Persistence of hSBA titers elicited by the meningococcal serogroup B vaccine menB-FHbp for up to 4 years after a 2- or 3-dose primary series and immunogenicity, safety, and tolerability of a booster dose through 26 months.

BACKGROUND: To demonstrate extended protection against meningococcal serogroup B (MenB) disease after MenB-FHbp (bivalent rLP2086) vaccination, this study evaluated immunopersistence through 26 months following MenB-FHbp boosting after 2 or 3 primary doses in adolescents. STUDY DESIGN: This phase 3, open-label study was an extension of 3 phase 2 studies with participants aged 11-18 years randomized to receive primary MenB-FHbp vaccination following 1 of 5 dosing schedules or control. A booster dose was administered 48 months after the primary series. Immunopersistence through 48 months after the last primary dose (persistence stage) and 26 months postbooster (booster stage) was determined by serum bactericidal assays using human complement (hSBAs) against 4 vaccine-heterologous test strains. Safety evaluations included adverse events (AEs) and local and systemic reactions. RESULTS: Overall, 698 and 304 subjects enrolled in the persistence and booster stages, respectively. hSBA titers declined in all groups during 12 months postprimary vaccination, then remained stable through 48 months. One month postbooster, 93.4-100.0% of subjects achieved hSBA titers ≥ lower limit of quantitation against each test strain; percentages at 12 and 26 months postbooster were higher than at similar time points following primary vaccination. Primary and booster MenB-FHbp vaccinations were well tolerated, with ≤ 12.5% of subjects reporting AEs during each stage. The most common local (reported by 84.4-93.8% of subjects) and systemic (68.8-76.6%) reactions to the booster were injection site pain and fatigue and headache, respectively; ≤ 3.7% of subjects reported severe systemic events. CONCLUSION: Protective hSBA titers initially declined but were retained by many subjects for 4 years irrespective of primary MenB-FHbp vaccination schedule. Boosting at 48 months after primary vaccination was safe, well tolerated, and induced immune responses indicative of immunological memory that persisted through 26 months. Booster vaccination during late adolescence may prolong protection against MenB disease.

Evaluation of immunogenicity and safety of VARIVAX™ New Seed Process (NSP) in children.

Prior to availability of an effective vaccine, an estimated 4 million cases of varicella occurred annually in the United States, resulting in 10,000 hospitalizations and over 100 deaths. With the increased usage of a two-dose varicella vaccine (as recommended by the ACIP), approval of other VZV-containing products and the adoption of varicella vaccination in additional countries, the demand for VZV-containing vaccines has increased. This study (NCT02062502) evaluated the safety, tolerability, and immunogenicity of VARIVAX™ (VAR, varicella vaccine live) manufactured using a new seed manufacturing process (VARNSP) compared to the currently licensed VAR. Healthy children 12-23 months were randomized (1:1) into Group 1 (2 doses of VARNSP given concomitantly with M-M-R™ II, ∼3 months apart) versus  Group 2 (2 doses of VAR given concomitantly with M-M-R™ II, ∼3 months apart).  Serum samples collected prior to vaccination on Day 1 and 6 weeks Postdose 1 were tested for antibody to VZV using a glycoprotein enzyme-linked immunosorbent assay (gpELISA).  Safety was assessed Days 1 to 42 following each vaccination. Six weeks Postdose 1, the response rate (percent of subjects with VZV antibody titer ≥5 gpELISA units/mL) of VARNSP was non-inferior compared to VAR.  Vaccine-related adverse events (AEs) were comparable with the exception of measles-like rash, where a greater number of rashes were observed with VAR than VARNSP.  The 2 vaccination groups were comparable with incidence rates of AEs, injection-site AEs, vaccine-related AEs, systemic AEs, and serious AEs. This new process is an important innovation for the extreme demand of sustaining sufficient supplies of varicella vaccine to protect our communities against diseases caused by VZV.

A double blind, randomized, active controlled study to assess the safety, tolerability and immunogenicity of measles, mumps rubella, and varicella vaccine (MMRV) manufactured using an alternative process.

