Assumptions for protective and enhancing antibodies

While the titre of antibodies against dengue virus is high, the protective role of antibodies is dominant: however, as the titre wanes, antibodies enhance development of DHF [Reference Kliks24]. It is not known whether protective antibodies and enhancing antibodies are physically separable (Fig. 1 a) ([Reference Brandt25] and E. Konishi et al., personal communication), or whether the same antibodies switch from protection to enhancement as their titres wane − in other words, virtual enhancing antibody (Fig. 1 b) [Reference Morens, Halstead and Marchette26]. However, these two hypotheses converge into an identical software coding if the first hypothesis (Fig. 1 a) surmises that the enhancing antibody persists life-long and if the second hypothesis (Fig. 1 b) assumes that antibody induced by viral inoculation exerts life-long enhancement. This framework enabled the distinction between enhancing antibodies induced by prior wild-type infection and those attributable to vaccine.

Fig. 1. Two hypotheses regarding antibodies to dengue viruses. (a) Enhancing antibodies and protective antibodies are different. Enhancing antibodies react with all virus serotypes (broken arrows). In contrast, protective antibodies are specific to a serotype (D1 in this figure), but exert transient cross-reactive protection against other serotypes (solid arrows). (b) The same antibodies may play different roles in protection and enhancement, depending on their titres. Antibodies (specific to D1 in this figure) exert protection against other serotypes when their titres are high (solid arrows). As the titre wanes, these antibodies act as enhancing antibodies (broken arrows). D1, D2, D3, and D4 represent dengue virus serotypes 1, 2, 3, and 4, respectively.

An inoculation with a wild-type virus induces protective antibodies specific to that serotype. On the other hand, an individual inoculated with a tetravalent live vaccine acquires protective antibodies specific only to the serotype(s) to which s/he seroconverted. The protective antibodies are assumed to exert life-long serotype-specific protection, as well as transient cross-serotype protection for a duration of C years from the latest inoculation. Sabin [Reference Sabin11] observed volunteers who were inoculated sequentially with two different strains of dengue virus, with the interval between the inoculations being maximally 9 months. It was found that cross-protection against severe illness still persisted at least after this interval. In addition, vaccination with yellow fever–dengue 2 chimeric vaccine induced cross-serotype protection that lasted >1 year [Reference Guirakhoo27]. Furthermore, it was reported that secondary infections resulted in DHF, DF, and asymptomatic infections at 2·6, 1·9, and 1·6 years after the primary infections, respectively [Reference Anderson28]. These observations suggested that cross-serotype protection against DHF may last for >1 year. Therefore, C was assumed to follow a normally distributed probability distribution function (PDF) with a mean equal to 2 years (Table 1). An individual inoculated with either wild-type or vaccine acquires enhancing antibodies, which persist throughout that individual's life [Reference Guzman29, Reference Gonzalez30].

Table 1. Variable parameters given to simulations

PDF, Probability distribution function with normal distribution; s.d., standard deviation.

* Fixed, a fixed value was input into each simulation to examine the effect of the parameter on the simulation result.

Table 2. Serotype-specific seroconversion rates (%) of CYD tetravalent dengue vaccine based on a PRNT₅₀ of 1:10, obtained from clinical trials conducted in non-endemic areas

D1, D2, D3, and D4 represent dengue virus serotypes 1, 2, 3, and 4, respectively.

Assumptions for DF and DHF

Individual-based model simulation software (detailed in Protocol S1 of reference [Reference Thammapalo13]) was modified to describe immunological behaviour of the host (Fig. 2 a). When a naive individual is inoculated by wild-type dengue virus, s/he transitions to the cross-protected state. In the course of this transition, s/he may develop DF with an age-dependent probability defined in Figure 2 b (constructed based upon reference [Reference Egger and Coleman5] and P. G. Coleman, personal communication), and DHF with a fixed small probability of 0·2% [Reference Sangkawibha12]. If an individual in the cross-protected state is inoculated with a virus serotype, s/he acquires antibodies specific to this serotype and remains in the cross-protected state. C years after the most recent inoculation, the individual moves to the expired cross-protection state. When an individual in this state is inoculated with a serotype to which s/he does not possess specific antibodies (i.e. unexperienced serotype), s/he may manifest DF. The individual may also develop DHF with an enhanced probability of 4% [Reference Sangkawibha12], if s/he already possesses enhancing antibodies. An individual who has seroconverted to ‘L’ serotype transitions to the completely immune state (Table 1). The transmissibility (or viraemia) may be enhanced ‘T’-fold during manifestation of DHF [Reference Vaughn31] (Table 1).

