation. All P-values represented two-tailed tests, with P < 0.05 considered statistically significant.

Ethical issues

The authors assert that all procedures contributing to this work complied with the ethical standards of the relevant national and institutional (Chiba University Ethics Committee [No. 1301]) committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008. Patients' records and information were anonymised prior to the analysis. For the microbial study performed in four hospitals, written informed assent was obtained from the parents of the children with CAP at the time of admission, in accordance with the guidelines of the Institutional Review Board of Chiba University (Chiba University Ethics Committee [No. 1301]).

Results

The annual hospitalised CAP incidence among children aged <5 years

Overall, 1399 children were admitted with CAP, in the PCV13 period. Of the children who participated in the study, 596 (42.6%), 526 (37.6%) and 277 (19.8%) were aged <2, 2–4 and 5–15 years, respectively. Figure 1 shows the number of children in Chiba City hospitalised with CAP in the pre-PCV7, PCV7 and PCV13 periods. The annual hospitalised CAP incidence per 1000 children aged <5 years in 2008, 2012, 2016, 2017 and 2018 were 17.7, 14.3, 10.1, 10.6 and 9.7, respectively. The CAP hospitalisation rate in children <5 years of age in 2018 declined by 45% (incidence rate ratio (IRR) 0.55, 95% confidence interval (CI) 0.48–0.62) and 32% (IRR 0.68, 95% CI 0.59–0.77) compared to the rates in the pre-PCV7 and PCV7 periods, respectively (Table 1).

Fig. 1. Number of hospitalized paediatric children <5 years of age with CAP before and after PCV7/PCV13 introduction in Chiba City, Japan. Since the introduction of PCV in children, the incidence of hospitalised paediatric CAP in children aged <5 years has decreased. After PCV13 introduction, the incidence of hospitalised CAP children <5 years of age further declined. CAP, community-acquired pneumonia; PCV7, heptavalent pneumococcal conjugate vaccine; PCV13, 13-valent pneumococcal conjugate vaccine

Table 1. The incidence of hospitalized community-acquired pneumonia in children in Chiba city, Japan, before and after the introduction of PCV7 and PCV13

CAP, community-acquired pneumonia; CI, confidence interval; IRR, incidence rate ratio; PCV7, heptavalent pneumococcal conjugate vaccine; PCV13, 13-valent pneumococcal conjugate vaccine.

a Cases/1000 population per year.

b Estimated using Poisson regression.

The annual hospitalised CAP incidence among children aged 5–15 years

The annual hospitalised CAP incidence per 1000 children aged 5–15 years in 2008, 2012, 2016, 2017 and 2018 were 1.18, 2.64, 1.41, 0.84 and 0.69, respectively (Fig. 2). The CAP hospitalisation rate in children aged 5–15 years increased in the PCV7 period compared to the pre-PCV7 period. However, in the PCV13 period, the rate declined by 41% (IRR 0.59, 95% CI 0.43–0.80) and 74% (IRR 0.26, 95% CI 0.20–0.35), compared to the rates in the periods before and after PCV7, respectively (Table 1).

Fig. 2. The number of hospitalised paediatric children 5–15 years of age with CAP before and after PCV7/PCV13 introduction in Chiba City, Japan. After PCV13 introduction, the incidence of hospitalised CAP children 5–15 years of age declined. CAP, community-acquired pneumonia; PCV7, heptavalent pneumococcal conjugate vaccine; PCV13, 13-valent pneumococcal conjugate vaccine

Characteristics of children admitted to the four study hospitals with CAP

Overall, 904 of 1399 (64.6%) children were admitted to four study hospitals with the diagnosis of CAP in the PCV13 period. During the study period, seven children with bacteremic pneumonia caused by S. pneumoniae were reported. Their characteristics are shown in Table 2. One child died of CAP due to parainfluenza virus.

