The immunogenicity and safety of 2 doses of pneumococcal conjugate vaccine (PCV) and 1 dose of pneumococcal polysaccharide vaccine (PPV) were evaluated in human immunodeficiency virus (HIV)-infected children receiving highly active antiretroviral therapy (HAART).Children 2 to <19 years, receiving stable HAART for > or =3-6 months, with HIV RNA PCR <30,000-60,000 copies/mL, received 2 doses of PCV and 1 dose of PPV at sequential 8-week intervals. Antibodies to pneumococcal serotypes (STs) 1 (PPV only) and 6B, 14, 19F, and 23F (PCV and PPV) were measured by ELISA.Two hundred sixty-three subjects were enrolled, of whom 225 met criteria for inclusion in the primary dataset. Antibody concentrations were low at entry, despite previous PPV in 75%. After vaccination, 76%-96% had concentrations > or =0.5 microg/mL and 62-88% > or =1.0 microg/mL to the 5 STs (geometric mean concentrations [GMCs] = 1.44-4.25 microg/mL). Incremental gains in antibody concentration occurred with each vaccine dose. Predictors of response included higher antibody concentration at entry, higher immune stratum (based on nadir CD4% before HAART and CD4% at screening), lower entry viral RNA, longer duration of the entry HAART regimen, and age <7 years. Response was more consistently related to screening CD4% than nadir CD4%. Seven percent had vaccine-related grade 3 events, most of which were local reactions.Two PCVs and 1 PPV were immunogenic and safe in HIV-infected children 2 to <19 years who were receiving HAART. Responses were suggestive of functional immune reconstitution. Immunologic status based on nadir and, especially, current CD4% and control of HIV viremia were independent determinants of response.
Quadrivalent human papillomavirus vaccine (QHPV) is > 95% effective in preventing infection with vaccine-type human papillomavirus. The safety and immunogenicity of QHPV are unknown in HIV-infected children.HIV-infected children (N = 126)-age > 7 to < 12 years, with a CD4% ≥ 15-and on stable antiretroviral therapy if CD4% was < 25-were blindly assigned to receive a dose of QHPV or placebo (3:1 ratio) at 0, 8, and 24 weeks. Adverse events were evaluated after each dose. Serum antibody against QHPV antigens was measured by a competitive Luminex immunoassay 1 month after the third QHPV dose.The safety profile of QHPV was similar in the 2 study arms and to that previously reported for QHPV recipients. QHPV did not alter the CD4% or plasma HIV RNA. Seroconversion to all 4 antigens occurred in > 96% of QHPV recipients and in no placebo recipients. Geometric mean titer was > 27 to 262 times greater than the seropositivity cutoff value, depending on the antigen, but was 30%-50% lower against types 6 and 18 than those of age-similar historical controls.QHPV was safe and immunogenic in this cohort of HIV-infected children. Efficacy trials are warranted.
To assess the 3-year anti-HBs persistence after primary vaccination with three-dose of hepatitis B vaccine (HepB) among normal and high-responder adults.A total of 24 237 healthy adults who had no histories of hepatitis B infection and hepatitis B vaccination, resided in local areas for more than six months and were aged 18-49 years were selected from 79 villages of Zhangqiu county, Shandong province, China in 2009. Blood samples were obtained and hepatitis B surface antigen (HBsAg), antibody against hepatitis B surface antigen (anti-HBs) and antibody against hepatitis B core antigen (anti-HBc) were detected using ELISA method. A total of 11 590 persons who were negative for all of these indicators were divided into four groups by cluster sampling method. Each group was vaccinated with one of the following four types of HepB at 0-1-6 months schedule: 20 μg HepB derived in Saccharomyces cerevisiae (HepB-SC), 20 μg HepB derived in Chinese hamster ovary cell (HepB-CHO), 10 μg HepB-SC and 10 μg HepB derived in Hansenula polymorpha (HepB-HP). Blood samples were collected one month after the third dose of primary immunization and tested for anti-HBs using chemiluminescence microparticle immunoassay (CMIA). During the follow-up to normal and high-responders, the following information was collected: the demographic