More than 60 publications address the immune response to PCV7 or higher valency PCVs.¹⁹ In addition, 3 different groups have conducted systematic reviews of the effect of different PCV dosing schedules on immune response, including 2 meta-analyses of head-to-head trials of different schedules^20,21 and 1 analysis that used modeling to compare across studies.¹⁹ The 3 reviews all found that a primary series of 3 doses results in a better immune response than 2 doses for most serotypes, especially when measured right after the primary series, at about 6–7 months of age (Table 1). The differences are largest for serotypes 6B and 23F and relatively small for the other serotypes evaluated. For example, in the meta-analysis by Scott et al,²¹ which included 5 randomized-controlled, head-to-head trials of PCV schedules, the proportion of children achieving antibody levels ≥0.35 µg/mL (the correlate predicting efficacy and used for licensure purposes) for 3 primary doses was 21% higher compared with 2 primary doses for serotype 6B and 17% higher for serotype 23F, but no more than 7% higher for the other serotypes examined. When measured at about 1 year of age, before a booster dose was given, little difference has been seen in antibody concentrations in children who had received either 2 or 3 primary doses within the first 6 months of life.^19,22,23

Studies of the effects of different PCV schedules on pneumococcal colonization in general correlate with findings of immunogenicity studies, indicating that 3 primary doses reduce colonization better than 2 primary doses, at least when measured shortly after finishing the series. Results from these carriage studies are summarized in a systematic review.²⁴ The review identified 3 head-to-head clinical trials, conducted in Fiji, The Gambia and Israel, comparing colonization after the primary series among children who had received 2 doses to colonization among children receiving a 3-dose series.^25–28 In these studies, children who had received 3 primary doses had less colonization than those receiving 2 doses when measured a few months after completing the series. In Israel, the difference in colonization rates was driven by reductions in colonization with serotypes 6B and 6A in the group that had received 3 primary doses.^25,26 The systematic review also identified 10 clinical trials of various PCV formulations that compared prevalence of colonization in the first year of life following either a 2- or 3-dose primary series compared with no vaccination.²⁴ In all except 1 study of an investigational product, both 2- and 3-dose primary series reduced colonization of vaccine types compared with no vaccination.

Only 1 study has attempted to directly look for a difference in effectiveness between schedules of 2 or 3 primary doses for preventing a clinical disease endpoint, finding that any differences may be short lived.²⁹ In this study, the investigators evaluated the impact of 2 versus 3 primary PCV7 doses against incidence of lower respiratory tract infections in a general pediatric population in the United States. This propensity-score-matched case-cohort study found that children who received 3 primary doses had fewer hospitalizations for lower respiratory tract infections up to the time of receipt of a booster dose (9.5 admissions per 1000 children) than those who only received 2 primary doses (17.3 admissions per 1000 children). No difference was seen in the number of hospitalizations after the booster dose. In addition, this difference in admissions was only seen among children born in 2002; the authors hypothesized that by 2003, 3 years after introduction of PCV7, herd effects lessened the difference in risk between the 2 groups. A US study conducted shortly after PCV7 introduction suggested that cases of invasive disease caused by serotype 6A were overrepresented among children who had received only 1 or 2 doses compared with those who had received 3 or 4 doses.³⁰

In addition to the number of doses, the interval between doses in the primary series may be an important consideration. A trial by Goldblatt et al³¹ that evaluated timing between doses found that an interval of 2 months resulted in significantly better immune responses compared with a 1-month interval when starting vaccination at 2 months of age. In an analysis using multivariable modeling that included results from 145 study arms from 63 different immunogenicity studies, IgG geometric mean concentrations were generally higher for schedules using a 2-month interval compared with 1-month interval, but the difference was not significant when controlling for other factors.³² The age at first dose did not appear to be an important predictor of immune response in this model, and even doses given at birth have been shown in a clinical trial to be immunogenic and prime for doses given later.³³ These studies, taken together, suggest that if a 2-dose primary series is used in a PCV immunization program, an interval of 2 months rather than 1 month may help to maximize immune response to vaccination.