Table 2. The characteristics of children with community-acquired pneumonia admitted to the four study hospitals after the introduction of PCV13

PCV13, 13-valent pneumococcal conjugate vaccine; PCV7, heptavalent pneumococcal conjugate vaccine; Hib, Haemophilus influenzae type b

Pneumococcal pneumonia

We obtained sputum and blood samples from 828 (91.6%) and 819 (90.6%) of the 904 children with CAP. While S. pneumoniae was culture-dominant in 64/828 (7.7%) of the sputum samples, there were only six blood culture samples positive for S. pneumoniae. Six patients had blood culture samples positive for S. pneumoniae, four (4/276: 1.5%) in 2016, one (1/ 292: 0.3%) in 2017 and one (1/ 251: 0.4%) in 2018. Of the six patients with blood culture-positive S. pneumoniae, three also had a positive sputum culture. One patient with positive blood culture in 2017, for S. pneumoniae. However, the patient was hospitalised to the remaining 11 hospitals included in our CAP study, which enabled us to obtain the pneumococcal strain for further analysis. H. influenzae was culture-dominant in 132/828 (15.9%) sputum samples, but no child was blood culture-positive for H. influenzae. Table 3 shows the microorganisms isolated from blood and sputum samples among CAP patients in the pre-PCV7, PCV7 and PCV13 periods. Over the course of the three periods, the number of isolates of S. pneumoniae decreased. In contrast to the incidence trend of CAP due to S. pneumoniae that related to H. influenzae and M. catarrhalis did not change significantly after PCV7 and PCV13 introduction.

Table 3. Microorganisms isolated from blood and dominantly isolated from sputum samples of children with community-acquired pneumonia admitted to the four study hospitals

PCV7, heptavalent pneumococcal conjugate vaccine; PCV13, 13-valent pneumococcal conjugate vaccine.

Serotype distribution of S. pneumoniae strains

Table 4 and Figure 3 show serotype distribution of S. pneumoniae strains isolated from blood and dominant isolates from sputum samples. Of the three children with S. pneumoniae isolated in both blood and sputum cultures, the blood isolates and sputum isolates were of the same serotype in two patients. In the third patient, the blood isolate was serotype 24B, while the sputum isolate was 24B capsular loss strain. In the pre-PCV7 period, the most frequent serotypes were 6B, 23F and 19F. Of the isolated strains, 67.6% and 82.4% were covered by PCV7 and PCV13, respectively. After PCV7 introduction, PCV7 serotypes dramatically decreased and the major serotypes changed to 19A, 6C, 15A and 15C. In the PCV13 period, among PCV13 serotypes, the incidence of CAP due to serotypes 1, 3, 7F and 19A strains decreased.

Fig. 3. Distribution of S. pneumoniae serotype isolated from blood and sputum of the paediatric inpatients with CAP. In the pre-PCV7 period, the most frequent serotypes were 6B, 23F and 19F in children. After introduction of PCV7, PCV7 serotypes dramatically decreased and the major serotypes changed to 19A, 6C, 15A and 15C. In the PCV13 period, of the PCV13 serotypes, a small number of serotypes 1, 3, 7F and 19A were isolated. Of the non-PCV13 serotypes, the dominant serotypes were 35B, 15A and 11A/E.

Table 4. PCV7/PCV13 serotypes of Streptococcus pneumoniae isolated from the blood or sputum as a proportion of all Streptococcus pneumoniae isolates in children with community-acquired pneumonia admitted to the four study hospitals, according to the year of admission

PCV7, heptavalent pneumococcal conjugate vaccine; PCV13, 13-valent pneumococcal conjugate vaccine.

a S. pneumoniae serotypes targeted by the PCV7.

b S. pneumoniae serotypes targeted by the PCV13.

One strain was isolated from the blood in a child that was admitted to a hospital, other than the four study hospitals.

Among the non-PCV13 serotypes, the dominant serotypes were 35B, 15A and 11A after PCV13 introduction. The PCV13 serotype rates among all isolated strains gradually decreased from 30.0% to 13.0% after the introduction of PCV13. Among PCV13 serotypes, 75% of the strains were isolated from patients with underlying disease.

MLST was performed on 59 sputum isolates in which S. pneumoniae was the dominant organism on the six blood isolates in the PCV13 period (Table 5). Of the 65 isolates tested, 35 STs were found, including two new STs. STs 22F (ST1092), 23A (ST3163), 24B (ST2572 and ST162), 24F (ST2572 and ST5496), 34 (ST7388) and 38 (ST1429) were categorised into the same clonal group with ST320 by eBURST. Among tested strains, 23.7% (14/59) and 33.3% (2/6) of the sputum and blood isolates had STs identical to five international PMEN clones, respectively. Nine, seven and six strains of 35B-ST558, 11A-ST99 and 15A-ST63, respectively, were the three major ST types in the PCV13 period.