Vaccination against measles, mumps, rubella, and varicella is recommended for all children in the US. Limitations manufacturing Oka/Merck strain varicella-zoster virus have hampered the availability of the combination vaccine (MMRV) against these 4 viruses, which drove the need to investigate an alternative manufacturing process. Healthy children 12-to-23 months of age at 71 US sites were randomized (1:1) to receive MMRV manufactured using an alternative process (MMRVAMP) or the currently licensed MMRV. Subjects received 2 0.5 mL doses 3 months apart. Sera were collected before and 6 weeks after Dose-1. Adverse experiences (AEs) were collected for 42 d after each dose and serious AEs and events of special interest for 180 d after Dose-2. Overall, 706 subjects were randomized to MMRVAMP and 706 to MMRV and 698 and 702 received at least 1 dose of study vaccine, respectively. The risk difference in response rates and geometric mean concentrations of antibody to measles, mumps, rubella, and varicella viruses 6 weeks after Dose-1 met non-inferiority criteria for MMRVAMP versus, MMRV. Response rates met acceptability criteria for each virus, and the seroconversion rate to varicella-zoster virus was 99.5% in both groups. Vaccine-related AEs were mostly mild-to-moderate in intensity and somewhat more common after MMRVAMP. Febrile seizures occurred at similar rates in both groups during the first 42 d after each vaccine dose. MMRVAMP is non-inferior to MMRV and represents an important advancement in maintaining an adequate supply of vaccines against these diseases.

M-M-R(®)II manufactured using recombinant human albumin (rHA) and M-M-R(®)II manufactured using human serum albumin (HSA) exhibit similar safety and immunogenicity profiles when administered as a 2-dose regimen to healthy children.

Prior to 2006, M-M-R(®)II (measles, mumps, and rubella virus vaccine live) was manufactured using human serum albumin (HSA) and each dose of the vaccine contained a relatively small amount (≤0.3mg) of HSA. Because of specific regulatory requirements and limited suppliers of HSA acceptable for human use, there was a need to replace HSA with recombinant human albumin (rHA) to mitigate any potential risk to the availability of M-M-R(®)II. Two different formulations of M-M-R(®)II manufactured using either rHA or HSA were clinically evaluated for safety and immunogenicity when administered as a 2-dose regimen to healthy children 12-18 months and 3-4 years of age. Adverse events, including those indicative of a possible hypersensitivity reaction, were collected for 42 days after each dose. Antibodies to measles, mumps, and rubella were measured before and approximately 6 weeks after dose 1. Antibodies to rHA were measured before and approximately 6 weeks after dose 1 and dose 2. Antibody seroconversion rates to measles, mumps, and rubella were 97.0%, 99.5%, and 99.7%, respectively, for recipients of M-M-R(®)II with rHA and 97.2%, 97.9%, and 99.6%, respectively, for recipients of M-M-R(®)II with HSA, and geometric mean titers to all 3 vaccine viral antigens were comparable between the 2 vaccination groups. The proportions of subjects who reported adverse events, including those suggestive of hypersensitivity reactions, after each dose of study vaccine were comparable between the 2 vaccination groups. No subject had detectable antibodies to rHA immediately prior to or following receipt of either the first or second dose of study vaccine. Given the comparable immunogenicity and safety profiles of both formulations, rHA is an acceptable replacement for HSA in the manufacture of M-M-R(®)II.

Impact of a birth dose of hepatitis B vaccine on the reactogenicity and immunogenicity of diphtheria-tetanus-acellular pertussis-hepatitis B-inactivated poliovirus-Haemophilus influenzae type b combination vaccination.

