Data collection

Data on AHC outbreaks were downloaded from the China Information System for Disease Control and Prevention, which is a web-based reporting system of national notifiable infectious diseases and public health emergencies. We collected information on all outbreaks reported from 1 January 2004 to 31 December 2015, in Changsha, China; data on nine AHC outbreaks occurring in schools were collected (Table 1). The data included the type of school (primary, middle, high school), school population, dates when the outbreaks were reported, and date of symptom onset for all cases. The AHC cases were confirmed to meet the WS 217–2008 diagnostic criteria for AHC [20]; AHC cases were diagnosed clinically based on a history of infectious agent exposure and characteristic findings, such as sudden onset of ocular pain, foreign body sensation, conjunctival hyperaemia, chemosis, and subconjunctival haemorrhages.

Table 1. Characteristics of nine acute haemorrhagic conjunctivitis outbreaks in Changsha city, China, 2004–2015

TAR, Total attack rate; DO, duration from illness onset date of the index case to illness onset date of the last case.

Outbreaks are listed in chronological order.

Modelling AHC without an intervention

A SIR model [Reference Kermack and McKendrick21, Reference Hethcote22] was built to simulate the normal transmission of outbreaks in schools, that is, without intervention. The SIR model [Reference Mu6, Reference Meng7] divides the population into three categories of individuals according to disease status (Fig. 1): susceptible (S), infected (I), and recovered (R). It assumes that a certain proportion of individuals move between the categories because of infection or recovery, or for other reasons. Several assumptions were built into the formulation of our SIR model based on the characteristics of AHC disease [Reference Wright2] and previous studies [Reference Chen18, Reference Chen and Liu19]. First, births, deaths, and migrations were omitted from the SIR model, since the AHC outbreaks usually occurred in student populations in which birth, death, and migration were negligible. Second, every individual in the population was assumed to have an equal probability of contracting the disease, β (the contact or infection rate of the disease). Therefore, the number of new infections was βSI at time t. Third, given the short incubation period of AHC, its impact on disease transmission was insignificant; therefore, the incubation period was ignored in our equations [Reference Chen18, Reference Chen and Liu19]. Fourth, since the fatality rate of AHC is low and asymptomatic infection is rare [Reference Waterman23, Reference Reeves24], these were both ignored. Fifth, a number equal to the fraction of infected individuals (γ, which represents the mean recovery rate, or 1/γ the mean infective period) leaving per unit time to the recovered category (the number of newly recovered individuals) was γI at time t. The final SIR model is given by the following equations:

(1) $$\left. \matrix{dS/dt = {\rm} - \beta SI, \hfill \cr dI/dt = \beta SI\gamma - \gamma I, \hfill \cr dR/dt = \gamma I, \hfill} \right\}$$

where dS/dt, dI/dt, and dR/dt denote the number of individuals (n) at time t in the corresponding categories.

Fig. 1. Dynamic acute haemorrhagic conjunctivitis transmission model.

Counter-measures

The interventions for controlling a viral infectious disease outbreak include pharmaceutical (typically antiviral agents and vaccination) and non-pharmaceutical (isolation and school closure) interventions. Unfortunately, there is no vaccine or antiviral treatment for AHC. Hence, for AHC outbreaks, the quantitative and effective interventions are likely to be isolation and school closure. The stage at which isolation is implemented and the duration of school closure are important. According to the natural history of AHC, the duration from illness onset to recovery is 7–10 days. Under these circumstances, we evaluated the effectiveness of isolation in different stages according to the actual epidemic curve and based on individual outbreaks, such as days 2, 4, 6, and 8 in outbreak number 4; different durations of school closure (3, 6, or 9 days); and different combinations of the two interventions.

Case isolation modelling

When isolation was added to the SIR model at time t (t = π), we assumed that strict isolation would be adopted once the infected individual was identified; subsequently, the infected individual, who left the infected category to enter the recovered class, was not infectious. Therefore, β was equal to zero after isolation. Thus, the function of parameter β along with time was as follows:

(2) $$f\,(\beta ) = \left\{ {\matrix{ {\beta,} & {(t \le \pi )} \cr {0,} & {(t \gt \pi )} \cr}} \right.$$

where π is the initial time (days) of isolation. In our study, we simulated different scenarios when isolation was implemented at different stages. For example, in outbreak number 4, isolation was implemented on days 2, 4, 6, and 8; thus, π = 2, 4, 6, and 8, respectively.

