Maria Elena Flacco1, Lamberto Manzoli2, Annalisa Rosso3, Carolina Marzuillo3, Mauro Bergamini4, Armando Stefanati4, Rosario Cultrera4, Paolo Villari3, Walter Ricciardi5, John P A Ioannidis6, Despina G Contopoulos-Ioannidis7. 1. Department of Preventive Services, Local Health Authority of South Tyrol, Bolzano, Italy; Regional Healthcare Agency of Abruzzo, Pescara, Italy. 2. Regional Healthcare Agency of Abruzzo, Pescara, Italy; Department of Medical Sciences, University of Ferrara, Ferrara, Italy. Electronic address: lmanzoli@post.harvard.edu. 3. Department of Public Health and Infectious Diseases, Sapienza University of Rome, Rome, Italy. 4. Department of Medical Sciences, University of Ferrara, Ferrara, Italy. 5. Institute of Public Health, Catholic University of the Sacred Heart, Rome, Italy; Italian National Institute of Health, Rome, Italy. 6. Stanford Prevention Research Center, Department of Medicine and Department of Health Research and Policy, Stanford University, Stanford, CA, USA; Meta-Research Innovation Center at Stanford (METRICS), Stanford University, Stanford, CA, USA; Department of Statistics, School of Humanities and Sciences, Stanford University, Stanford, CA, USA. 7. Meta-Research Innovation Center at Stanford (METRICS), Stanford University, Stanford, CA, USA; Department of Pediatrics, Division of Infectious Diseases, School of Medicine, Stanford University, Stanford, CA, USA.
Abstract
BACKGROUND: The multicomponent meningococcal serogroup B vaccine (4CMenB) has been licensed in more than 35 countries. However, uncertainties remain about the lowest number of doses required to induce satisfactory, persistent immune responses. We did a systematic review and meta-analysis to provide quantitative estimates for the immunogenicity, persistence of immunogenicity, and safety of 4CMenB vaccine in children and adolescents. METHODS: For this systematic review and meta-analyses (proportion, head to head, and network), we searched MEDLINE, Scopus, Embase, and ClinicalTrials.gov from database inception to June 30, 2017, for randomised trials that compared the immunogenicity or safety of the 4CMenB vaccine with its originator meningococcal B recombinant vaccine or routine vaccines in children or adolescents. For proportion meta-analyses, we also included single arm trials and follow-up studies of randomised controlled trials. Trials that assessed immunogenicity against at least one of four Neisseria meningitidis serogroup B reference strains (44-76/SL, 5/99, NZ98/254, and M10713) and included participants younger than 18 years who had received two or more doses of the 4CMenB vaccine were eligible for inclusion. We requested individual patient-level data from study authors and extracted data from published reports and online trial registries. We did meta-analyses to assess 4CMenB safety and immunogenicity against the four reference strains 30 days after a primary immunisation course (three doses for children, two doses for adolescents), 30 days after the primary course plus one booster dose (children only), 6 months or more after primary course, and 6 months or more after the booster dose. FINDINGS: 736 non-duplicate records were screened, and ten randomised trials and eight follow-on extension trials on 4CMenB met the inclusion criteria. In intention-to-treat analyses, the overall proportion of children and adolescents who achieved seroconversion 30 days after the primary course of 4CMenB was 92% (95% CI 89-95 [I2=95%, p<0·0001]) for the 44/76-SL strain, 91% (87-95 [I2=95%, p<0·0001]) for the 5/99 strain, 84% (77-90 [I2=97%, p<0·0001]) for the NZ98-254 strain, and 87% (68-99 [I2=97%, p<0·0001]) for the M10713 strain. 6 months after the primary course, the immunogenicity remained adequate to high against all three tested strains (5/99, 44/76-SL, and NZ98/254) in adolescents (≥77%), and against two of four strains (5/99 and 44/76-SL) in children (≥67%): the proportion of patients who achieved seroconversion substantially declined for M10713 (<50%) and NZ98/254 (<35%). A booster dose re-enhanced the proportion of patients who achieved seroconversion (≥93% for all strains). However, immunogenicity remained high 6 months after the booster dose for strains 5/99 (95%) and M10713 (75%) only, whereas the proportion of patients who achieved seroconversion against strains 44/76-SL and NZ98/254 returned to similar proportions recorded 6 months after the primary course (62% for 44/76-SL, 35% for NZ98/254). The incidence of potentially vaccine-related, acute serious adverse events in individuals receiving 4CMenB was low (5·4 per 1000 individuals), but was significantly higher than routine vaccines (1·2 per 1000 individuals). INTERPRETATION: 4CMenB has an acceptable short-term safety profile. The primary course is sufficient to achieve a satisfactory immune response within 30 days of vaccination. A booster dose is required for children to prolong the protection against strain M10713, and the long-term immunogenicity against strain NZ98/254 remains suboptimal. FUNDING: None.