OBJECTIVES: To assess the impact of a birth dose of hepatitis B vaccine (HepB) on the reactogenicity and immunogenicity of a novel diphtheria-tetanus-acellular pertussis (DTaP)- HepB-inactivated poliovirus (IPV)/ type b (Hib) combination vaccine administered subsequently at 2, 4 and 6 months of age. METHODS: Neonates ( = 550) were randomized into two groups with regard to receipt of HepB at birth. All subjects in both groups received DTaP-HepB-IPV/Hib at 2, 4 and 6 months of age. Solicited local and general adverse events were recorded for 8 days after each dose. Antibodies to hepatitis B surface antigen were measured 1 month after the third dose of DTaP-HepB-IPV/Hib in a subset of 170 infants; titers of at least 10 mIU/ml were considered protective. RESULTS: The DTaP-HepB-IPV/Hib combination vaccine was well-tolerated in both groups. Of the infants who received a birth dose of HepB, 22.6% had severe (Grade 3) reactions after any of the three doses of DTaP-HepB-IPV/Hib combination vaccine compared with 23.2% of subjects who did not receive a birth dose of HepB (difference, -0.5%; 90% confidence interval, -7.4 to 6.1). Antibody to hepatitis B surface antigen titers were > or =10 mIU/ml for all tested infants. Geometric mean titers were 2996.2 and 1240.1 mIU/ml with and without a birth dose of HepB, respectively. CONCLUSIONS: A HepB birth dose does not increase the reactogenicity of a combination DTaP-HepB-IPV/Hib vaccine administered at 2, 4 and 6 months of age, and all tested subjects achieved protective anti-HBs titers (> or =10 mIU/ml), although geometric mean titers were higher when a birth dose of HepB was given.

Safety and immunogenicity of an inactivated quadrivalent influenza vaccine in children 6 months through 8 years of age.

BACKGROUND: Strains of 2 distinct influenza B lineages (Victoria and Yamagata) have cocirculated in the United States for over a decade, but trivalent influenza vaccines (TIVs) contain only 1 B-lineage strain. Each season, some or most influenza B disease is caused by the B lineage not represented in that season's TIV. Quadrivalent influenza vaccines (QIVs) containing a strain from each B lineage should resolve this problem. METHODS: This was a Phase III, randomized, multicenter trial in the United States among children 6 months to <9 years of age to evaluate the safety and immunogenicity of inactivated QIV compared with inactivated control TIVs containing opposite B-lineage strains. Participants were randomized at a ratio of approximately 4:1:1 to receive QIV, TIV containing a Victoria-lineage B strain or TIV containing a Yamagata-lineage B strain. Sera were collected pre- and 28-days post-final vaccination and safety was assessed for 6 months after the last injection. RESULTS: A total of 4363 participants were enrolled. QIV induced noninferior antibody responses to all A strains and corresponding B strains compared with the control TIVs and superior antibody responses to the noncorresponding B strain in each TIV. Rates of solicited reactions and unsolicited and serious adverse events were similar in all groups. CONCLUSIONS: This study demonstrated that QIV is safe and immunogenic among children 6 months to <9 years of age. These findings, along with data from 2 other studies of this QIV in adults, suggest that QIV should offer protection against both B lineages with a safety profile similar to TIV across all ages.

Safety of a combination diphtheria, tetanus toxoid, acellular pertussis, hepatitis B, and inactivated polio vaccine coadministered with a 7-valent pneumococcal conjugate vaccine and a Haemophilus influenzae type b conjugate vaccine.

The safety of DTaP-HepB-IPV vaccine coadministered with PCV and Hib was compared with separate administration of DTaP, HepB, IPV, Hib, and PCV at 2, 4, and 6 months of age. Healthy 2-month-old infants (N=1008) were randomized to the two groups. Following dose 1, there was no significant difference between the groups in the incidence of fever >101.3 degrees F. After each dose, the incidence of any fever (> or =100.4 degrees F) was significantly higher in the Combination Vaccine Group. The rate of fever >103.1 degrees F was < or =1.4% in both groups after any of the doses. Medical advice visits for fever were infrequent in both groups (< or =1.2%). DTaP-HepB-IPV was safe and well tolerated when coadministered with PCV and Hib.

Immunogenicity and safety of an inactivated hepatitis A vaccine administered concomitantly with diphtheria-tetanus-acellular pertussis and haemophilus influenzae type B vaccines to children less than 2 years of age.

