Model equations

(1) $$\displaystyle{{{\rm d}S} \over {{\rm d}t}} = - \lambda I,$$

(2) $$\displaystyle{{{\rm d}E} \over {{\rm d}t}} = \lambda I - \alpha E, $$

(3) $$\displaystyle{{{\rm d}I} \over {{\rm d}t}} = \alpha E - \displaystyle{\gamma \over {1 - \rho}} I, $$

(4) $$\displaystyle{{{\rm d}R} \over {{\rm d}t}} = \gamma I, $$

(5) $$\displaystyle{{{\rm d}D} \over {{\rm d}t}} = \displaystyle{{\gamma \rho} \over {1 - \rho}} I.$$

Here S, E, I, and R denote the number of susceptible, exposed, infectious, recovered and dead but no longer infectious individuals in the population, respectively. The form of λ depends on the type of transmission. In particular, for frequency-dependent transmission λ = β(S/N), and for density-dependent transmission λ = β(S/A). Where A denotes the area over which the epidemic occurs, N = S + E + I + R, and the value of the parameter β is model-specific. Because of the relatively short time over which the epidemic evolves, we do not consider natural deaths and births in these models. It is also important to note that these models are considerably simpler than many other models of Ebola. In particular, they differ from more complex models of Ebola in that they do not include a separate class for those who are both dead and infectious. Instead the infectious class may be considered to include both living and dead infectious or, alternatively, the model may be considered to neglect infection through contact with the dead. In these models, the time to leave the infectious class is determined by the time to recover (1/γ) and the probability of death (ρ). For the baseline parameter values from Table 1, this leads to an average time to death of about 6·8 days. For comparison, the time from symptom onset to death was reported as 6·4 ± 5·3 days in Guinea [1].

Table 1. Parameters

* The average latent period is taken as that for single-day exposures.

† The average time to recovery is taken as the average time from symptom onset to hospital discharge.

To parameterize the model with density-dependent transmission, we take the most relevant measure of population density as floor area per individual within a family dwelling. This parameter is estimated using [7], which reports the floor area per individual in several African nations. Since no parameter value is available for Guinea, we take the baseline value of this parameter from that of the closest nation for which data is available, Ghana, i.e. 5·5 [7].

Estimates of the size of the population of Meliandou vary. In particular, Vatican Radio reports that Meliandou was home to approximately 700 individuals before the epidemic and approximately 400 individuals after the epidemic [Reference Faul8], while a detailed map produced by the European Commission estimates that the entire region of interest, which includes two other villages of a similar size, was inhabited by approximately 719 individuals as of January 2014 [9]. In retrospect, the WHO has reported that the village includes only 31 households [10]. Assuming 10 members per household, the population size is then around 300, which is consistent with the data from the European Commission. Hence, we take the baseline population of Meliandou as 300.

The model parameters α, γ, R ₀ and ρ are taken from a WHO publication [1]. These parameters are then used to estimate the value of β, as follows. In case of frequency-dependent transmission, we use

$$R_0 = \displaystyle{{\beta (1 - \rho )} \over \gamma}. $$

In case of density-dependent transmission, we use

$$R_0 = \displaystyle{{\beta (1 - \rho )d} \over \gamma}, $$

where d denotes the initial density of the population in terms of individuals/m² of floor space.

In addition to the basic SEIR models described above, we consider models with disease-induced emigration. Although this mechanism is specific to small, well-defined populations, it has the effect of limiting the access of the infectious to the susceptible and so is, in some ways, similar to hospitalization. In developing these models we assume that the rate of emigration depends on either the number of infectious or the number of dead individuals. Specifically, in the case of density-dependent transmission, a term of the form –u(I/A)X or –u(D/A)X is added to the differential equation for variable X, for X = S, E, I, R, in order to model emigration in response to infection or mortality, respectively. Analogous terms are added to the equations of the basic frequency-dependent model in order to create the corresponding models with frequency-dependent emigration. In fitting these models to the data, only the parameter u is varied. The other parameters, including β, remain fixed.

Finally, we consider the potential of behavioural changes to impact the course of an epidemic: Individuals may change their behaviour in response to the epidemic in an attempt to avoid infection. As was the case for the models with emigration, we consider models in which individuals change their behaviour in response to either the infectious or the dead. Furthermore, we assume that these behavioural changes lower the basic reproductive ratio of the disease according to either

$$R_0 = \displaystyle{{R_m} \over {kI/A + 1}}\quad {\rm or}\quad R_0 = \displaystyle{{R_m} \over {kD/A + 1}},$$

in case of density-dependent transmission, and either

$$R_0 = \displaystyle{{R_m} \over {kI/N + 1}}\quad {\rm or}\quad R_0 = \displaystyle{{R_m} \over {kD/N + 1}},$$

in case of frequency-dependent transmission. In these models, R _m represents the reproductive ratio of the disease in a population that is unaware of the presence of either an infectious or deadly pathogen, i.e. in the absence of any extra precautionary measures, and k determines the sensitivity of the population's response to the presence of the infectious or dead. In simulating these models, R ₀ is recalculated and then used to update β at each time step.

Because estimates of the parameters R _m , k, and u are not available, these parameters are chosen to fit the data with the stipulation that the optimal parameter values must be biologically meaningful. Since the model parameters are uncertain, in some simulations the parameters for which estimates are available are also chosen to fit the data; however, these parameters are constrained to lie in a given range. For the parameters provided in [1], parameter ranges are determined by 95% confidence intervals (in the case of R ₀) or mean values ±1 standard deviation (in the case of γ and α). The other parameter ranges are delineated by the maximal and minimal values of the available parameter estimates. The optimal parameters are chosen to minimize the squared error between the model and the data (Matlab, lsqnlin). The data is a time series of cumulative cases derived from data provided by the WHO, augmented with an additional data point at 500 days, in order to penalize parameterizations that overestimate the final size of the epidemic. The models are simulated in Matlab, and model predictions of the extent and duration of the epidemic in Meliandou are compared to the data.