Within-host model

In previous work we studied a Lotka–Volterra-type model [Reference Volterra and Chapman33, Reference Lotka34] of the within-host dynamics of two strains that interact with two types of immune effectors through primary and secondary interactions [Reference Pepin35]. Here we extended the model to include effects from antiviral drugs [equations (1)–(4)].

(1)$$V_{i} \equals \rho _{i} V_{i} \lpar 1 \minus V_{i} \minus V_{j} \rpar \minus V_{i} \lpar \sigma _{i} I_{i} \plus \epsiv _{i} I_{j} \rpar \minus \delta _{i} V_{i} H\lpar p\rpar \comma \hfill$$

(2)$$I_{i} \equals I_{i} \lpar \sigma _{i} V_{i} \plus \epsiv _{j} V_{j} \rpar \comma \hfill$$

(3)$$V_{j} \equals \rho _{j} V_{j} \lpar 1 \minus V_{j} \minus V_{i} \rpar \minus V_{j} \lpar \sigma _{j} I_{j} \plus \epsiv _{j} I_{i} \rpar \minus \delta _{j} V_{j} H\lpar p\rpar \comma \hfill$$

(4)$$I_{j} \equals I_{j} \lpar \sigma _{j} V_{j} \plus \epsiv _{i} V_{i} \rpar \comma \hfill$$

Here, V is viral load, I is immunity level, i is strain 1 and j is strain 2. ρ, σ, ε and δ are constant parameters for replication rate, interaction with primary effectors, cross-interactions and drug effects, respectively (Table 1a). H(p) is a step function such that H(p) = 0 for t < p and H(p) = 1 for t ⩾ p, to allow a delay between the time of infection and the time at which drugs were initiated. For simplicity, variables were re-scaled from the original form in the logistic population growth model (rV _i(1 – (V _i+V _j)/K)) to units of the carrying capacity, K, which is the maximum viral load due to cell depletion, and time was re-scaled by the inverse of the carrying capacity, resulting in an effective carrying capacity of 1. Immunity levels had an upper bound determined by total viral load, and a minimum of 10⁻³ (i.e. naive hosts; value chosen via sensitivity analyses in Pepin et al. [Reference Pepin35]). We assumed that two types of cross-reactivity were possible: (i) cross-immunity where strains are suppressed by primary antibodies of the other strain [ε in equations (1) and (3)], and (ii) cross-stimulation where strains stimulate production of the alternate immune effectors [ε in equations (2) and (4)]. Each strain had more efficient interactions with one type of immune effector (primary effector) and weaker interactions with the alternate effector (cross-effector). We assumed that re-infections were similar to primary infections except that increased initial immunity levels caused decreased viral loads and infectious periods, and increased levels of adaptive immunity.

Table 1.

Description of parameters used in main results

In all analyses, the intrinsic characteristics of the two strains were symmetric (the same values for replication rate and immunity interaction parameters) in order to focus on the effects of time-varying infection profiles and drug regimens (Table 1a). In rare cases where super-infection occurred, strains competed within hosts resulting in altered strain-specific viral load and immunity levels. For simplicity, we did not model the innate immune response explicitly, rather we assumed it was a constant and that differences in the ability of the immune system to control infection were due to differences in adaptive immune system responses. Target-cell depletion was also modelled implicitly as a constant through the carrying capacity term. Thus, we assumed that the viral load dynamics of a particular strain were impacted entirely by: adaptive immunity, the presence of another strain, an upper limit on viral load, and drugs.

Detailed behaviour of the within-host model with drug effects is shown in Supplementary Figures S1 & S2 (see also [Reference Pepin35] for a version of the model with no drug effects). Briefly, viral population size increases sharply to peak load followed by a slower rate of decrease to complete clearance. In the absence of drugs, total viral load, final immunity and infectious period do not depend on initial viral dose unless the strains co-infect. Differences in population growth rate (ρ) and cross-interactions with immunity (ε, δ) cause complex behaviour in relative strain dynamics, especially when the parameter values are asymmetric between strains. Here, we exclude these effects by considering strains with the same values of population growth and cross-interaction.