Table 5. Multilocus sequence typing analysis of Streptococcus pneumoniae strains isolated after the introduction of PCV13, by year

PCV7, heptavalent pneumococcal conjugate vaccine; PCV13, 13-valent pneumococcal conjugate vaccine; ST, sequence type; CC, clonal complex; UT, untypeable; NT, non-typeable; PMEN, Pneumococcal Molecular Epidemiology Network

NT strain was the non-encapsulated strain

Clones known as multidrug-resistant pneumococcal molecular epidemiology network (PMEN) clones are shown in bold.

The number of strains isolated from blood is shown in (parentheses).

a One strain that was isolated from the sputum was 24B capsular loss strain.

Antimicrobial susceptibility of S. pneumoniae

Antimicrobial susceptibility was tested in 68 S. pneumoniae isolates. Table 6 shows MIC 50 and MIC-range of the isolates tested according to the year. Antimicrobial susceptibility did not change after the introduction of PCV13. Figure 4 shows the PCG susceptibility of S. pneumoniae isolates from blood and sputum samples among CAP patients during the pre-PCV7, PCV7 and PCV13 periods. The proportion of PCG-sensitive isolates increased after PCV introduction. In the PCV13 period, the serotypes that were less susceptible to PCG were serotypes 15A (ST 63) and 35B (ST 558). These serotypes were susceptible to the antibiotics, TFLX and TBPM, which were newly approved in Japan. From 2017, EM susceptible strains were detected. Of the total, 53% of PCG less-susceptible strains (PCG ⩾ 0.12) were isolated from patients with underlying disease.

Fig. 4. Susceptibility of S. pneumoniae isolates from blood and sputum samples to penicillin G among CAP patients. The susceptibility to PCG recovered after PCV introduction. CAP, community-acquired pneumonia; PCG, penicillin G; PCV, pneumococcal conjugate vaccine

Table 6. Antimicrobial susceptibility of Streptococcus pneumoniae isolates from children with community-acquired pneumonia

PCV13, 13-valent pneumococcal conjugate vaccine; MIC, minimal inhibitory concentration; PCG, penicillin G; ABPC, ampicillin; CTX, cefotaxime; CDTR, cefditoren; CTRX, ceftriaxone; MEPM, meropenem; PAPM, panipenem; TBPM, tebipenem; EM, erythromycin; CLDM, clindamycin; VCM, vancomycin; TFLX, tosufloxacin.

Serotype distribution and antimicrobial susceptibility of H. influenzae

Serotyping and antimicrobial susceptibility were performed in 126 sputum samples in which H. influenzae was the dominant isolate. With serotypes, 125 strains were non-typeable, one strain was type f but type b strain was not detected. Antimicrobial susceptibility did not also change after PCV13 introduction. Of the 126 isolates, 92 (73.0%) were ABPC resistant (ABPC ⩾ 4) (Table 7). Among the isolates, 33 (26.2%) were β-lactamase-producing strains. β-lactamase non-ABPC-resistant strains had less susceptibility to third generation cephalosporin.

Table 7. Antimicrobial susceptibility of Haemophilus influenzae isolates from children with community-acquired pneumonia

PCV13, 13-valent pneumococcal conjugate vaccine; MIC, minimal inhibitory concentration; PCG, penicillin G; ABPC, ampicillin; CTX, cefotaxime; CDTR, cefditoren; CTRX, ceftriaxone; MEPM, meropenem; PAPM, panipenem; TBPM, tebipenem; EM, erythromycin; CLDM, clindamycin; VCM, vancomycin; TFLX, tosufloxacin

Discussion

This is the first study to directly prove the impact of PCV13 against hospitalised paediatric CAP following an observational surveillance study in Asia. Compared to before PCV13 introduction, hospitalised paediatric CAP incidence decreased significantly. Furthermore, the proportion of CAP due to S. pneumoniae decreased and the pneumococcal serotype changed from PCV13 serotypes to non-PCV13 serotypes. During the three study periods (2008–2018), health system and diagnostic methods of CAP and bacterial pneumonia were not changed in Chiba City. This phenomenon further provides evidence of the impact of PCV13. To date, reports on the effectiveness of PCV13 against paediatric CAP have been focused on children <5 years of age [Reference Hortal4Reference Griffin8]. In 2012, after the introduction of PCV7, the incidence of CAP among those aged 5–15 years increased in our surveillance system (Fig. 2). The Mycoplasma pneumoniae epidemic and CAP due to other microbial pathogens influenced the overall incidence of CAP. A M. pneumoniae infection epidemic occurred in Japan from 2011 to 2012 [Reference Tanaka20]. One of the reasons why the incidence of CAP in older children increased in 2012 could be attributed to the epidemic of macrolide-resistant M. pneumoniae infection in Japan [Reference Tanaka20]. Our study revealed that after the introduction of PCV13, hospitalised CAP incidence decreased not only in children aged <5 years, but also in those aged 5–15 years. In the PCV13 period, almost all children aged ⩾5 years did not receive the full shots of PCV13 because it was introduced in Japan in 2013. According to a review paper, an indirect effect of PCV13 for both invasive pneumococcal disease (IPD) and pneumonia in adults has been observed [Reference Tsaban and Ben-Shimol21]. Our results suggest that PCV13 also had an indirect impact on children aged 5–15 years.

