When this intervention was implemented, schools closed when the prevalence of illness among children in the school exceeded a predetermined threshold, set to 10%, 15%, or 20% in the simulations. A school remained closed for a predetermined period (7, 14, or 21 days). On weekdays, household and community contact parameters of children whose school was closed were assigned their weekend levels; their contacts with other children who continued to attend school and with working adults did not change.

When this intervention was implemented, a given fraction of households were assumed to comply. If a household complied, then all of its members followed the confinement rules unless they had been previously ill and had recovered. We considered 2 types of confinement: ill persons only, and ill persons and all the members of the same household. Confinement began after a given number of days of illness (1, 2, or 3 days) and did not depend on the severity of illness. If symptoms were severe, then the person reduced his or her duration of contacts with other household members by 50%.

When a person was confined on a weekday (because of his or her illness or illness of another household member) and did not withdraw due to severe symptoms, then the duration of contacts with household members who continued to go to school or work did not change. Durations of contacts with household members who stayed at home and were not withdrawn were the same as on a weekend day.

When ill persons were confined, they returned to school or work 1 day after their illness ended. When ill persons and other household members were confined, a person returned to school or to work 1 day after his or her illness ended (even if other ill persons remained in the household). A person who did not become ill returned to school or work on the third day after the last day of illness of any household member (because the length of the latent/incubation period was assumed to be 2 days).

We examined the effects of 2 interventions on LTCF residents: reduction in duration of contacts with other residents who were ill, and reduction in duration of contacts with visiting family members. Contacts with LTCF staff did not change.

The most important parameters related to the effectiveness of school closings are those that underlie the contacts between children while they are in school. In our simulations we assumed that on a school day each child makes contact with 10 other schoolchildren, each contact lasting 120 minutes (see section D.1.a in the Appendix). Some of these contacts may be concurrent. To examine the effect of changing each child’s exposure to other schoolchildren on the effectiveness of school closures, we increased and decreased the baseline duration of 120 minutes by 50%. Table 3 shows the effectiveness of closing schools for 14 days for the 3 baseline values of duration of school contact. As we see, longer or shorter durations of contact while schools are open do not result in substantial changes in the effectiveness of school closings.

We varied the values of several parameters in the baseline model and examined the effects these changes had on estimates of the effectiveness of confinement of ill persons to their homes (Table 4). We assumed that 40% of ill persons without severe symptoms were confined to home within 2 days of symptom onset. When the fraction of infected persons who developed symptoms was increased from 0.67 to 0.93, then the illness rate without an intervention (i.e., at the baseline level) changed only from 0.333 to 0.319, while implementation of the intervention changed this rate from 0.272 to 0.242. Thus, the effectiveness of this intervention increased from 0.183 to 0.241. The alternative values we used in Table 2 modeled a more severe pandemic than the pandemic modeled with the baseline initial values.

The following parameters describe how persons made contact with others. For individual A from stratum i_A and mixing group of type k and stratum j, we denoted by Ψ _Ajkl the group of all persons with whom A made contact on a day of type l , where l = 1 for weekdays and l = 2 for weekend days. These groups were referred to as "contact groups." The size, ^c_iAjkl , of Ψ _Ajkl and the average total duration in minutes, ^d_iAjkl, of all the contacts made by A with each member of Ψ _Ajkl on 1 day were specified as input parameters. At the beginning of each simulation, the initial contact groups Ψ _Ajkl were determined for A by selecting at random ^c_iAjkl persons of stratum j from each mixing group other than the household to which Abelonged. For households (k = 1) the contact groups consisted of all household members (other than A) in the corresponding stratum. If a mixing group had fewer than ^c_iAjkl members of stratum j, then the contact group consisted of the entire mixing group.

Influenza transmission was determined by contact parameters and transmission rates. The rate of viral transmission per minute of contact from an infected person in stratum j to a susceptible person in stratum i (where i, j = 1,2,3,4,5) was denoted by λ_ϋ. The probability that transmission occurred during a contact of d minutes was 1 –exp{–λ_ϋd}. On each day of the simulated outbreak, the model calculated for each susceptible person the probability of becoming infected that day, based on the contacts made with all persons in each contact group. Consider a susceptible person Afrom stratum i_A and a person B in one of A's contact groups, Ψ _Ajkl . Define ^y_B = 0 if B was not infectious and ^y_B = 1 if B was infectious. The probability that A escaped infection from B that day was exp {–λ_ϋd_{i Ajkl}^y_B}. To remain uninfected, A must have escaped infection from all the members of all her/his contacts groups. Hence the probability that A became infected on this day was: P(inf) = 1 - П_kП_jПΒЄΨ_Ajkl exp{–λ_ϋd_iAjkl^y_B}. This probability was compared with a random number, r, drawn from the interval [0,1]. The person A became infected if r < P(inf).

