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In Quebec, a pneumococcal conjugate vaccine (PCV) program was implemented in December 2004. The recommended schedule is 2+1 doses for low-risk infants. PCV-7 was first used (including catch-up for children <5 years of age), replaced by PCV10 in June 2009, and by PCV13 in January 2011 (no catch-up in both instances). From the beginning, >90% of children received the recommended number of doses. To assess the effectiveness of the three PCVs sequentially used to prevent invasive infectious disease (IPD). IPD cases in children 2–59 months during the years 2005–2013 were eligible. Controls were randomly identified in the provincial health insurance registry. Parents were interviewed and immunization records reviewed. Vaccine effectiveness (VE) was computed using multivariate logistic regression models. Out of 889 IPD cases reported, full participation was obtained for 516 cases (58%) and for 1767 controls. Against vaccine-type IPD, VE (≥1 dose) was 90% (82–95%) for PCV7, 97% (84–99%) for PCV10 and 86% (62–95%) for PCV13. Against 19A IPD, VE was, respectively, 42% (−9% to 69%), 71% (24–89%), and 74% (11–92%). VE (≥2 doses) against PCV13-type IPD was 85% for PCV10 (66–94%), 85% for PCV13 (55–94%), and 89% (58–97%) for a mixed PCV10+PCV13 schedule. All three PCV vaccines showed high level of protection against IPD caused by serotypes included in their formulation and there was a high level of cross-protection against 19A for PCV10. No substantial difference was seen between PCV10, PCV13, or a mixed PCV10+PCV13 schedule.

Streptococcus pneumoniae is a leading cause of bacterial pneumonia, meningitis, and sepsis in children worldwide. However, many countries lack national estimates of disease burden. Effective interventions are available, including pneumococcal conjugate vaccine and case management. To support local and global policy decisions on pneumococcal disease prevention and treatment, we estimated country-specific incidence of serious cases and deaths in children younger than 5 years. We measured the burden of pneumococcal pneumonia by applying the proportion of pneumonia cases caused by S pneumoniae derived from efficacy estimates from vaccine trials to WHO country-specific estimates of all-cause pneumonia cases and deaths. We also estimated burden of meningitis and non-pneumonia, non-meningitis invasive disease using disease incidence and case-fatality data from a systematic literature review. When high-quality data were available from a country, these were used for national estimates. Otherwise, estimates were based on data from neighbouring countries with similar child mortality. Estimates were adjusted for HIV prevalence and access to care and, when applicable, use of vaccine against Haemophilus influenzae type b. In 2000, about 14·5 million episodes of serious pneumococcal disease (uncertainty range 11·1–18·0 million) were estimated to occur. Pneumococcal disease caused about 826 000 deaths (582 000–926 000) in children aged 1–59 months, of which 91 000 (63 000–102 000) were in HIV-positive and 735 000 (519 000–825 000) in HIV-negative children. Of the deaths in HIV-negative children, over 61% (449 000 [316 000–501 000]) occurred in ten African and Asian countries. S pneumoniae causes around 11% (8–12%) of all deaths in children aged 1–59 months (excluding pneumococcal deaths in HIV-positive children). Achievement of the UN Millennium Development Goal 4 for child mortality reduction can be accelerated by prevention and treatment of pneumococcal disease, especially in regions of the world with the greatest burden. GAVI Alliance and the Vaccine Fund.

Vaccine-serotype (VT) invasive pneumococcal disease (IPD) rates declined substantially following introduction of 7-valent pneumococcal conjugate vaccine (PCV7) into national immunization programs. Increases in non-vaccine-serotype (NVT) IPD rates occurred in some sites, presumably representing serotype replacement. We used a standardized approach to describe serotype-specific IPD changes among multiple sites after PCV7 introduction. Of 32 IPD surveillance datasets received, we identified 21 eligible databases with rate data ≥ 2 years before and ≥ 1 year after PCV7 introduction. Expected annual rates of IPD absent PCV7 introduction were estimated by extrapolation using either Poisson regression modeling of pre-PCV7 rates or averaging pre-PCV7 rates. To estimate whether changes in rates had occurred following PCV7 introduction, we calculated site specific rate ratios by dividing observed by expected IPD rates for each post-PCV7 year. We calculated summary rate ratios (RRs) using random effects meta-analysis. For children <5 years old, overall IPD decreased by year 1 post-PCV7 (RR 0.55, 95% CI 0.46-0.65) and remained relatively stable through year 7 (RR 0.49, 95% CI 0.35-0.68). Point estimates for VT IPD decreased annually through year 7 (RR 0.03, 95% CI 0.01-0.10), while NVT IPD increased (year 7 RR 2.81, 95% CI 2.12-3.71). Among adults, decreases in overall IPD also occurred but were smaller and more variable by site than among children. At year 7 after introduction, significant reductions were observed (18-49 year-olds [RR 0.52, 95% CI 0.29-0.91], 50-64 year-olds [RR 0.84, 95% CI 0.77-0.93], and ≥ 65 year-olds [RR 0.74, 95% CI 0.58-0.95]). Consistent and significant decreases in both overall and VT IPD in children occurred quickly and were sustained for 7 years after PCV7 introduction, supporting use of PCVs. Increases in NVT IPD occurred in most sites, with variable magnitude. These findings may not represent the experience in low-income countries or the effects after introduction of higher valency PCVs. High-quality, population-based surveillance of serotype-specific IPD rates is needed to monitor vaccine impact as more countries, including low-income countries, introduce PCVs and as higher valency PCVs are used. Please see later in the article for the Editors' Summary.