Practically, among 232 hospitalised CAP children <5 years of age in this study, only six (6.6%) were PCV13 unvaccinated. Conversely, among 48 hospitalised CAP children 5–15 years of age, 27 (56.3%) were PCV13 unvaccinated. The rate of hospitalised CAP in unvaccinated children 5–15 years of age decreased from 10.3% (65/626) in 2008 to 9.6% (27/280) in 2018; however, not statistically different.

Diagnosis of bacterial pneumonia was an important issue in this study. The prevalence of invasive PP in children in developed countries is low [Reference Hickey, Bowman and Smith22]. There were only seven children with CAP complicated by bacteraemia among the 1399 CAP patients in this study. To estimate the direct effect of PCV, several diagnostic methods have been used, including serological diagnosis, pneumococcal-specific PCR and urinary antigen [Reference Berg23Reference Wunderink25]. In our surveillance, we utilised sputum sample for the diagnosis of bacterial pneumonia because sputum can be obtained easily and non-invasively. Both the Japanese and the US guidelines recommend sputum Gram staining and culture for the pathogenic diagnosis of paediatric CAP [Reference Uehara16, Reference Bradley26]. The diagnostic yields of sputum culture are limited by potential contamination from the upper respiratory tract. We combined a washing technique with a semi-quantitative culture approach to evaluate pathogenic bacteria in our previous studies [Reference Tanaka11, Reference Naito12]. Given that S. pneumoniae is rarely isolated from blood culture in children with pneumonia, the washed sputum method used in this study was reliable and can be used to identify the pathogen in children. This enabled us to investigate the impact of PCV13 on the incidence of non-invasive PP.

Washed sputum culture has also provided information on how PCV13 protects against pathogenic bacteria other than S. pneumoniae. In our study, after PCV13 introduction, PP incidence decreased; however, the number of pneumonia cases caused by H. influenzae and M. catarrhalis remained unchanged.

In terms of the serotype replacement of S. pneumoniae, after the PCV13 introduction, the causative S. pneumoniae strains changed from PCV13 type to non-PCV13 type in our study. Olarte et al. [Reference Olarte27] reported that PP requiring hospitalisation significantly decreased in children after PCV13 introduction in the USA. The most common serotypes were 3, 19A and 35B in 2014, 4 years after PCV13 introduction. In our surveillance data, before PCV introduction, most of the isolated S. pneumoniae strains were 6B, followed by 19F and 23F. After PCV7 introduction, the isolated strains changed from PCV7 serotypes to non-PCV7 serotypes, mainly 6C, 15A, 15C and 19A. In this study, after PCV13 introduction, no PCV7 serotypes were detected and the incidence of PCV13 serotypes among isolated strains gradually decreased, 4 years after PCV13 introduction in Japan. The non-PCV13 serotypes isolated from participants during the study period varied. Of the non-PCV13 serotypes, serotypes 35B, 11A and 15A were the most frequently identified isolates; these serotypes and also 24B, were not isolated in 2008 and 2012 [Reference Tanaka11, Reference Naito12]. In particular, serotype 35B has increased since 2017.

The phenomenon of serotype replacement has been reported for other respiratory infection and colonisation in Japanese children. Nakano et al. [Reference Nakano28] recently reported the serotype distribution of S. pneumoniae isolated from paediatric patient with non-invasive diseases, the majority of which were otitis media during 2012–2014. According to their results, serotype 19A decreased and serotype 15A and 35B increased during the study period [Reference Nakano28]. Ubukata et al. [Reference Ubukata29] also reported changes in serotypes of pneumococcal isolates collected between pre-PCV7, PCV7 and PCV13 periods in children. According to their report, among children, the proportion of PCV7 serotypes decreased rapidly from 73.3% during the PCV7 period to 2.3% during the PCV13 period. In particular, the number and proportion of nine serotypes (10A, 12F, 15A, 15B, 15C, 22F, 24F, 33F and 35B) increased significantly after the introduction of PCV7 and PCV13. Thus, even though the overall S. pneumoniae and CAP hospitalisation incidence has decreased, monitoring serotype replacement is important.

