Of note, the sample sizes are clearly smaller also under alternative (d), in which efficacy for non-common
(“new”) serotypes is estimated. Some pneumococcal serotypes are only rarely found in carriage despite causing a significant proportion of disease. This is particularly true for the invasive disease outcomes with so called ‘epidemic’ types (e.g. 1 and 5), since they are carried either very briefly or selleck chemicals as minor populations in the nasopharynx. One possible approach in such a case is to conduct a colonisation study in pneumonia patients to estimate VEcol. It would then be based on rates of acquisition weighted according to the case-to-carrier ratios (i.e. probabilities of disease per episode of carriage) for each of the target serotypes, reflecting more directly the distribution of serotypes causing GDC-0068 molecular weight disease. The set of reference states of colonisation should again exclude any states with VT colonisation (cf. Section 4 in [1]). Apart from the fact that the uncolonised study subjects can be included in the reference set of the analysis, this study design is equivalent to the indirect cohort method. The indirect effects of large-scale vaccination with current PCVs in the whole population follow after a relatively short time-lag. Usually such changes are seen in VT colonisation. Therefore, it may be of concern that data collected in vaccine studies conducted in restricted areas may be affected by indirect
protection, thus complicating the interpretation of any estimates of direct vaccine efficacy. Theoretical results based on a simple VT/NVT split inhibitors indicate that prevalence-based estimates of vaccine efficacy are less prone to bias when indirect protection occurs simultaneously in vaccinees and controls [15]. One problem requiring further investigation is the possibility ever of an interaction (effect modification) between the current colonisation (at the time of vaccination) and the subsequent vaccine effect. Such an effect of current carriage on the vaccine-induced serotype-specific antibody
response has been recently shown [16]. A somewhat different question relates to the potential interaction of the vaccine effect and the current carriage (yes/no) at the time of acquisition of (secondary) serotypes. Protection induced by a vaccine may be heterogeneous across individuals. A general discussion of the estimation of vaccine efficacy under heterogeneity is provided in an article by Halloran et al. [17]. Most importantly, the account of VEcol in the present article is based on the assumption of a leaky vaccine effect, i.e. that vaccinees would benefit from the vaccination through a reduced target serotype acquisition rate, rather than through a portion of vaccinees being completely protected against pneumococcal colonisation (and the rest remaining unprotected). Ideally, investigations of the impact of vaccination on the dynamics of colonisation should be based on longitudinal data.