Fig. 2. Individual-based model for dengue infections. (a) Diagram of the transition between immunological states. Transition between immunological states (filled arrow) occurs as a result of either viral inoculation or expiration of time from the most recent inoculation (open arrow). During a state transition, the individual may manifest dengue fever (DF) or dengue haemorrhagic fever (DHF) (arrow head). * A modification of the model in reference [Reference Thammapalo13] was made: the individual is predisposed to the risk of DHF only if enhancing antibodies pre-exist. (b) Age-dependent probability for an infection to manifest as DF in an individual who is not protected specifically or cross-reactively. The probability is expressed as: 100/[1 + 1/exp(−3·44 + 0·177 × age)] % ([Reference Egger and Coleman5] and P. G. Coleman, personal communication).

Basic and effective reproductive numbers

In the mathematical models for dengue proposed so far, transmission intensity was often expressed as mosquito density [Reference Wearing and Rohani32, Reference Chikaki and Ishikawa33] or as basic reproductive number (R ₀) [Reference Nagao and Koelle9, Reference Massad34, Reference Coelho35]. In the present study, R ₀ represents transmission intensity, since R ₀ is proportional to vector abundance [Reference Anderson and May3, Reference Macdonald36, Reference Macdonald37]. The range of R ₀ was selected, considering previous estimates [Reference Massad34, Reference Ferguson, Donnelly and Anderson38, Reference Johansson, Hombach and Cummings39].

The immunological state of each individual was updated at discrete time-steps of 2 weeks' length, which approximates the sum of intrinsic incubation and infectious periods [Reference Sabin11, Reference Vaughn31, Reference Gubler40]. The risk of being infected by a serotype (force of infection or viral inoculation rate) at the ith time-step (F _i ) was obtained as:

(1) $$F_i = R_{0,i - 1} \times U_{i - 1} /N_{i - 1} , $$

where R _0,i−1, U _i−1 and N _i−1 represent basic reproductive number, viraemic load and population size in the (i−1)th time-step, respectively. Here, the viraemic load at the ith time step (U _i ) is defined as:

(2) $$U_i = {\rm DF}_i + (T \times {\rm DHF}_i ),$$

where DF _i and DHF _i denote the number of patients with DF and DHF, respectively. T is the above-mentioned enhancement in transmissibility (Table 1). Effective reproductive number, which is defined as the secondary infectious cases originating from a primary infectious case, was estimated for each time step to be compared with R ₀ given to the simulation.

Estimation of vaccine seroconversion rates

To exclude the effect of natural infections, the results of clinical trials conducted in non-endemic areas were used in the present study (Table 2). Two trials adopted a regimen of 0–3·5–12 months [Reference Poo20, Reference Morrison21]. However, the short first interval resulted in trans-serotype interference [Reference Guy15, Reference Morrison21]. Therefore, the present study assumed 0–6–12 months interval (Table 3). The results in adult vaccinees were applied to paediatric vaccinations. All the trials in Table 2 defined a 50% plaque reduction neutralization titre (PRNT₅₀) of 1:10 as the cut-off for seropositivity. This titre had been considered as the surrogate for maximal protection, as in Japanese encephalitis [Reference Hombach41]. The clinical studies reported the seroconversion rate after the first dose (R _i ,_1%), that after the second dose (R _i ,_1 + 2%) and that after the third dose (R _i ,_1 + 2+3%) for each serotype i (i = 1, 2, 3, or 4). From these values, the seroconversion rate achieved solely by the second dose (R _i ,₂) was estimated as:

(3) $$ R_i, _{2{\rm}} = 100{\rm} \times (R_i, _{1 + 2{\rm}} - {\rm} R_i, _1 \kern -2pt)/(100 - R_i, _1 \kern -2pt),$$

Similarly, the seroconversion rate achieved solely by the third dose (R _i ,₃) was estimated as:

(4) $$\eqalign {R_i, _{3{\rm}} = 100 \times (R_i, _{1 + 2 + 3{\rm}} - {\rm} R_i, _{1 + 2} \kern -2pt)/(100 - R_i, _{1 + 2} \kern -2pt),}\hskip-10pt$$

Here, it was assumed that vaccinees that had seroconverted would not turn seronegative.