In addition, the effective implementation of case isolation required supplementary measures, including disinfection of the environment that was contaminated by the isolated case, inspection of all healthy persons, and instituting a class absence. Therefore, case isolation in model (2) was a package that included supplementary measures.

School closure modelling

During a school closure, all staff and pupils return home. Person-to-person contact is severed, and β = 0. Once the school closure interval is complete, the school population returns, and the transmission mode reverts to the SIR model. In this case, the function of parameter β along with time is as follows:

(3) $$f\,(\beta ) = \left\{ {\matrix{ {\beta,} & \!\!\!\!\!\!\!\!\!\!\!\!{(t \lt \pi _1)} \cr {0,} & {(\pi _1 \le t \le \pi _2)} \cr {\beta,} & \!\!\!\!\!\!\!\!\!\!\!\!{(t \gt \pi _2)} \cr}} \right.$$

where π ₁ (days) is the initial date of the school closure, π ₂ (days) is the end of the school closure, and Δπ = π ₁ – π ₂ (days) is the interval of the school closure. We simulated school closures of 3, 6, and 9 days; therefore, Δπ = 3, 6, and 9.

Modelling combinations of the intervention strategies

For all of the school outbreaks, we simulated combinations of interventions of case isolation and school closure to examine their impact on the efficacy of outbreak control: (i) isolation implemented at different stages according to the epidemic curve (days 2, 4, 6, or 8) relative to the outbreak and (ii) school closures of 3, 6, or 9 days, where school closure and isolation were implemented on the same day.

Parameter estimation

In the SIR model, there were two parameters: β and γ. There is currently no known treatment for AHC, and the viral infection generally resolves spontaneously. Given that the infectious period of AHC is 7–10 days, 8 days were selected as the average infectious period [Reference Chen18]; thus, γ was 0·125. β values for the nine school outbreaks were generated by curve fitting of the SIR model and reported data.

Effective reproduction number

In epidemiological models, the effective reproduction number (R _eff), which quantifies the transmission potential of a disease, is an important quantitative parameter that determines whether an epidemic occurs (R _eff > 1) or if the disease simply dies out (R _eff < 1) [Reference Xu and Zhang25]. R _eff equals the average number of secondary infections caused by a single infected person during his/her entire infectious period in a wholly susceptible population. In the SIR model, the effective reproduction number is:

(4) $$R_{{\rm eff}} = \displaystyle{{\beta S_{(t)}} \over \gamma}, $$

where S _(t) denotes susceptible individuals at time t. R _eff was divided into two parts (R _unc and R _con) before and after the intervention, where R _unc and R _con represent the uncontrolled and controlled effective reproduction numbers, respectively.

Intervention assessment

The total attack rate (TAR), duration of outbreak (DO, duration in days from index case to last case), and number of peak cases were used to assess the effectiveness of the outbreak control interventions. Epidemic curves were compared to evaluate the effectiveness of using the containing strategies compared with using no intervention and with the actual strategies implemented by the health departments and schools.

Simulation methods

We fitted the data from the nine outbreaks to a SIR model curve to estimate β of each outbreak. β was further divided into two parts (β _unc and β _con) when simulating the reported data, where β _unc and β _con represent the infection rate before and after the intervention, respectively. β = β _unc was adopted as a baseline outbreak to simulate the effects of case isolation, school closure, and combined interventions in all nine outbreaks. Berkeley Madonna 8.3.18 (www.berkeleymadonna.com/download.html) and Microsoft Office Excel 2003 (Microsoft Corp., USA) software were employed for model simulation and figures. The fourth-order Runge–Kutta method, with tolerance set at 0·001, was used to perform curve fitting. While the curve fitting is in progress, Berkeley Madonna displays the root mean square deviation between the data and best run so far. The coefficient of determination (R ²) from the reported and model data was used to judge the goodness of fit.