OBJECTIVE: The availability of a hepatitis A virus vaccine for infant and early childhood immunization could reduce the transmission of hepatitis A virus in the United States. This study evaluated the immunogenicity and safety of a hepatitis A virus vaccine (Havrix, GlaxoSmithKline Biologicals, Rixensart, Belgium) administered concomitantly with diphtheria-tetanus-acellular pertussis and Haemophilus influenzae type b vaccines to children < 2 years. METHODS: In this open, comparative, multicenter study, 1084 healthy children aged 11 to 25 months were allocated (4:4:3:3:4 ratio) to 5 treatment groups based on age and previous vaccination history. Subjects 11 to 13 months of age received 2 doses of hepatitis A virus vaccine 6 months apart (N = 243). Subjects aged 15 to 18 months received 2 doses of hepatitis A virus vaccine 6 months apart (N = 241); or hepatitis A virus vaccine, diphtheria-tetanus-acellular pertussis, and H influenzae type b at month 0 and the second dose of hepatitis A virus vaccine 6 months later (N = 183); or diphtheria-tetanus-acellular pertussis and H influenzae type b at month 0 and hepatitis A virus vaccine at months 1 and 7 (N = 175). Subjects 23 to 25 months of age received hepatitis A virus vaccine at months 0 and 6 (N = 242). Immune responses were measured at baseline and 30 days after vaccine doses, and solicited and unsolicited adverse events were collected. RESULTS: After 2 doses of hepatitis A virus vaccine, all of the subjects in all of the groups were seropositive. Coadministration of hepatitis A virus vaccine with diphtheria-tetanus-acellular pertussis and H influenzae type b vaccines did not impact the immunogenicity of the 3 vaccines, except for the antipertussis toxoid vaccine response, which was slightly decreased. Hepatitis A virus vaccine was well tolerated in children 11 to 25 months of age. CONCLUSION: The administration of 2 doses of hepatitis A virus vaccine on a 0- and 6-month schedule starting at 11 to 13 months of age or at 15 to 18 months of age was as immunogenic and well tolerated as the administration of 2 doses in children 2 years of age. Immune responses to diphtheria-tetanus-acellular pertussis and H influenzae type b either given alone or coadministered with hepatitis A virus vaccine were similar except for antipertussis toxoid response.

Interchangeability of 2 diphtheria-tetanus-acellular pertussis vaccines in infancy.

OBJECTIVE: Currently, 4 diphtheria-tetanus-acellular pertussis (DTaP) vaccines are licensed for pediatric use in the United States, and 2 are commercially available. Although a single manufacturer's DTaP vaccine should be used for all 3 doses of the primary immunization series, some circumstances result in infants receiving DTaP vaccines from more than 1 manufacturer. The purpose of this study was to evaluate the safety and immunogenicity of a mixed sequence of 2 different DTaP vaccines. METHODS: In this multicenter, observer-blinded, controlled study, 449 infants were randomized into 1 of 3 groups (1:1:1 ratio) to receive Tripedia at 2, 4, and 6 months of age (control group); Tripedia at 2 and 4 months of age and Infanrix at 6 months of age; or Tripedia at 2 months and Infanrix at 4 and 6 months of age. Other vaccines were administered concurrently as separate injections according to the recommended childhood immunization schedule. Safety was monitored closely, and standard enzyme immunoassays were used to measure antibody concentrations to each antigen of the DTaP vaccines. RESULTS: The rates of injection-site and systemic adverse events were similar in each study group, and there were no clinically significant differences among groups after any dose. Infants in all 3 groups responded well to each antigen contained in both vaccines, with 97% to 100% seroprotection or vaccine response rates after the 3-dose primary series. Postvaccination geometric mean antibody concentrations and seroprotection or vaccine response rates to nearly all vaccine antigens were as high or higher in the mixed-sequence groups as in the control group. CONCLUSION: Initiating the primary immunization series with 1 or 2 doses of Tripedia and completing the 3-dose series with Infanrix is as safe and at least as immunogenic as administering Tripedia for all 3 doses.