•PCV10 reduced IPD caused by vaccine serotypes of Streptococcus pneumoniae.•PCV10 reduced IPD by vaccine serotypes in the non-targeted population.•IPD by serotypes 3, 6C, and 19A increased after the introduction of PCV10. In March 2010, the 10-valent pneumococcal conjugate vaccine (PCV10) was introduced into the routine immunization program in Brazil. We describe the pneumococcal serotypes that caused invasive pneumococcal diseases (IPD) before and after the introduction of PCV10 using data from a national laboratory-based surveillance system. We compared the prevalence of vaccine types (VT) and non-vaccine types (NVT) of Streptococcus pneumoniae in three periods, pre-PCV10 (January/2005-December/2009), early post-PCV10 (January/2010-December/2013), and late post-PCV10 (January/2014-December/2015), by episode in meningitis and non-meningitis cases and by age group. Changes in serotype prevalence in the early and late post-PCV10 periods were determined using pre-PCV10 period as a reference. A total of 8971 IPD isolates from patients aged 2 months to 99 years were analyzed. In the late post-PCV10 period, the VT-IPD reduction in the 2-month to 4-year age group was 83.4% for meningitis and 87.4% for non-meningitis cases; in the age groups 5–17 years, 18–64 years, and ≥65 years, VT declined by 56.1%, 54.1%, and 47.4%, respectively, in meningitis cases, and by 60.9%, 47.7%, and 53.4%, respectively, in non-meningitis cases. NVT-IPD increased throughout the study period, driven mainly by serotypes 3, 6C, and 19A, which remained the predominant types causing IPD in the late post-PCV10 period. We observed direct and indirect PCV10 protection against IPD caused by VT and a shift in the distribution of serotypes 5 years after the introduction of PCV10. Continued IPD surveillance is needed to evaluate the sustainability of the high prevalence of serotypes 3, 6C, and 19A, which were not included in PCV10.

Background. The impact of 13-valent pneumococcal conjugate vaccine (PCV13) on pneumococcal meningitis (PM) in US children is unknown. We compared the serotype distribution, antibiotic susceptibility, hospital course, and outcomes of children with PM 3 years before and 3 years after the introduction of PCV13. Methods. We identified patients ≤18 years of age with PM at 8 children's hospitals in the United States. Pneumococcal isolates were collected prospectively. Serotyping and antibiotic susceptibility were performed in a central laboratory. Clinical data were abstracted from medical records. Patients were divided into 3 subgroups: pre-PCV13 (2007–2009), transitional year (2010), and post-PCV13 (2011–2013). Categorical variables were analyzed by the χ2 test and continuous variables by the Mann–Whitney U test. Results. During the study period, 173 of 1207 episodes (14%) of invasive pneumococcal disease were identified as PM; 76 of 645 (12%) were during 2007–2009 and 69 of 394 (18%) during 2011–2013 (50% increase; P = .03). The proportion of PCV13 serotype cases decreased from 54% in 2007–2009 to 27% in 2011–2013 (P = .001). Non-PCV13 serotype cases represented 73% of the isolates in 2011–2013. Isolates with ceftriaxone minimum inhibitory concentration ≥1 μg/mL decreased (13% to 3%) from 2007–2009 to 2011–2013 (P = .03). No significant differences were identified for hospital course or outcome, with the exception that a greater proportion of patients had subdural empyema and hemiparesis in 2011–2013. Conclusions. After the introduction of PCV13, the number of cases of PM in children remained unchanged compared with 2007–2009, although the proportion of PCV13 serotypes decreased significantly. Serotype 19A continued to be the most common serotype in 2011–2013. Antibiotic resistance decreased significantly. Morbidity and case-fatality rate due to PM remain substantial.

