e. that could lead to increases in the number of cases), we focused on scenarios that would favor the transmission of the serotype with lowest vaccine efficacy, i.e. DENV-2. Thus, the three main scenarios explored were: (a) risk of clinically apparent disease after infection by DENV-2 is greater than risk for other serotypes, (b) transmission intensity of DENV-2 is greater than transmission intensity of other serotypes, and (c) enhancement of infectiousness upon secondary infection
with DENV-2 is greater than enhancement by other serotypes. Example output of the simulated annual incidence of clinically apparent dengue and seroprevalence under the three scenarios explored is shown in the supplementary material selleck chemicals (Supplementary Figs. S2.2 and S2.3). Fig. 2 shows example output from simulations under the “base case”, where all serotypes are equally transmissible, have an equal probability of leading to clinical disease, and do not interact. As expected, a vaccine that is equally effective against all serotypes leads to a symmetric decline in the serotype specific incidence (Fig. 2A). In contrast, if the vaccine is only effective against 3 out of 4 circulating serotypes, reductions
in the incidence of some serotypes are accompanied by an absolute increase in the incidence from serotypes with lower efficacy (Fig. 2B). Since this model assumes that individuals can only suffer up to two infections, HCS assay there is intrinsic competition between the dengue serotypes. Vaccine induced reductions in the incidence of some serotypes reduces this competition and favors the serotype with lower vaccine efficacy. Fig. 3 summarizes the results obtained after performing simulations Parvulin over a wide range of vaccine efficacies for the three scenarios. In a large proportion of scenarios explored, partially effective vaccines result in a 50% or greater reduction in the cumulative number of clinical cases over 10 years. This is the case even for scenarios that included
large heterogeneities in the probability of infections being clinically apparent (Fig. 3A), transmission intensity (Fig. 3B) and infectiousness enhancement (Fig. 3C). Decreases in the cumulative number of cases were even more dramatic in simulations that considered low-transmission settings (see Supplementary materials S3). Our results also show that even in the presence of high efficacy against 3/4 serotypes (leading to near elimination of them, Supplementary Fig. S2.5) vaccination can lead to non-significant reductions or even increases in the incidence of dengue under certain scenarios. Increases in the 10-year cumulative number of cases were only observed for scenarios in which DENV-2 had a relative risk of clinically apparent disease greater than two.