characteristic (including age and gender), histories of hepatitis B infection, hepatitis B vaccination, smoking, drinking and chronic diseases. Blood samples were collected one month (T1) and three years after primary vaccination (T2) and anti-HBs, anti-HBc and HBsAg (if anti-HBs<10 mU/ml) were detected by CMIA. The risk factors associated with positive rate of anti-HBs and GMC of anti-HBs were identified by multiple logistic regression analysis and multifactor linear regression model analysis, respectively.A total of 4 677 normal and high-responders were identified. Among 4 677 participants, 2 014 (43.06%) were males and 2 663 (56.94%) were females. The positive rate was 100% at T1 and it decreased to 80.99% (3 788/4 677) three years after vaccination. The corresponding GMC was decreased from 1 413.48 (95%CI: 1 358.86-1 470.30) mU/ml to 60.33 (95%CI: 56.97-63.90) mU/ml. When comparing with those vaccinated 20 μg HepB-CHO, the significantly lower positive rate of anti-HBs three years after vaccination was observed in those vaccinated 20 μg HepB-SC, 10 μg HepB-SC and 10 μg HepB-HP. The OR (95%CI) was 0.65 (0.50-0.84), 0.52 (0.41-0.67) and 0.31 (0.28-0.45), respectively. The GMC of anti-HBs was also significantly lower among those vaccinated 20 μg HepB-SC, 10 μg HepB-SC and 10 μg HepB-HP. The b (95%CI) was -0.33 (-0.47- -0.20), -0.41 (-0.55- -0.28) and -0.78 (-0.92- -0.65), respectively. The GMC of anti-HBs in those aged 30-39 years old and 40-49 years old were lower than that in 18-29 years. The b (95%CI) was -0.31 (-0.47- -0.15) and -0.24 (-0.39- -0.09), respectively. When comparing with those whose anti-HBs titer was less than 999 mU/ml at T1, the significantly higher positive rate of anti-HBs three years after vaccination was observed in those whose anti-HBs titer was 1 000-1 999 mU/ml, those whose anti-HBs titer was 2 000-9 999 mU/ml and those whose anti-HBs titer was ≥10 000 mU/ml. The OR (95%CI) was 4.97 (3.80-6.49), 7.87 (16.19-10.01) and 9.67 (6.47-14.44), respectively. When comparing with those whose anti-HBs titer was ≤999 mU/ml at T1, the GMC of anti-HBs three years after vaccination was also significantly higher among those whose anti-HBs titer at T1 was 1 000-1 999 mU/ml, those whose anti-HBs titer at T1 was 2 000-2 999 mU/ml and those whose anti-HBs titer at T1 was ≥10 000 mU/ml. The b (95%CI) was 1.00 (0.87-1.14), 1.85 (1.74-1.97) and 3.28 (3.12-3.44), respectively. Four subjects showed HBsAg seroconversion and anti-HBc conversion rate was 4.68% at T2.Anti-HBs GMC decreased rapidly three years after primary vaccination among normal and high-responder adults, while the positive rate of anti-HBs still kept at a high level. The anti-HBs persistence after primary vaccination was associated with HepB type, age and GMC of anti-HBs one month after vaccination.
To study the immuno-persistence after inoculating with the domestic BRD II strain rubella vaccine among infants and young children.Hemagglutination inhibition (HI) antibody detection method was used to test on children at age 6 to 18 months without rubella infection or rubella vaccine immunization in Yantai city of Shandong province and were selected for the observation of the immuno-persistence against the domestic BRD II strain rubella vaccine from 1995 to 1998.Positive rates of HI antibody among children of 6, 7, 8, 9, 12 and 18 month-old of inoculation were 94.44%, 97.22%, 96.67%, 100.00%, 100.00%, 100.00% and 93.10%, 93.55%, 96.77%, 96.97%, 100.00%, 100.00% (P > 0.05), in one or two years respectively. The geometric mean reverse titers (GMRTs) were about 50% lower than that after 1 month after 1 year. Similar results were found that after 2 years GMRTs was about 50% lower than that after 1 year of inoculation. There was highly significant difference on GMRTs of HI antibody between infants with 6 to 7 month-olds (29.89) and young children with 8 to 18 month-olds (53.00) after 2 years of inoculation (t = 3.58, P < 0.001).The immunization schedule at the first dose for BRD II strain rubella vaccine should be started when the child is 8 month old. For the second dose, the immunization schedule used in other developed countries should be referred adopted in China.