BACKGROUND: The multicomponent meningococcal serogroup B vaccine (4CMenB) has been licensed in more than 35 countries. However, uncertainties remain about the lowest number of doses required to induce satisfactory, persistent immune responses. We did a systematic review and meta-analysis to provide quantitative estimates for the immunogenicity, persistence of immunogenicity, and safety of 4CMenB vaccine in children and adolescents. METHODS: For this systematic review and meta-analyses (proportion, head to head, and network), we searched MEDLINE, Scopus, Embase, and ClinicalTrials.gov from database inception to June 30, 2017, for randomised trials that compared the immunogenicity or safety of the 4CMenB vaccine with its originator meningococcal B recombinant vaccine or routine vaccines in children or adolescents. For proportion meta-analyses, we also included single arm trials and follow-up studies of randomised controlled trials. Trials that assessed immunogenicity against at least one of four Neisseria meningitidis serogroup B reference strains (44-76/SL, 5/99, NZ98/254, and M10713) and included participants younger than 18 years who had received two or more doses of the 4CMenB vaccine were eligible for inclusion. We requested individual patient-level data from study authors and extracted data from published reports and online trial registries. We did meta-analyses to assess 4CMenB safety and immunogenicity against the four reference strains 30 days after a primary immunisation course (three doses for children, two doses for adolescents), 30 days after the primary course plus one booster dose (children only), 6 months or more after primary course, and 6 months or more after the booster dose. FINDINGS: 736 non-duplicate records were screened, and ten randomised trials and eight follow-on extension trials on 4CMenB met the inclusion criteria. In intention-to-treat analyses, the overall proportion of children and adolescents who achieved seroconversion 30 days after the primary course of 4CMenB was 92% (95% CI 89-95 [I2=95%, p<0·0001]) for the 44/76-SL strain, 91% (87-95 [I2=95%, p<0·0001]) for the 5/99 strain, 84% (77-90 [I2=97%, p<0·0001]) for the NZ98-254 strain, and 87% (68-99 [I2=97%, p<0·0001]) for the M10713 strain. 6 months after the primary course, the immunogenicity remained adequate to high against all three tested strains (5/99, 44/76-SL, and NZ98/254) in adolescents (≥77%), and against two of four strains (5/99 and 44/76-SL) in children (≥67%): the proportion of patients who achieved seroconversion substantially declined for M10713 (<50%) and NZ98/254 (<35%). A booster dose re-enhanced the proportion of patients who achieved seroconversion (≥93% for all strains). However, immunogenicity remained high 6 months after the booster dose for strains 5/99 (95%) and M10713 (75%) only, whereas the proportion of patients who achieved seroconversion against strains 44/76-SL and NZ98/254 returned to similar proportions recorded 6 months after the primary course (62% for 44/76-SL, 35% for NZ98/254). The incidence of potentially vaccine-related, acute serious adverse events in individuals receiving 4CMenB was low (5·4 per 1000 individuals), but was significantly higher than routine vaccines (1·2 per 1000 individuals). INTERPRETATION: 4CMenB has an acceptable short-term safety profile. The primary course is sufficient to achieve a satisfactory immune response within 30 days of vaccination. A booster dose is required for children to prolong the protection against strain M10713, and the long-term immunogenicity against strain NZ98/254 remains suboptimal. FUNDING: None.
Authors: Sarah A Mbaeyi; Catherine H Bozio; Jonathan Duffy; Lorry G Rubin; Susan Hariri; David S Stephens; Jessica R MacNeil Journal: MMWR Recomm Rep Date: 2020-09-25
Authors: Rodolfo Villena; Marco Aurelio P Safadi; María Teresa Valenzuela; Juan P Torres; Adam Finn; Miguel O'Ryan Journal: Hum Vaccin Immunother Date: 2018-04-30 Impact factor: 3.452
Authors: Irene Rivero-Calle; Peter Francis Raguindin; Jose Gómez-Rial; Carmen Rodriguez-Tenreiro; Federico Martinón-Torres Journal: Infect Drug Resist Date: 2019-10-09 Impact factor: 4.003
Authors: Marzena Drozd-Dąbrowska; Katarzyna Topczewska; Marcin Korzeń; Anna Sałacka; Maria Ganczak Journal: Int J Environ Res Public Health Date: 2019-01-18 Impact factor: 3.390