Streptococcus pneumoniae is an important cause of bacterial meningitis. Since the introduction of the heptavalent pneumococcal conjugate vaccine PCV7, rates of pneumococcal meningitis have decreased substantially in the United States, from 1.13 cases to 0.79 case per 100,000 persons between 1998–1999 and 2004–2005; rates of disease from serotypes covered by the vaccine decreased the most, and rates from those not covered increased. Since the introduction of the heptavalent pneumococcal conjugate vaccine PCV7, rates of pneumococcal meningitis have decreased substantially in the United States, from 1.13 cases to 0.79 case per 100,000 persons between 1998–1999 and 2004–2005. Streptococcus pneumoniae is the most common cause of bacterial meningitis in the United States and many countries worldwide. 1 – 4 Despite effective antimicrobial therapy, pneumococcal meningitis remains highly lethal and has substantial long-term sequelae. 4 , 5 The pediatric heptavalent pneumococcal conjugate vaccine (PCV7; Prevnar, Wyeth) has had a major effect on the incidence of pneumococcal disease in the United States. 6 PCV7 not only protects immunized children from pneumococcal disease 7 – 11 but also provides protection to nonimmunized children and adults through herd immunity, resulting from reduced transmission of S. pneumoniae from immunized children. 8 , 10 , 12 , 13 Licensed in 2000, PCV7 is recommended by . . .

In 2013, Burkina Faso introduced 13-valent pneumococcal conjugate vaccine (PCV13) into the routine childhood immunization program, to be administered to children at 8, 12, and 16 weeks of age. We evaluated the impact of PCV13 on pneumococcal meningitis. Using nationwide surveillance, we gathered demographic/clinical information and cerebrospinal fluid (CSF) results for meningitis cases. Pneumococcal cases were confirmed by culture, polymerase chain reaction (PCR), or latex agglutination; strains were serotyped using PCR. We compared annual incidence (cases per 100 000) 4 years after PCV13's introduction (2017) to average pre-PCV13 incidence (2011-2013). We adjusted incidence for age and proportion of cases with CSF tested at national laboratories. In 2017, pneumococcal meningitis incidence was 2.7 overall and 10.5 (<1 year), 3.8 (1-4 years), 3.5 (5-14 years), and 1.4 (≥15 years) by age group. Compared to 2011-2013, PCV13-serotype incidence was significantly lower among all age groups, with the greatest decline among children aged <1 year (77%; 95% confidence interval [CI], 65%-84%). Among all ages, the drop in incidence was larger for PCV13 serotypes excluding serotype 1 (79%; 95% CI, 72%-84%) than for serotype 1 (52%; 95% CI, 44%-59%); incidence of non-PCV13 serotypes also declined (53%; 95% CI, 37%-65%). In 2017, 45% of serotyped cases among all ages were serotype 1 and 12% were other PCV13 serotypes. In Burkina Faso, meningitis caused by PCV13 serotypes continues to decrease, especially among young children. However, the concurrent decline in non-PCV13 serotypes and short pre-PCV13 observation period complicate evaluation of PCV13's impact. Efforts to improve control of serotype 1, such as switching from a 3 + 0 schedule to a 2 + 1 schedule, may improve overall control of pneumococcal meningitis in this setting.

•Before and after PCV13 implementation, the ST relationship between carriage and IPD was investigated.•In children <2 years old, 569 IPD and 355 Sp isolated from 1212 healthy were compared.•Before PCV13, 5 serotypes: 7F, 3, 1, 24F, and 19A had high invasive disease potential.•After PCV13, only 2 serotypes: 24F and 12F had high invasive disease potential. Changes in serotype distribution have been induced after pneumococcal conjugate vaccines (PCV) implementation, and non-vaccine serotypes are now circulating. Among these latter serotypes, we aimed to distinguish those with high invasive disease potential before (2008–2009) and after PCV13 implementation (2012–2013). Invasive pneumococcal disease (IPD) serotypes isolated from children 6 to 24 months were compared with nasopharyngeal-colonizing serotypes in healthy children. To assess the invasive potential of a given serotype, odds ratios (ORs) were calculated. For each serotype, OR >1 indicated increased probability of association with IPD and OR <1 decreased probability. In 2008/2009 and 2012/2013, 355 pneumococci were isolated from 1212 healthy children and from 569 IPD, including 166 meningitis, 114 pneumonia, and 289 other IPDs. In period 1, serotypes 7F, 3, 1, 24F, and 19A showed highly significant invasive disease potential whereas in period 2, only serotype 24F was associated with a significant high OR (6.6 [95% CI 2.6; 16.2]). Of note, for serotype 12F, OR could not be calculated because of no carrier recorded, however, if there had been a single 12F carrier, the OR would be among the highest, in period 2, 15.7 [95% 3.4; 73.0]). Only two serotypes appeared negatively associated with IPD, 11A and 23B in the period 2 as compared with nine in period 1. In the second period, pneumococcal penicillin non-susceptible isolates were mostly represented by serotypes 19A, 15A, 19F, 35B and 24F both in carriers and IPD. Only one strain was resistant to penicillin with MIC=4μg/ml (serotype 19A) during the first period. In children <2 years old, compared to the previous period, the number of serotypes having a high disease potential decreased after PCV13 implementation, only two non-vaccine serotypes, 24F and 12F, had high invasive disease potential.

