Mathematical modeling of pneumococcal transmission dynamics in response to PCV13 infant vaccination in Germany predicts increasing IPD burden due to serotypes included in next-generation PCVs

INTRODUCTION: Two next-generation pneumococcal conjugate vaccines (PCVs), a 15- and a 20-valent PCV (PCV15 and PCV20), have recently been licensed for use in adults, and PCV15 has also been licensed in children. We developed a dynamic transmission model specific for Germany, with the aim to predict...

Descripción completa

Detalles Bibliográficos
Autores principales: Horn, Matthias, Theilacker, Christian, Sprenger, Ralf, von Eiff, Christof, Mahar, Ernestine, Schiffner-Rohe, Julia, Pletz, Mathias W., van der Linden, Mark, Scholz, Markus
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2023
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9931105/
https://www.ncbi.nlm.nih.gov/pubmed/36791091
http://dx.doi.org/10.1371/journal.pone.0281261
_version_ 1784889173740617728
author Horn, Matthias
Theilacker, Christian
Sprenger, Ralf
von Eiff, Christof
Mahar, Ernestine
Schiffner-Rohe, Julia
Pletz, Mathias W.
van der Linden, Mark
Scholz, Markus
author_facet Horn, Matthias
Theilacker, Christian
Sprenger, Ralf
von Eiff, Christof
Mahar, Ernestine
Schiffner-Rohe, Julia
Pletz, Mathias W.
van der Linden, Mark
Scholz, Markus
author_sort Horn, Matthias
collection PubMed
description INTRODUCTION: Two next-generation pneumococcal conjugate vaccines (PCVs), a 15- and a 20-valent PCV (PCV15 and PCV20), have recently been licensed for use in adults, and PCV15 has also been licensed in children. We developed a dynamic transmission model specific for Germany, with the aim to predict carriage prevalence and invasive pneumococcal disease (IPD) burden for serotypes included in these vaccines. METHODS: The model allows to follow serotype distributions longitudinally both in the absence and presence of PCV vaccinations. We considered eight age cohorts and seven serotype groups according to the composition of different pneumococcal vaccines. This comprises the additional serotypes contained in PCV15 and PCV20 but not in PCV13. RESULTS: The model predicted that by continuing the current vaccine policy (standard vaccination with PCV13 in children and with PPSV23 in adults) until 2031, IPD case counts due to any serotype in children <2 years of age will remain unchanged. There will be a continuous decrease of IPD cases in adults aged 16-59y, but a 20% increase in adults ≥60y. Furthermore, there will be a steady decrease of the proportion of carriage and IPD due to serotypes included in PCV7 and PCV13 over the model horizon and a steady rise of non-PCV13 serotypes in carriage and IPD. The highest increase for both pneumococcal carriage and absolute IPD case counts was predicted for serotypes 22F and 33F (included in both PCV15 and PCV20) and serotypes 8, 10A, 11A, 12F, and 15B (included in PCV20 only), particularly in older adults. Between 2022 and 2031, serotypes included in PCV20 only are expected to cause 19.7–25.3% of IPD cases in adults ≥60y. CONCLUSIONS: We conclude that introduction of next-generation PCVs for adults may prevent a substantial and increasing proportion of adult IPDs, with PCV20 having the potential to provide the broadest protection against pneumococcal disease.
format Online
Article
Text
id pubmed-9931105
institution National Center for Biotechnology Information
language English
publishDate 2023
publisher Public Library of Science
record_format MEDLINE/PubMed
spelling pubmed-99311052023-02-16 Mathematical modeling of pneumococcal transmission dynamics in response to PCV13 infant vaccination in Germany predicts increasing IPD burden due to serotypes included in next-generation PCVs Horn, Matthias Theilacker, Christian Sprenger, Ralf von Eiff, Christof Mahar, Ernestine Schiffner-Rohe, Julia Pletz, Mathias W. van der Linden, Mark Scholz, Markus PLoS One Research Article INTRODUCTION: Two next-generation pneumococcal conjugate vaccines (PCVs), a 15- and a 20-valent PCV (PCV15 and PCV20), have recently been licensed for use in adults, and PCV15 has also been licensed in children. We developed a dynamic transmission model specific for Germany, with the aim to predict carriage prevalence and invasive pneumococcal disease (IPD) burden for serotypes included in these vaccines. METHODS: The model allows to follow serotype distributions