A booster dose is a powerful addition to a PCV schedule, in particular in terms of measured immune response. Giving a dose at about 1 year of age to children who have received a primary series results in a vigorous antibody response for most serotypes, and while immune responses following the primary series differ between those who received 2 or 3 primary doses, such differences disappear following a booster dose. Two systematic reviews have assessed antibody level concentrations after the booster dose.^19,21 In these, children who received 3 primary doses had, compared with children who received 2 primary doses, significantly better immune responses after the booster dose only for serotype 6B (Table 1); this was true whether measured by the proportion of children with antibody levels above the 0.35 µg/mL threshold for predicting efficacy²¹ or by geometric mean antibody concentrations.¹⁹ In addition, a booster dose generally results in higher antibody concentrations than does a primary series, regardless of whether antibody concentrations are measured approximately 1 month after a booster would be given (eg, 13 months) or when comparing results 1 month after the booster to those 1 month after the primary series.¹⁹ Antibody levels following a third dose of vaccine are higher when those doses are given as a 2+1 schedule than when given as a 3+0 schedule.¹⁹

While the benefits of a booster dose are clear when looking at immunological endpoints, few studies have explored the additional benefits a booster dose might provide for reducing carriage or clinical disease caused by vaccine serotypes. The best information comes from carriage studies, which suggest a benefit at least in the short term for a booster dose—but only if the primary series contained 2 doses rather than 3. In a study from Israel, differences in vaccine serotype colonization between those getting 2 primary doses compared with 3 primary doses (ie, measured after the primary series) were no longer seen after children in both the 2-dose and 3-dose arms received a booster dose with PCV7.^25,34 Of note, the study in Israel found that among those receiving a 3-dose primary schedule, there was no additional impact of a booster dose for further reducing VT colonization.²⁶ Another clinical trial, conducted in the Netherlands, demonstrated that a booster dose added to a 2-dose primary schedule increased the reduction in vaccine serotype colonization.³⁵ In that study, children who received PCV7 at 2 and 4 months (2+0) were compared to those getting doses at 2, 4 and 11 months (2+1) and unvaccinated controls. At 12, 18 and 24 months of age, children in both the 2+0 and 2+1 groups had significantly less vaccine-type carriage than unvaccinated controls. Children in the 2+1 group also had a significantly lower prevalence of vaccine-type carriage at 18 months (16%) than the 2+0 group (24%, P = 0.01); no difference was found at 24 months.

Taken together, these head-to-head studies of the effect of different schedules on colonization show that 3 primary doses reduce colonization for some serotypes (eg, 6B) better than 2 primary doses up until the time of a booster dose and that a booster dose provides additional protection against vaccine serotype carriage but only for children who have received a 2-dose primary series and not for children who already received 3 doses. These findings agree with the observational study discussed earlier of lower respiratory tract infections, which indicated that after a booster dose, no difference was found in hospitalizations for lower respiratory tract infections for children who had received either 2 or 3 primary doses.²⁹ These findings, however, are inconsistent with the 1 study of invasive disease that assessed whether a booster dose provided additional benefit; in this case-control study, a schedule of 3 primary doses plus a booster was significantly more effective than 3 primary doses alone.³⁶ Overall, booster doses are clearly beneficial for programs that use only 2 primary doses, but the clinical benefit of a booster dose remains uncertain for programs that achieve high coverage with 3 primary doses.

While examining the effects of the primary series and booster dose separately is useful for understanding differences between the biologic effects of various schedules, policy makers generally want to review the evidence in support of a complete schedule when making vaccine recommendations. The 3+1 schedule has more published evidence documenting its efficacy and effectiveness than the other schedules (Table 2), primarily because PCV7 was first used in the United States, a country that uses a 3+1 schedule. However, the body of evidence from clinical trials and observational studies supporting 3+0 and 2+1 schedules continues to grow. At this point, clinical trials have studied the 3+0 schedule more thoroughly than the 2+1 schedule, but more observational data are available for the 2+1 schedule than the 3+0 schedule. With few exceptions, studies show that all of these schedules are protective against carriage, pneumonia and invasive disease. Unfortunately, the different study methods do not readily allow direct comparison of the efficacy or effectiveness of 1 schedule to another.

Clinical trials using PCV7 were conducted in the United States and assessed a 3+1 schedule, with doses at 2, 4, 6 and 12–15 months.^5,6 Efficacy against invasive disease in these 2 prelicensure clinical trials ranged from 83% to 94%. The similar 9-valent vaccine formulation was evaluated in South Africa and The Gambia using 3+0 schedules with doses given at 6, 10 and 14 weeks; efficacy against invasive disease in these studies ranged from 71% to 83% among the general population of children and was a little lower (65%) among children with HIV in South Africa.^8,37 While reports of clinical trials for 3+1 and 3+0 schedules were published between 2000 and 2005, the first randomized trial demonstrating efficacy for the 2+1 schedule was not published until 2012. This cluster-randomized trial in Finland³⁸ evaluated both 2+1 schedule and 3+1 schedule for PCV10; the 2 schedules were each compared to a control group that received hepatitis B vaccine. Compared with 12 cases of vaccine-type invasive disease that occurred in the control group, no cases occurred among children receiving the 3+1 schedule (vaccine effectiveness 100%, 95% confidence interval (CI): 83–100%) and only 1 case occurred among children receiving the 2+1 schedule (vaccine effectiveness 92%, 95% CI: 58–100%). Note that even in the control arm, no children <1 year of age developed invasive disease, suggesting little opportunity to evaluate the potential for breakthrough disease before the booster dose in the 2+1 arm and emphasizing the low disease risk in this population.