Concerning antimicrobial susceptibility, recovery of PCG susceptibility was reported after PCV7 introduction, because many PCV7 serotypes had penicillin-resistant strains [Reference Ubukata29]. In our study, also, after PCV7 introduction, antimicrobial susceptibility increased and the low resistant rate persisted after PCV13 introduction. However, several non-PCV13 serotype PCG-resistant strains existed, including MDR PMEN clone strains especially 15A (ST63). Serotype 35B (ST 558), which is a single locus variant of PMEN clone Utah35B-24 (ST377), was also a major non-PCV13 strain with reduced susceptibility to PCG in our study. These strains also showed reduced susceptibility to cephem and carbapenem. Another study on the antimicrobial susceptibility of S. pneumoniae clinical isolates, conducted among children in Japan, showed the spread of S. pneumoniae with a reduced susceptibility to PCG in non-vaccine serotypes 15A (ST63); 23A (ST338, 5242); 6C (ST242, 5832); and 35B (ST558) [Reference Kawaguchiya, Urushibara and Kobayashi30]. Among strains isolated from otitis media samples, the PCG-resistant serotypes 15A and 35B have also increased. Serotypes 15A, 3 and 35B most often belong to STs 63, 180 and 558 [Reference Ubukata31]. In other countries, the increase in MDR serotype 35B is also directly related to the expansion of ST558 clonal complex and the emergence of vaccine escape recombinant 35B (ST156) due to capsular switching [Reference Olarte32]. Serotype 15A is also known to have one of the MDR pneumococcal serotypes [Reference Hackel33]. Almost all MDR 15A isolates were ST63 variants, whereas susceptible 15A isolates were clonally diverse. The rise in serotype 15A suggests that PCVs will need ongoing adaptation [Reference Sheppard34]. Therefore, there is need to focus attention on these types of strains. In Japan, the rate of macrolide-resistant of S. pneumoniae is higher than in other countries [Reference Ubukata29]. In our study, all isolated strains in 2016 were macrolide resistant. However, several macrolide-sensitive strains have been isolated since 2017.

Non-typeable H. influenzae is also an important bacterial pathogen that causes CAP in children [Reference Cripps35]. In our study, H. influenzae was the most prevalent bacterial pathogen isolated from sputum in study participants. Serotype distribution of H. influenzae is quite different from that of S. pneumoniae. Almost all isolated strains are non-typeable. Only one serotype f strain was isolated from sputum culture. After the introduction of Hib conjugate vaccine in Japan, invasive Hib infection dramatically decreased [Reference Suga36]. Pneumonia caused by Hib has also been eliminated. In terms of the antimicrobial susceptibility of H. influenzae, ABPC resistant rate was 73.0% including the β-lactamase-producing rate of 26.2%. Both resistant rates are higher than the rate in other nationwide studies in children from Japan [Reference Shiro37, Reference Nagai38]. β-lactamase ABPC resistant H. influenzae (BLNAR) has a major resistant pattern of ABPC resistance in Japan and BLNAR strains were also less susceptible to cephems. We have to monitor the tendency of ABPC resistant H. influenzae isolated from CAP in children continuously.

Our study has limitations. The diagnosis of pneumonia was not based on a standardised method; for example, the definition for radiological pneumonia was developed by a World Health Organisation (WHO) group [Reference Cherian39]. The WHO criteria are not being utilised in Japan. Thus, we followed the same method used in our previous studies [Reference Tanaka11, Reference Naito12].

In conclusion, since the introduction of PCV for children, the incidence of hospital admissions for paediatric CAP has decreased in Japan. Culture-proven PP due to PCV13 serotypes has dramatically decreased. This phenomenon suggests the direct impact of PCV13 against paediatric hospitalised CAP. Furthermore, after PCV13 introduction, the incidence of hospitalisations due to CAP decreased not only in children aged <5 years but also in children 5–15 years of age. Conversely, serotypes less susceptible to penicillin, namely, non-PCV13 serotype 15A (ST63) and 35B (ST 558), have become the main non-PCV13 serotypes in Japan. PCV13 is effective for the reduction of hospitalised CAP in children and it is important to maintain the high PCV13 vaccination coverage to control CAP in children. Continuous surveillance of paediatric CAP is necessary to detect emerging pathogens for appropriate management of pneumonia in children.