Transmission model

Multiple factors influence transmission – from host contact structure to within-host viral abundance [Reference Bansal36–Reference Miller38]. In order to isolate effects of viral infection profiles on transmission and immunity, we compared two types of simple population-patch structure: random global mixing and a 10-patch metapopulation with random mixing within and 0·25% movement between patches per time step. The scenarios had equal R ₀ values. We used an agent-based simulation approach to model transmission in discrete time such that infectiousness and infectious doses depended on viral abundance in donor hosts at the time of contact. Simulations were conducted in Matlab (R2009b, MathWorks Inc., USA). Transmission from an infected host occurred with a fixed transmission probability given that the donor had a total viral abundance above the threshold of infectiousness (⩾10²) and the recipient candidate was susceptible. Infection in the recipient was established with a fixed transmission probability if the amount of virus, after sampling by a fixed bottleneck factor (10⁻³), was above the threshold for establishment (⩾10⁻⁶, arbitrarily chosen to reflect 1 viral particle assuming that a host expels up to 10⁷ particles per transmission event). The bottleneck parameter was chosen under the assumption that the number of particles transmitted is 1/1000 times more dilute than that in the infected host, and sensitivity analyses showed that bottleneck factors ⩾10⁻⁴ did not increase stochastic extinction of either strain. Super-infections, although rare, could occur when multiple infected hosts attempted transmission to the same susceptible host during the same time step (if both were successful according to the random transmission probability then the recipient was infected with the sum of the donor virus). Host transition from infected class to recovered class depended on infection period (the time from infection start to clearance which includes infectious and non-infectious time).

Simulations were mainly conducted under R ₀ = 1·5 (mean time between serial infections 2–3 days) for the case without drugs to mimic conditions that are typical for influenza [Reference Ferguson8, Reference Fraser39, Reference White40], but effects of R ₀ between 2 and 3 were also explored since they have been reported for a pandemic strain [Reference Mills, Robins and Lipsitch41, Reference Boelle42]. For analyses of drug effects, 40% coverage was used in the main text since this is a realistic level of drug stockpiling for pandemic preparedness (e.g. http://www.chp.gov.hk/en/guideline1/29.html). Hosts that took antivirals were chosen at random (implemented by assigning a 40% chance of taking antivirals to each host that became infected). Although we only investigated effects of post-infection drug treatment, simulations where antivirals were taken on the first day are similar to prophylactic drug use. The effects of 100% drug coverage were simulated for comparison and to show that the model produces realistic decreases in transmission due to drug treatment under the fixed parameters (38–65%, Fig. S2; similar to a decrease in household transmission of 42–80% [Reference Goldstein2, Reference Halloran3]). In order to focus on the epidemic dynamics rather than stochastic extinction, all simulations were begun with 10 infected hosts that were randomly selected from the population. The invader was introduced in 10 other hosts when 5% of hosts had been infected with the resident strain, which was approximately the midpoint of the epidemic growth curve under R ₀ = 1·5. A sensitivity analysis on invasion time is presented in Figure S3.

Transmission across multiple waves

Each wave was initiated by introducing 10 infected hosts into a population consisting of individuals whose immunity levels were determined from the last wave. We assumed that hosts could only be re-infected between seasons since re-infection with a completely homologous strain within the same season does not cause productive infection [Reference Carroll43]. Thus, each wave faded out when contact rates with susceptible hosts (i.e. hosts that had not yet been infected within the season) decreased below the infectious period of infected hosts. When we re-introduced the virus in the next season, we assumed that previously infected hosts could again be infected since each the resident strain and invader would have experienced a small amount of antigenic drift, which is typical for influenza viruses. However, this assumption was only included implicitly rather than explicitly to reduce model complexity and uncertainty (i.e. decrease the number of parameters for which there are few empirical data). Thus, in our model, the small amount of antigenic drift enabled re-infection of hosts that had previously been infected with a similar strain and the infection profiles generated by these previously infected hosts correlated with immunity generated during prior infection [Reference Carroll43, Reference Greenberg, Couch and Kasel44]. Specifically, immunity was not prohibitive to infection if the viral dose was high enough to generate an infectious period despite a given immunity level or if the use of drugs in season 1 caused decreased immunity.