The primary endpoints of the study were antibody titers to yellow fever in mIU/mL and categories (seropositive: ERK inhibitor titer higher than
2.7 log10 mIU/mL or reciprocal dilution higher than 10). Seroconversion was defined as quadrupling of pre-vaccination antibodies against yellow fever. Serologic testing for rubella antibodies (ELISA, Enzygnost® Anti-Rubella-Virus/IgG, Dade Behring, Germany) and for mumps antibodies (ELISA, Enzygnost® Anti-Parotitis-Virus/IgG, Dade Behring, Germany) were performed at the Respiratory Virus Laboratory of Instituto Oswaldo Cruz (FIOCRUZ, Rio de Janeiro), and the results expressed in International Units per milliliter of serum (IU/mL). The primary endpoints for rubella were post-vaccination antibody titers in IU/mL and categories (non-reactive: <4.0 IU/mL; inconclusive: 4.0–6.5 IU/mL; reactive: >6.5 IU/mL). For mumps, sera with antibody titers ≥231 U/mL were considered reactive, implying that borderline CHIR-99021 order titers were considered seropositive. Both for rubella and for mumps, seroconversion was defined as seropositivity in subjects who were non-reactive before vaccination. The proportion of seroconversion, the
geometric mean titer (GMT) and proportion of adverse events after vaccination were compared across groups defined by types of yellow fever vaccine and interval between vaccinations. The statistical significance of differences in proportions was analyzed by chi-square test, whereas for the differences in the means of antibody
titer logarithms the Student’s t test was used. Reverse cumulative distribution plots were constructed to display the complete range of serologic data. The level of significance was 5%. Data were analyzed using SPSS version 13.0 (SPSS, Inc., Chicago, IL). The complete cohort (“intention-to-treat”) Bay 11-7085 for analysis of adverse events included children with data on reactogenicity, even those who failed to adhere to the study protocol. For the analysis of immunogenicity, the cohort consisted of all subjects randomized to YFV types, keeping subjects in the groups to which they were randomly assigned. The interaction of the MMR vaccine and yellow fever was evaluated by comparing the proportions of seroconversion for yellow fever in individuals in subgroups defined by the interval between vaccinations. Children without post-vaccination serological test, or who violated eligibility criteria were disregarded in “per-protocol analysis”. With this approach, analysis of immune response considered the vaccine actually administered, regardless of randomization group. The probability of seroconversion was adjusted for the covariates of interest (age, sex, pre-vaccination seropositivity, time between pre- and post-vaccination blood collection, and comorbidity) in a logistic regression model.