Effect of Childhood Pneumococcal Conjugate Vaccination on Invasive Disease in Older Adults of 10 European Countries: Implications for Adult Vaccination

Overview

Journal Thorax

Date 2018 Oct 26

PMID 30355641

Citations 61

Authors

Germaine Hanquet

Pavla Krizova

Palle Valentiner-Branth

Shamez N Ladhani

J Pekka Nuorti

Agnes Lepoutre

Jolita Mereckiene

Mirjam Knol

Brita A Winje

Pilar Ciruela

Maria Ordobas

Marcela Guevara

Eisin McDonald

Eva Morfeldt

Jana Kozakova

Hans-Christian Slotved

Norman K Fry

Hanna Rinta-Kokko

Emmanuelle Varon

Mary Corcoran

Arie van der Ende

Didrik F Vestrheim

Carmen Munoz-Almagro

Pello Latasa

Jesus Castilla

Andrew Smith

Birgitta Henriques-Normark

Robert Whittaker

Lucia Pastore Celentano

Camelia Savulescu

Affiliations

Soon will be listed here.

Abstract

Background: Pneumococcal conjugate vaccines (PCVs) have the potential to prevent pneumococcal disease through direct and indirect protection. This multicentre European study estimated the indirect effects of 5-year childhood PCV10 and/or PCV13 programmes on invasive pneumococcal disease (IPD) in older adults across 13 sites in 10 European countries, to support decision-making on pneumococcal vaccination policies.

Methods: For each site we calculated IPD incidence rate ratios (IRR) in people aged ≥65 years by serotype for each PCV10/13 year (2011-2015) compared with 2009 (pre-PCV10/13). We calculated pooled IRR and 95% CI using random-effects meta-analysis and PCV10/13 effect as (1 - IRR)*100.

Results: After five PCV10/13 years, the incidence of IPD caused by all types, PCV7 and additional PCV13 serotypes declined 9% (95% CI -4% to 19%), 77% (95% CI 67% to 84%) and 38% (95% CI 19% to 53%), respectively, while the incidence of non-PCV13 serotypes increased 63% (95% CI 39% to 91%). The incidence of serotypes included in PCV13 and not in PCV10 decreased 37% (95% CI 22% to 50%) in six PCV13 sites and increased by 50% (95% CI -8% to 146%) in the four sites using PCV10 (alone or with PCV13). In 2015, PCV13 serotypes represented 20-29% and 32-53% of IPD cases in PCV13 and PCV10 sites, respectively.

Conclusion: Overall IPD incidence in older adults decreased moderately after five childhood PCV10/13 years in 13 European sites. Large declines in PCV10/13 serotype IPD, due to the indirect effect of childhood vaccination, were countered by increases in non-PCV13 IPD, but these declines varied according to the childhood vaccine used. Decision-making on pneumococcal vaccination for older adults must consider the indirect effects of childhood PCV programmes. Sustained monitoring of IPD epidemiology is imperative.

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