Acknowledgements

We thank all clinicians in and around Chiba City who contributed to this study. This work was supported by Pfizer research grant (53233001).

Conflict of interest

This study was funded as an investigator-initiated study programme by Pfizer. The funder had no role in the design or conduct of the study, the collection, analysis, or interpretation of data, nor in the preparation, review, or approval of the manuscript. The authors report no personal, political, commercial, financial, or academic conflicts of interest. All authors have approved the final article.

References

Grijalva, CG, et al. (2007) Decline in pneumonia admissions after routine childhood immunisation with pneumococcal conjugate vaccine in the USA: a time-series analysis. The Lancet 369, 11791186.CrossRefGoogle ScholarPubMed
Koshy, E et al. (2010) Impact of the seven-valent pneumococcal conjugate vaccination (PCV7) programme on childhood hospital admissions for bacterial pneumonia and empyema in England: national time-trends study, 1997–2008. Thorax 65, 770774.CrossRefGoogle ScholarPubMed
Jardine, A, Menzies, RI and McIntyre, PB (2010) Reduction in hospitalizations for pneumonia associated with the introduction of a pneumococcal conjugate vaccination schedule without a booster dose in Australia. The Paediatric Infectious Disease Journal 29, 607612.CrossRefGoogle ScholarPubMed
Hortal, M et al. (2012) Hospitalized children with pneumonia in Uruguay: pre and post introduction of 7- and 13-valent pneumococcal conjugated vaccines into the national immunization program. Vaccine 30, 49344938.CrossRefGoogle ScholarPubMed
Izu, A et al. (2017) Pneumococcal conjugate vaccines and hospitalization of children for pneumonia: a time-series analysis, South Africa, 2006–2014. Bulletin of the World Health Organisation 95, 618628.CrossRefGoogle ScholarPubMed
Berglund, A et al. (2014) All-cause pneumonia hospitalizations in children <2 years old in Sweden, 1998 to 2012: impact of pneumococcal conjugate vaccine introduction. PLoS One 9, e112211.CrossRefGoogle ScholarPubMed
Mackenzie, GA et al. (2017) Impact of the introduction of pneumococcal conjugate vaccination on pneumonia in The Gambia: population-based surveillance and case-control studies. The Lancet Infectious Disease 17, 965973.CrossRefGoogle ScholarPubMed
Griffin, MR et al. (2014) Declines in pneumonia hospitalizations of children aged <2 years associated with the use of pneumococcal conjugate vaccines — Tennessee, 1998–2012. Morbidity and Mortality Weekly Report 63, 995998.Google Scholar
Madhi, SA et al. (2013) The burden of childhood pneumonia in the developed world: a review of the literature. The Paediatric Infectious Disease Journal 32, e119e127.Google ScholarPubMed
Ishiwada, N et al. (2014) The incidence of paediatric invasive Haemophilus influenzae and pneumococcal disease in Chiba prefecture, Japan before and after the introduction of conjugate vaccines. Vaccine 32, 54255431.CrossRefGoogle ScholarPubMed
Tanaka, J et al. (2012) Incidence of childhood pneumonia and serotype and sequence-type distribution in Streptococcus pneumoniae isolates in Japan. Epidemiology & Infection 140, 11111121.CrossRefGoogle ScholarPubMed
Naito, S et al. (2016) The impact of heptavalent pneumococcal conjugate vaccine on the incidence of childhood community-acquired pneumonia and bacteriologically confirmed pneumococcal pneumonia in Japan. Epidemiology & Infection 144, 494506.CrossRefGoogle ScholarPubMed
Nguyen, TK, Tran, TH and Roberts, CL (2017) Child pneumonia-focus on the Western Pacific Region. Paediatric Respiratory Reviews 21, 102110.CrossRefGoogle ScholarPubMed
Japanese Census Data for Chiba City. Available at http://www.city.chiba.jp/sogoseisaku/sogoseisaku/kikaku/tokei/agejyuki_past.html (Accessed 26 November 2019).Google Scholar
Cao, LD et al. (2004) Value of washed sputum gram stain smear and culture for management of lower respiratory tract infections in children. The Journal of Infectious Chemotherapy 10, 3136.CrossRefGoogle ScholarPubMed
Uehara, S et al. (2011) Japanese Guidelines for the management of respiratory infectious diseases in children 2007 with focus on pneumonia. Paediatrics International 53, 264276.CrossRefGoogle ScholarPubMed
Enright, MC and Spratt, BG (1998) A multilocus sequence typing scheme for Streptococcus pneumoniae: identification of clones associated with serious invasive disease. Microbiology (Reading, England) 144, 30493060.CrossRefGoogle ScholarPubMed
Price, EP et al. (2017) Simultaneous identification of Haemophilus influenzae and Haemophilus haemolyticus using real-time PCR. Future Microbiology 12, 585593.CrossRefGoogle ScholarPubMed