Table 3. Dengue serotype-specific seroconversion rates (%) assumed in simulations

R _i,1, R _i,1 + 2 and R _i,1 + 2+3 denote the seroconversion rate for serotype i after the first, second, and third doses, respectively. R _i,2 and R _i,3 represent the seroconversion rate achieved solely by the second and third doses, respectively. R _i,2 and R _i,3 of CYD₁₀₀ were estimated using equations (3) and (4) in the main text, respectively. R _i,1, R _i,2, and R _i,3 of CYD₄₀ and those of CYD₂₀ were 40% and 20% of the corresponding values for CYD₁₀₀, respectively. R _I,1, R _i2 and R _i,3 were input into the simulations. D1, D2, D3, and D4 represent dengue virus serotypes 1, 2, 3, and 4, respectively.

Compromised protective seroconversion rates

R _i,j (i = 1−4, j = 1−3) represents the maximal achievable protective potencies. However, the efficacies reported in the clinical trial were low (i.e. 30·2%) [Reference Sabchareon16], indicating that ‘protective’ seroconversion rates for CYD may be much lower than R _i,j , which was measured based on a PRNT₅₀ of 1:10. Therefore, the present study conducted a sensitivity analysis by considering tetravalent vaccines with compromised protective potencies (Table 3). CYD₄₀ and CYD₂₀ were assumed to induce protective seroconversion rates of 40% and 20%, respectively, compared to the seroconversion rates measured as PRNT₅₀ of 1:10. CYD₁₀₀ induces protective seroconversion rates equal to those measured as PRNT₅₀ of 1:10.

Vaccine assumptions

Enhancing antibodies derived from vaccine and those from wild-type virus were differentiated in the software. Inoculation by a vaccine will not manifest as clinical illness or lead to development of transmissible viraemia. Since CYD tetravalent vaccine contains only two dengue-virus peptides (E and prM), this vaccine may not confer efficient cross-protection. Consistent with this assumption, the efficacy of CYD measured within 2 years after vaccination was only 30% [Reference Sabchareon16]. Therefore, this study adopted an unfavourable scenario for CYD, assuming that CYD does not induce cross-serotype protection.

Emulation of vaccination programme

A future vaccination programme was emulated. At the 100th year in a 150-year simulation, a vaccination programme was initiated. After this year, an attempt was made to vaccinate all children who reached age 2 years but only with a successful coverage of V%. This age was selected because it was the youngest age tested in the clinical trials so far conducted. It was attempted to re-vaccinate the vaccinees at 6 months and 12 months after the first dose, but with a successful follow-up coverage of V%, respectively. This was because 100% accomplishment of any vaccination programme, especially of three-dose regimen, is difficult to achieve in developing countries.

Inhomogeneous mixing

The degree of inhomogeneity in the mixing pattern was represented by I, where I = 0 indicated completely homogeneous mixing and I = 1 indicated maximally inhomogeneous mixing (see Supplementary online Appendix 1 and Table 1).

Seasonality

Since vector mosquito abundance fluctuates seasonally [Reference Strickman and Kittayapong42], seasonality is an important factor which should be considered in modelling a mosquito-borne disease [Reference Chikaki and Ishikawa33]. Therefore, the present study expressed seasonality as a sinusoidal function of R ₀, as follows:

(5) $$R_0 (\theta ) = \bar R_0 \; \times {\rm [}1 - \cos (\theta ) \times {\rm} S{\rm ]},$$

where θ represents the phase of a time-step in a year [0 ⩽ θ⩽ 2π], R ₀(θ) indicates R ₀ at this phase, and $\bar R_0 \; $ expresses the average annual R ₀. S represents the strength of seasonality. S = 1 indicates the strongest seasonality and S = 0 represents no seasonality (Table 1).

Age-specific birth rate and mortality rate

Demographic data from Thailand were used as an example of a region heavily afflicted by dengue. Age-population structure of Thailand in 1960 was used as the initial population structure. Population growth was represented by the total fertility rate (TFR) [Reference Russel and Cohn43]. Based on the TFR given to a simulation, age-specific birth rate was reconstructed for the each age class of females (Supplementary Appendix 2). The age-specific mortality rate reported from Thailand in 2005 was used throughout the entire simulation. TFR of Thailand was 1·86 in 2000.

Source code

The source code, which was written in PERL language, can be obtained from Supplementary Appendix 3.