The model framework

We developed a stochastic age-structured agent-based model of influenza transmission dynamics, which includes epidemiological statuses of susceptible (S), latent (L), symptomatic infection (I), asymptomatic infection (A) and recovered (R). Recovery from infection was assumed to confer immunity against re-infection in the same epidemic season.

Population study and contact patterns

Demographics of the population were sampled from census data collected by Statistics Canada (Fig. S1, Supplementary Material) [17]. Due to short timelines of a single influenza epidemic season, we ignored demographics of birth and natural death. We considered 15 age groups for the population and used the average of contact matrices in POLYMOD study for European countries as a proxy for matrix of contact patterns in urban structures [Reference Mossong18]. The daily number of contacts for each individual was sampled from an age-specific negative-binomial distribution (Table S1, Supplementary Material) and randomly assigned to individuals in different age groups (Fig. S2, Supplementary Material).

Disease dynamics

Disease transmission occurred through contacts between susceptible and symptomatically or asymptomatically infectious individuals, and was implemented as rejection sampling-based (Bernoulli) trials where the chance of success is defined by a transmission probability distribution [Reference Laskowski and Moghadas19, Reference Mostaço-Guidolin20]. The baseline transmission probability was obtained by calibrating the model to a specific reproduction number (R ₀ = 1.4) within the estimates for influenza outbreaks [Reference Biggerstaff21].

Following exposure to infection and disease transmission, the newly infected individuals enter the latent stage during which the disease cannot be transmitted. Once the latent period has elapsed, the disease may manifest as symptomatic or asymptomatic infection. Durations of latent and infectious periods were sampled for each individual from the associated distributions described in the Parameterisation section.

Vaccine effectiveness

Vaccination was implemented randomly to achieve the vaccine coverage reported for seasonal influenza in different age groups [22]. For a given vaccine efficacy V _e (defined as infection prevention in randomised control trials involving healthy individuals [Reference Nicoll and Sprenger5]), the protection level of a vaccinated individual against infection was determined by E = V _e(1 − f), where f represents the frailty index. We considered E as the individual-level vaccine effectiveness. We sampled the frailty index for each individual by performing a segmented linear regression as a function of age (Fig. S4, Supplementary Information), fitted to the 2014 Canadian Community Health Survey data of chronic diseases [23]. The vaccine effectiveness was included as a reduction factor for disease transmission. This effectiveness also reduced the probability of developing symptomatic infection by a factor of 1 − E in vaccinated individuals if infection occurred. The transmission probability per contact was then obtained by

$$P_{{\rm transmission}} = \left\{ {\matrix{ {\beta \alpha} & {\!{\rm contact:\;} \,S\leftrightarrow I\,{\rm or}\,S\leftrightarrow A} \cr {\beta \alpha (1-E)} & {{\rm contact:}\,V\leftrightarrow I\,{\rm or}\,V\leftrightarrow A} \cr}} \right.$$

where α represents the level of infectiousness, with α = 1 for symptomatic infection (I), and α < 1 for asymptomatic infection (A).

Behavioural responses

We modelled behavioural responses of individuals using a parameter p _s (p _v), representing the fraction of contacts that are avoided by susceptible (vaccinated) individuals with symptomatically infectious individuals. The effect of changes in contact patterns during the epidemic has been investigated in previous studies [Reference Shaw and Schwartz24, Reference Zanette and Risau-Gusmán25]. We assumed that vaccinated individuals have a lower contact avoidance compared to susceptible individuals, and therefore considered p _v ⩽ p _s. This assumption corresponds to a higher number of contacts post-vaccination. Although quantifying human behaviour is challenging, a previous study reports that in the 2 days immediately following influenza vaccination, individuals socially encountered almost twice as many contacts as they did in the 2 days prior to vaccination [Reference Reiber13].