Falla, TJ et al. (1994) PCR for capsular typing of Haemophilus influenzae. Journal of Clinical Microbiology 32, 23822386.CrossRefGoogle ScholarPubMed
Tanaka, T et al. (2017) Macrolide-Resistant Mycoplasma pneumoniae infection, Japan, 2008–2015. Emerging Infectious Disease 23, 17031706.CrossRefGoogle Scholar
Tsaban, G and Ben-Shimol, S (2017) Indirect (herd) protection, following pneumococcal conjugated vaccines introduction: a systematic review of the literature. Vaccine 35, 28822891.CrossRefGoogle ScholarPubMed
Hickey, RW, Bowman, MJ and Smith, GA (1996) Utility of blood cultures in paediatric patients found to have pneumonia in the emergency department. Annals of Emergency Medicine 27, 721725.CrossRefGoogle Scholar
Berg, AS et al. (2016) Etiology of pneumonia in a paediatric population with high pneumococcal vaccine coverage: a prospective study. The Paediatric Infectious Disease Journal 35, e69e75.CrossRefGoogle Scholar
Silva-Costa, C et al. (2019) Dominance of vaccine serotypes in pediatric invasive pneumococcal infections in Portugal (2012–2015). Scientific Report 9, 6.CrossRefGoogle Scholar
Wunderink, RG et al. (2018) Pneumococcal community-acquired pneumonia detected by serotype-specific urinary antigen detection assays. Clinical Infectious Disease 66, 15041510.CrossRefGoogle ScholarPubMed
Bradley, JS et al. (2011) The management of community-acquired pneumonia in infants and children older than 3 months of age: clinical practice guidelines by the paediatric infectious diseases society and the infectious diseases society of America. Clinical Infectious Disease 53, e25e76.CrossRefGoogle ScholarPubMed
Olarte, L et al. (2017) Pneumococcal pneumonia requiring hospitalization in US children in the 13-valent pneumococcal conjugate vaccine era. Clinical Infectious Disease 64, 16991704.CrossRefGoogle ScholarPubMed
Nakano, S et al. (2016) Serotypes, antimicrobial susceptibility, and molecular epidemiology of invasive and non-invasive Streptococcus pneumoniae isolates in paediatric patients after the introduction of 13-valent conjugate vaccine in a nationwide surveillance study conducted in Japan in 2012–2014. Vaccine 34, 6776.CrossRefGoogle Scholar
Ubukata, K et al. (2018) Effects of pneumococcal conjugate vaccine on genotypic penicillin resistance and serotype changes, Japan, 2010–2017. Emerging Infectious Disease 24, 20102020.CrossRefGoogle Scholar
Kawaguchiya, M, Urushibara, N and Kobayashi, N (2017) Multidrug resistance in non-PCV13 serotypes of Streptococcus pneumoniae in Northern Japan, 2014. Microbial Drug Resistance 23, 206214.CrossRefGoogle Scholar
Ubukata, K et al. (2018) Etiology of acute otitis media and characterization of pneumococcal isolates after introduction of 13-valent pneumococcal conjugate vaccine in Japanese Children. The Paediatric Infectious Disease Journal 37, 598604.CrossRefGoogle ScholarPubMed
Olarte, L et al. (2017) Emergence of multidrug-resistant pneumococcal serotype 35B among children in the United States. Journal of Clinical Microbiology 55, 724734.CrossRefGoogle ScholarPubMed
Hackel, M et al. (2013) Serotype prevalence and antibiotic resistance in Streptococcus pneumoniae clinical isolates among global populations. Vaccine 31, 48814887.CrossRefGoogle ScholarPubMed
Sheppard, C et al. (2016) Rise of multidrug-resistant non-vaccine serotype 15A Streptococcus pneumoniae in the United Kingdom, 2001 to 2014. Eurosurveillance 21, 30423.CrossRefGoogle ScholarPubMed
Cripps, AW (2010) Nontypeable Haemophilus influenzae And childhood pneumonia. PNG Medical Journal 53, 147150.Google ScholarPubMed
Suga, S et al. (2018) A nationwide population-based surveillance of invasive Haemophilus influenzae diseases in children after the introduction of the Haemophilus influenzae type b vaccine in Japan. Vaccine 36, 56785684.CrossRefGoogle ScholarPubMed
Shiro, H et al. (2015) Nationwide survey of the development of drug resistance in the paediatric field in 2000–2001, 2004, 2007, 2010, and 2012: evaluation of the changes in drug sensitivity of Haemophilus influenzae and patients' background factors. The Journal of Infectious Chemotherapy 21, 247256.CrossRefGoogle ScholarPubMed
Nagai, K et al. (2019) Antimicrobial susceptibility of Streptococcus pneumoniae, Haemophilus influenzae, and Moraxella catarrhalis clinical isolates from children with acute otitis media in Japan from 2014 to 2017. The Journal of Infectious Chemotherapy 25, 229232.CrossRefGoogle ScholarPubMed
Cherian, T, et al. (2005) Standardized interpretation of paediatric chest radiographs for the diagnosis of pneumonia in epidemiological studies. Bulletin of the World Health Organisation 83, 353359.Google Scholar
Figure 0