longitudinally both in the absence and presence of PCV vaccinations. We considered eight age cohorts and seven serotype groups according to the composition of different pneumococcal vaccines. This comprises the additional serotypes contained in PCV15 and PCV20 but not in PCV13. RESULTS: The model predicted that by continuing the current vaccine policy (standard vaccination with PCV13 in children and with PPSV23 in adults) until 2031, IPD case counts due to any serotype in children <2 years of age will remain unchanged. There will be a continuous decrease of IPD cases in adults aged 16-59y, but a 20% increase in adults ≥60y. Furthermore, there will be a steady decrease of the proportion of carriage and IPD due to serotypes included in PCV7 and PCV13 over the model horizon and a steady rise of non-PCV13 serotypes in carriage and IPD. The highest increase for both pneumococcal carriage and absolute IPD case counts was predicted for serotypes 22F and 33F (included in both PCV15 and PCV20) and serotypes 8, 10A, 11A, 12F, and 15B (included in PCV20 only), particularly in older adults. Between 2022 and 2031, serotypes included in PCV20 only are expected to cause 19.7–25.3% of IPD cases in adults ≥60y. CONCLUSIONS: We conclude that introduction of next-generation PCVs for adults may prevent a substantial and increasing proportion of adult IPDs, with PCV20 having the potential to provide the broadest protection against pneumococcal disease. Public Library of Science 2023-02-15 /pmc/articles/PMC9931105/ /pubmed/36791091 http://dx.doi.org/10.1371/journal.pone.0281261 Text en © 2023 Horn et al https://creativecommons.org/licenses/by/4.0/This is an open access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/) , which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
spellingShingle Research Article
Horn, Matthias
Theilacker, Christian
Sprenger, Ralf
von Eiff, Christof
Mahar, Ernestine
Schiffner-Rohe, Julia
Pletz, Mathias W.
van der Linden, Mark
Scholz, Markus
Mathematical modeling of pneumococcal transmission dynamics in response to PCV13 infant vaccination in Germany predicts increasing IPD burden due to serotypes included in next-generation PCVs
title Mathematical modeling of pneumococcal transmission dynamics in response to PCV13 infant vaccination in Germany predicts increasing IPD burden due to serotypes included in next-generation PCVs
title_full Mathematical modeling of pneumococcal transmission dynamics in response to PCV13 infant vaccination in Germany predicts increasing IPD burden due to serotypes included in next-generation PCVs
title_fullStr Mathematical modeling of pneumococcal transmission dynamics in response to PCV13 infant vaccination in Germany predicts increasing IPD burden due to serotypes included in next-generation PCVs
title_full_unstemmed Mathematical modeling of pneumococcal transmission dynamics in response to PCV13 infant vaccination in Germany predicts increasing IPD burden due to serotypes included in next-generation PCVs
title_short Mathematical modeling of pneumococcal transmission dynamics in response to PCV13 infant vaccination in Germany predicts increasing IPD burden due to serotypes included in next-generation PCVs
title_sort mathematical modeling of pneumococcal transmission dynamics in response to pcv13 infant vaccination in germany predicts increasing ipd burden due to serotypes included in next-generation pcvs
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9931105/
https://www.ncbi.nlm.nih.gov/pubmed/36791091
http://dx.doi.org/10.1371/journal.pone.0281261
work_keys_str_mv AT hornmatthias mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs
AT theilackerchristian mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs
AT sprengerralf mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs
AT voneiffchristof mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs
AT maharernestine mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs
AT schiffnerrohejulia mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs
AT pletzmathiasw mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs
AT vanderlindenmark mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs
AT scholzmarkus mathematicalmodelingofpneumococcaltransmissiondynamicsinresponsetopcv13infantvaccinationingermanypredictsincreasingipdburdenduetoserotypesincludedinnextgenerationpcvs

Ejemplares similares