Per-contact risk-of-infection

To estimate the risk-of-infection in each age group throughout the epidemic, we used a maximum-likelihood approach. Since infection per contact was implemented as a Bernoulli trial, we defined a likelihood function for the risk in susceptible individuals by (assuming the independence of events):

$$L(r_{\rm s}) = r_{\rm s}^n (1-r_{\rm s})^{\left( {\sum\nolimits_i {a_i} + \sum\nolimits_j {b_j}} \right)-n},$$

where n is the number of infections generated by contacts between susceptible and infectious individuals; $\sum\nolimits_i {a_i} $ is the total number of contacts that led to infection as the outcome and $\sum\nolimits_j {b_j} $ is the total number of contacts between susceptible and infectious individuals without infection as the outcome. For each scenario, we used the maximum likelihood estimator:

$$\hat{r}_{\rm s} = \displaystyle{n \over {\mathop \sum \nolimits_i a_i + \mathop \sum \nolimits_j b_j}},$$

in independent realisations to determine the risk in different age groups. Since vaccine-induced protection reduced the probability of infection, we considered a parameter c as the reduction factor for the per-contact risk-of-infection (r _v) in vaccinated individuals and defined the likelihood function by:

$$L(r_{\rm v}) = (cr_{\rm s})^m(1-cr_{\rm s})^{\left( {\sum\nolimits_i {u_i} + \sum\nolimits_j {w_j}} \right)-m},$$

where m is the number of infections generated by contacts between vaccinated and infectious individuals; $\sum\nolimits_i {u_i} $ is the total number of contacts that led to infection as the outcome and $\sum\nolimits_j {w_j} $ is the total number of contacts between vaccinated and infectious individuals without infection as the outcome. Given $\hat{r}_{\rm s}$, we used the likelihood estimator:

$$\hat{c} = \left( {\displaystyle{1 \over {{\hat{r}}_{\rm s}}}} \right)\displaystyle{m \over {\mathop \sum \nolimits_i u_i + \mathop \sum \nolimits_j w_j}},$$

to determine the per-contact risk-of-infection among vaccinated individuals in different age groups.

Parameterisation

We parameterised the simulation model with a total population size N = 10 000 individuals, with a transmission probability that was calibrated to the reproduction number R ₀ = 1.4 in the absence of any control measures [Reference Biggerstaff21]. A recent systematic review estimates the median R ₀ = 1.28 for seasonal epidemics, with a range of 1.11–2.2 [Reference Biggerstaff21]. The reproduction number, which was calculated by introducing an individual in the latent state of disease in independent realisations and averaging the number of new symptomatic cases generated, reflects the epidemic growth at the early stages and changes during the course of the epidemic (Figs S8 and S9, Supplementary Material). Latent period was drawn from a uniform distribution with the mean of 1.5 days within the estimated ranges [Reference Cori26, Reference Laskowski27]. The infectious periods for both symptomatic and asymptomatic infections were sampled from a truncated lognormal distribution with scale parameter μ = 1 day and shape parameter σ ² = 0.4356 (Fig. S3, Supplementary Material), having a mean of 3.38 days [Reference Laskowski27, Reference Tuite28]. The probability of developing asymptomatic infection was sampled for each individual from a uniform distribution in the range 0.3–0.7 [Reference Laskowski27]. We assumed that the infectiousness of asymptomatic infection is reduced by 50% compared to symptomatic infection [Reference Laskowski27]. Vaccine efficacy (V _e) was varied between 0.2 and 0.8, from which the vaccine effectiveness (E) for each vaccinated individual was calculated based on the sampled frailty index (Fig. S5, Supplementary Material). Vaccine coverage was accounted for in different age groups (Table S2, Supplementary Material), based on the 2016–2017 report of the National Influenza Immunization Coverage Survey in Canada [22]. Parameter values and their respective ranges are reported in Table 1.

Table 1. Parameters and their associated ranges used for simulating model scenarios

Model implementation and simulations

We implemented the model in Julia language and performed Monte-Carlo simulations to analyse the outcomes as the average of sample realisations in different scenarios of disease spread. Individuals were vaccinated before the start of the epidemic, based on the given vaccine coverage in different age groups. During the simulations, the daily sampled contacts of a susceptible (vaccinated) individual were discarded with the probability p _s (p _v), corresponding to the contact avoidance factor, if the contact was identified as a symptomatic infection. We ran simulations with varying vaccine efficacy and contact avoidance in their respective ranges, and compared the outcomes with the baseline scenario in which the epidemic unfolds without vaccination. All simulations were seeded with a randomly selected individual in the latent state of the disease, and averaged over 2000 independent realisations. We analysed the outputs to determine (ii) the relative epidemic size (compared to the scenario without vaccination); and (ii) per-contact risk-of-infection in different age groups.