Fig. 1. Number of hospitalized paediatric children <5 years of age with CAP before and after PCV7/PCV13 introduction in Chiba City, Japan. Since the introduction of PCV in children, the incidence of hospitalised paediatric CAP in children aged <5 years has decreased. After PCV13 introduction, the incidence of hospitalised CAP children <5 years of age further declined. CAP, community-acquired pneumonia; PCV7, heptavalent pneumococcal conjugate vaccine; PCV13, 13-valent pneumococcal conjugate vaccine

Figure 1

Table 1. The incidence of hospitalized community-acquired pneumonia in children in Chiba city, Japan, before and after the introduction of PCV7 and PCV13

Figure 2

Fig. 2. The number of hospitalised paediatric children 5–15 years of age with CAP before and after PCV7/PCV13 introduction in Chiba City, Japan. After PCV13 introduction, the incidence of hospitalised CAP children 5–15 years of age declined. CAP, community-acquired pneumonia; PCV7, heptavalent pneumococcal conjugate vaccine; PCV13, 13-valent pneumococcal conjugate vaccine

Figure 3

Table 2. The characteristics of children with community-acquired pneumonia admitted to the four study hospitals after the introduction of PCV13

Figure 4

Table 3. Microorganisms isolated from blood and dominantly isolated from sputum samples of children with community-acquired pneumonia admitted to the four study hospitals

Figure 5

Fig. 3. Distribution of S. pneumoniae serotype isolated from blood and sputum of the paediatric inpatients with CAP. In the pre-PCV7 period, the most frequent serotypes were 6B, 23F and 19F in children. After introduction of PCV7, PCV7 serotypes dramatically decreased and the major serotypes changed to 19A, 6C, 15A and 15C. In the PCV13 period, of the PCV13 serotypes, a small number of serotypes 1, 3, 7F and 19A were isolated. Of the non-PCV13 serotypes, the dominant serotypes were 35B, 15A and 11A/E.

Figure 6

Table 4. PCV7/PCV13 serotypes of Streptococcus pneumoniae isolated from the blood or sputum as a proportion of all Streptococcus pneumoniae isolates in children with community-acquired pneumonia admitted to the four study hospitals, according to the year of admission

Figure 7

Table 5. Multilocus sequence typing analysis of Streptococcus pneumoniae strains isolated after the introduction of PCV13, by year

Figure 8

Fig. 4. Susceptibility of S. pneumoniae isolates from blood and sputum samples to penicillin G among CAP patients. The susceptibility to PCG recovered after PCV introduction. CAP, community-acquired pneumonia; PCG, penicillin G; PCV, pneumococcal conjugate vaccine

Figure 9

Table 6. Antimicrobial susceptibility of Streptococcus pneumoniae isolates from children with community-acquired pneumonia

Figure 10

Table 7. Antimicrobial susceptibility of Haemophilus influenzae isolates from children with community-acquired pneumonia