Similar to the literature on invasive disease, clinical trials evaluating pneumonia prevention using different PCV schedules show that 3+0, 2+1 and 3+1 schedules all provide some protection. Randomized clinical trials of 3+0 schedules from the Philippines, South Africa and The Gambia have found reductions of 23–37% for chest X-ray confirmed pneumonia among vaccinated children.^8,37,39 In the United States, efficacy of a 3+1 schedule for PCV7 was 30% among children in Northern California⁴⁰ although efficacy was not demonstrated for hospitalized pneumonia episodes in a cluster-randomized trial among Navajo children.⁴¹ Preliminary data for PCV10 from Latin America suggest good efficacy for the 3+1 schedule (23%).⁴² A systematic review identified several trials that used clinical diagnosis of pneumonia rather than X-ray confirmed pneumonia for both 3+0 and 3+1 schedules; results for this less-specific endpoint were mixed.⁴³ Only 1 nonrandomized cohort study has evaluated efficacy of a 2+1 schedule, finding 65% (95% CI: 47–78%) less X-ray confirmed pneumonia among children whose parents chose PCV compared with unvaccinated children.⁴⁴

Observational studies conducted in settings where PCVs are routinely used also demonstrated PCV effectiveness against vaccine-type invasive disease and pneumonia for the 3- and 4-dose schedules. A systematic review of invasive disease studies identified 3 case-control studies and 3 indirect cohort analyses that evaluated PCV7 effectiveness (Table 2).⁴⁵ Five of 6 studies were done in settings using 3+1 schedules, although most of the studies were able to include information on children with incomplete schedules and evaluate effectiveness for schedules with fewer doses. Effectiveness estimates for schedules using 3 or more doses (76–100%) were similar to efficacy measured in clinical trials evaluating an invasive disease endpoint.

Surveillance studies have also shown benefits of PCV by documenting drops in disease rates or reported cases of invasive disease and pneumonia following PCV introduction (Table 2). In general, these studies show disease reductions at least as good as those demonstrated in clinical trials and results are often better because of indirect effects. A systematic review identified 26 such studies of invasive disease.⁴⁵ In nearly all studies regardless of schedule, rates of vaccine-type invasive disease dropped quickly after vaccine introduction. While few data are available from developing countries, preliminary data from Kilifi, Kenya indicate promising reductions in invasive disease using 3 doses at 6, 10 and 14 weeks with catch-up provided for children up to age 5 years.⁴⁶ To date, 33 surveillance-type studies have assessed a pneumonia or empyema endpoint after introduction into a routine immunization schedule.⁴³ While results of surveillance studies of pneumonia endpoints are less consistent than those evaluating invasive disease, in general, the findings suggest 2+1, 3+0 and 3+1 schedules are all effective.

Children with chronic illnesses such as HIV or sickle cell disease can have disease rates >20 times than those seen in healthy children.¹ While PCVs have been shown to provide protection for children with HIV,⁸ sickle cell disease⁴⁷ and chronic illnesses as a group,³⁶ some evidence suggests that PCVs may be somewhat less effective in children with chronic illnesses than in healthy children. In a large randomized-controlled clinical trial in South Africa, PCV9 used on a 3+0 schedule was shown to be efficacious against invasive pneumococcal disease caused by vaccine serotypes in both children with HIV and healthy children, although the point estimates were lower for HIV-infected children (65% vs. 83%).⁸ For the endpoint of radiographically confirmed pneumonia, point estimates of efficacy were 13% and 20% for HIV-infected and uninfected children, respectively, and the estimate was only statistically significant for HIV-uninfected children. In a case-control evaluation that was conducted in the United States, vaccine effectiveness for PCV7 serotypes was significantly lower among children with any chronic illness (as a group) than in healthy children (81% vs. 96%).³⁶ The recommended schedule in the United States was 3 primary doses plus a booster, although at the time of the study many children were missing doses because of a national shortage.