The goals of this study were to optimize processing methods of cryopreserved peripheral blood mononuclear cells (PBMC) for immunological assays, identify acceptance parameters for the use of cryopreserved PBMC for functional and phenotypic assays, and to define limitations of the information obtainable with cryopreserved PBMC. Blood samples from 104 volunteers (49 human immunodeficiency virus-infected and 55 uninfected) were used to assess lymphocyte proliferation in response to tetanus, candida, and pokeweed-mitogen stimulation and to enumerate CD4(+) and CD8(+) T cells and T-cell subpopulations by flow cytometry. We determined that slowly diluting the thawed PBMC significantly improved viable cell recovery, whereas the use of benzonase improved cell recovery only sometimes. Cell storage in liquid nitrogen for up to 15 months did not affect cell viability, recovery, or the results of lymphocyte proliferation assays (LPA) and flow cytometry assays. Storage at -70 degrees C for < or =3 weeks versus storage in liquid nitrogen before shipment on dry ice did not affect cell viability, recovery, or flow cytometric results. Storage at -70 degrees C was associated with slightly higher LPA results with pokeweed-mitogen but not with microbial antigens. Cell viability of 75% was the acceptance parameter for LPA. No other acceptance parameters were found for LPA or flow cytometry assay results for cryopreserved PBMC. Under optimized conditions, LPA and flow cytometry assay results for cryopreserved and fresh PBMC were highly correlated, with the exception of phenotypic assays that used CD45RO or CD62L markers, which seemed labile to freezing and thawing.
Live-attenuated influenza vaccine (LAIV) prevents more cases of influenza in immune-competent children than the trivalent inactivated vaccine (TIV). We compared the antibody responses to LAIV or TIV in HIV-infected children.Blood and saliva obtained at enrollment, 4 and 24 weeks postimmunization from 243 HIV-infected children randomly assigned to TIV or LAIV were analyzed.Both vaccines increased the anti-influenza neutralizing antibodies at 4 and 24 weeks postimmunization. At 4 weeks postimmunization, TIV recipients had 2-fold to 3-fold higher neutralizing antibody titers than LAIV recipients, but the proportions of subjects with protective titers (≥ 1:40) were similar between treatment groups (96%-100% for influenza A and 81%-88% for influenza B). Both vaccines increased salivary homotypic IgG antibodies, but not IgA antibodies. Both vaccines also increased serum heterosubtypic antibodies. Among HIV-specific characteristics, the baseline viral load correlated best with the antibody responses to either vaccine. We used LAIV-virus shedding as a surrogate of influenza infection. Influenza-specific humoral and mucosal antibody levels were significantly higher in nonshedders than in shedders.LAIV and TIV generated homotypic and heterosubtypic humoral and mucosal antibody responses in HIV-infected children. High titers of humoral or mucosal antibodies correlated with protection against viral shedding.
Live-attenuated influenza vaccine (LAIV) prevents significantly more cases of influenza in immune-competent children than the trivalent inactivated vaccine (TIV). We compared the T cell responses to LAIV or TIV in HIV-infected children. IFN-gamma-ELISPOT for the three vaccine-contained influenza strains, two mismatched strains, and phytohemagglutinin (PHA), was performed at 0, 4, and 24 weeks postimmunization in 175 HIV-infected children randomly assigned to LAIV or TIV. The contribution of CD8 T cells to the influenza-specific response (CD8-ELISPOT) was evaluated by CD8-cell depletion. CD8 T cells accounted for > or =87% of the total influenza-ELISPOT. At baseline, total influenza-ELISPOT and CD8-ELISPOT values were similar or higher in TIV compared with LAIV recipients. Four and 24 weeks after TIV, total influenza-ELISPOT and CD8-ELISPOT results were significantly lower than baseline results (p < or = 0.001). Responses to PHA also tended to decrease at 4 weeks after TIV (p = 0.06), but rebounded to baseline levels at 24 weeks. Four weeks after LAIV, total influenza-ELISPOT responses to vaccine-contained strains A H3N2 and B significantly decreased. Other ELISPOT values at 4 weeks and all values at 24 weeks were similar to the baseline values. At 4 and 24 weeks, TIV compared to LAIV administration resulted in a significantly greater decrease in influenza-specific ELISPOT values for vaccine-contained influenza A strains (p < or = 0.02). Responses to PHA also tended to decrease more in TIV recipients (p = 0.07). HIV-infected children immunized with TIV had significant and persistent decreases in ELISPOT responses to influenza. LAIV administration suppressed ELISPOT responses less. The clinical significance of these findings deserves further study.