•PCV13 reduced the incidence pneumococcal meningitis in children in Madrid.•The reduction was mainly due to a decrease of those cases caused by serotype 19A.•Isolates nonsusceptible to cefotaxime almost disappeared after PCV13 use.•A shift of pneumococcal meningitis towards older ages occurred after PCV13 vaccination.•Case fatality rate and sequelae were similar before and after the use of PCV13. To evaluate the impact of 13-valent pneumococcal conjugate vaccine on pneumococcal meningitis in children. Children younger than 15years of age attending 27 hospitals in the Region of Madrid with confirmed pneumococcal meningitis were identified in a prospective surveillance study, from 2007 to 2015. Clinical data, neurological sequelae, pneumococcal vaccination status, serotyping and antibiotic susceptibility were recorded. One hundred and four cases of pneumococcal meningitis were identified, 63 during the period of routine 7-valent pneumococcal conjugate vaccine immunisation (May 2007–April 2010) and 41 during the period of 13-valent pneumococcal conjugate vaccine immunisation (May 2010–April 2015). When both periods were compared, a 62% (95% CI: 45–75%) decrease in the incidence of pneumococcal meningitis was observed, from 2.19 cases per 100,000 inhabitants in the PCV7 period to 0.81 per 100,000 inhabitants in the PCV13 period (p=0.0001), mainly due to an 83% (95% CI: 30–96%) reduction in cases caused by serotype 19A. Isolates not susceptible to cefotaxime (MIC>0.5μg/L) decreased from 27% to 8%, (p=0.02). Mean patient ages rose from 28.7months to 38.5months (p<0.05). Case fatality rate across both periods was 5%. An unfavourable outcome (death or neurological sequelae) occurred in 27% of patients, while the rate was similar in both periods. There was no increase in meningitis caused by pneumococcal serotypes not included in 13-valent pneumococcal conjugate vaccine throughout the years of the study. Immunisation with 13-valent pneumococcal conjugate vaccine has reduced the rate of pneumococcal meningitis in children less than 15years, with a near-elimination of cefotaxime-resistant isolates, but morbidity has remained unchanged. A shift of pneumococcal meningitis towards slightly higher age groups was also observed.

•Reactive vaccination could be beneficial for pneumococcal meningitis.•Using modelling, we examine outbreak control measures on past Spn outbreaks.•Our modelling analysis considers five past African Meningitis Belt outbreaks.•Both reactive and routine vaccination are considered on a long timeframe. Pneumococcal meningitis outbreaks occur sporadically in the African meningitis belt. Outbreak control guidelines and interventions are well established for meningococcal but not pneumococcal meningitis. Mathematical modelling is a useful tool for assessing the potential impact of different pneumococcal control strategies. This work aimed to estimate the impact of reactive vaccination with pneumococcal conjugate vaccine (PCV) had it been implemented in past African meningitis belt outbreaks and assess their efficiency relative to existing routine infant immunisation with PCV. Using recent pneumococcal meningitis outbreaks in Burkina Faso, Chad, and Ghana as case studies, we investigated the potential impact of reactive vaccination. We calculated the number needed to vaccinate to avert one case (NNV) in each outbreak setting and over all outbreaks and compared this to the NNV for existing routine infant vaccination. We extended previous analyses of reactive vaccination by considering longer-term protection in vaccinees over five years, incorporating a proxy for indirect effects. We found that implementing reactive vaccination in previous pneumococcal meningitis outbreaks could have averted up to 10–20 % of outbreak cases, with the biggest potential impact in Brong Ahafo, Ghana (2015–2016) and Goundi, Chad (2009). The NNV, and hence the value of reactive vaccination, varied greatly. ‘Large’ (80 + cumulative modelled cases per 100,000 population) and/or ‘prolonged’ (exceeding a response threshold of 10 suspected cases per 100,000 per week for four weeks or more) outbreaks had NNV estimates under 10,000. For routine infant vaccination with PCV, the estimated NNV ranged from 3,100–5,600 in Burkina Faso and 1,500–2,600 in Ghana. This analysis provides evidence to inform the design of pneumococcal meningitis outbreak response guidelines. Countries should consider reactive vaccination in each outbreak event, together with maintaining routine infant vaccination as the primary intervention to reduce pneumococcal disease burden and outbreak risk.