In Australia and North America, some populations of indigenous children have documented rates of pneumococcal disease up to 20 times higher than nonindigenous children.^48–51 PCV7 has been shown to be effective in these groups. Efficacy among the Navajo and Apache in the United States in a community–randomized-controlled clinical trial evaluating a 4-dose schedule of PCV7 was 82.6% against invasive disease,⁶ and invasive disease rates, nasopharyngeal carriage and pneumococcal transmission to adults decreased among Navajo and Alaska Natives after routine vaccination with PCV7 began.^52,53 In Australia, where a schedule of 3 primary doses of PCV7 was used with a booster of 23-valent pneumococcal polysaccharide vaccine (PPV23), vaccination did not reduce pneumonia rates among aboriginal children in the Northern Territories.⁵⁴

Whether using a schedule of 4 PCV doses will provide better protection than a schedule with 3 doses has not been evaluated for aboriginal children or for children with chronic illnesses. In spite of the lack of evidence, policy makers in some, but not all, countries that recommend either 3+0 or 2+1 schedules for the general population of children recommend 4-dose schedules for aboriginal or chronically ill children because of the higher risk of severe disease and complications compared with healthy children as well as concern over poor vaccine response.⁵⁵ While a schedule consisting of 3 primary doses of PCV and a booster dose of PPV23 may seem attractive for high-risk children because of the potential for preventing more serotypes, this schedule should be avoided because of the lack of effectiveness in aboriginal children in Australia⁵⁴ and the potential for inducing hyporesponsiveness.⁵⁶

Ideally, a PCV schedule should provide long-term protection through at least the period of childhood during which disease burden is significant. To date, however, few studies have attempted to assess the duration of protection that PCV provides. The best information comes from South Africa, where investigators continued to follow subjects from the randomized clinical trial to assess duration of efficacy of PCV9.⁵⁷ In this population, where PCV9 was given at 6, 10 and 14 weeks without a booster dose, efficacy against invasive disease caused by vaccine serotypes was similar at 6.2 years of follow-up (78%) compared with 2.3 years (83%) for HIV-uninfected children, but efficacy fell among HIV infected [65% at 2.3 years vs. 39% (95% CI: −7.8% to 65%) at 6.2 years]. The evidence from South Africa provides some reassurance that a schedule without a booster can provide long-term protection against disease, at least in healthy children. However, because of the reduction in effectiveness over time among HIV-infected children, policy makers in South Africa adopted a novel 3-dose schedule (doses at 6 and 14 weeks and 9 months), putting the last dose late in the first year of life in an attempt to improve longer term protection for these HIV-infected children.⁵⁶ More recently, South Africa recommended a 3+1 schedule for HIV-infected children, as data from a case-control study suggested the 2-dose primary series was not adequately protective (C. Cohen et al, unpublished data).

Concern over duration of protection of a 3-dose primary series without a booster comes in part from experience with Haemophilus influenzae type b (Hib) vaccine. In the United Kingdom, Hib vaccine was introduced on a 3+0 schedule with catch-up vaccination for all children <5 years of age, resulting in dramatic reductions in disease. However, several years into the program, the rate of Hib meningitis among older children and adults began to rise, likely as a result of a complex interplay between reductions in population level Hib colonization, lower immunogenicity of Hib in combination vaccines that included acellular instead of whole cell pertussis antigens and the Hib dosing regimen; in response, a booster dose was added to the schedule and rates subsequently decreased.⁵⁹ In the United States, where PCV7 has been used on a 4-dose schedule (2, 4, 6 and 12–15 months) since 2000, no increase in disease caused by vaccine serotypes has been noted in older children through 2012.⁶⁰

Duration of protection might be more of a concern for serotype 1 than for other PCV types, both because of the serotype’s tendency to cause more disease in older children and adults and because some data suggest that any protection provided by a primary series of this vaccine antigen may be short lived. In an analysis combining data from the clinical trials in South Africa and The Gambia, both of which used PCV9 at 6, 10 and 14 weeks, investigators found that PCV9 did not provide significant protection against serotype 1 invasive disease.¹⁵ Serotype 1 cases that occurred in the PCV9 group all occurred after 12 months of age, whereas several cases of serotype 1 disease occurred before 12 months of age in the control arms. While the authors of this study speculated that a booster dose may be needed for control of serotype 1 disease, results from ongoing surveillance studies in the United Kingdom and Kenya, expected soon, should provide more definitive information.