Each newly infected person entered a latent period, at the conclusion of which the person became infectious to others, based on values estimated by Elveback et al. (21). We assumed that the probability of symptoms developing, given influenza infection, was 0.67 and that an infected person who did not become ill was 50% less infectious than one who did. An ill person with severe symptoms withdrew to home, made contacts only with household members, and the duration of these contacts was decreased by 50%. We assumed that in 50% of adults and 75% of children severe symptoms developed and the person withdrew. An ill person could require hospitalization or die from influenza complications. The probabilities of hospitalization and death were determined on the basis of the distribution of age-specific hospitalizations and deaths in an average seasonal (nonpandemic) influenza season (22–24) and on the total hospitalization and death rates expected in a pandemic that is similar to the Asian influenza pandemic of 1957–58, for which the overall illness attack rate was estimated at 0.33, with an influenza death rate of 0.58/1,000 persons (25). A list of the initial settings of all the parameters used in these models is provided below.

The simulated epidemic started with a small number of infective persons. The transmission process continued until no further infected persons remained in the community. At the end of each simulated epidemic, the program determined the proportion of persons who became ill as well as the proportions of hospitalizations and deaths in the community. We ran 200 simulations and calculated the means of the above 3 proportions over these simulated epidemics.

The following parameters describe how persons made contact with others. For individual A from stratum i_A and mixing group of type k and stratum j, we denoted by Ψ _Ajkl the group of all persons with whom A made contact on a day of type l, where l = 1for weekdays and l = 2 for weekend days. These groups were referred to as "contact groups." The size, ^c_iAjkl, of Ψ _Ajkl and the average total duration in minutes, ^d_iAjkl, of all the contacts made by A with each member of Ψ _Ajkl on 1 day were specified as input parameters. At the beginning of each simulation, the initial contact groups Ψ _Ajkl were determined for A by selecting at random ^c_iAjkl persons of stratum j from each mixing group other than the household to which A belonged. For households (k = 1) the contact groups consisted of all household members (other than A) in the corresponding stratum. If a mixing group had fewer than ^c_iAjkl members of stratum j, then the contact group consisted of the entire mixing group.

Influenza transmission was determined by contact parameters and transmission rates. The rate of viral transmission per minute of contact from an infected person in stratum j to a susceptible person in stratum i (where i, j = 1,2,3,4,5) was denoted by λ_ϋ. The probability that transmission occurred during a contact of d minutes was 1 – exp {–λ_ϋd}. On each day of the simulated outbreak, the model calculated for each susceptible person the probability of becoming infected that day, based on the contacts made with all persons in each contact group. Consider a susceptible person A from stratum i_A and a person B in one of A's contact groups, Ψ _Ajkl . Define ^y_B = 0 if B was not infectious and ^y_B = 1 if B was infectious. The probability that A escaped infection from B that day was exp {–λ_ϋd_iAjkl^γ_B}. To remain uninfected, A must have escaped infection from all the members of all her/his contacts groups. Hence the probability that A became infected on this day was: ^{P(inf) = 1 – ПkПjПBЄψ}_Ajkl exp {–λ_ϋd_iAjkl^γ_B} . This probability was compared with a random number, r, drawn from the interval [0,1]. The person A became infected if r < P(inf).

Each newly infected person entered a latent period, at the conclusion of which the person became infectious to others, based on values estimated by Elveback et al. (21). We assumed that the probability of symptoms developing, given influenza infection, was 0.67 and that an infected person who did not become ill was 50% less infectious than one who did. An ill person with severe symptoms withdrew to home, made contacts only with household members, and the duration of these contacts was decreased by 50%. We assumed that in 50% of adults and 75% of children severe symptoms developed and the person withdrew. An ill person could require hospitalization or die from influenza complications. The probabilities of hospitalization and death were determined on the basis of the distribution of age-specific hospitalizations and deaths in an average seasonal (nonpandemic) influenza season (22–24) and on the total hospitalization and death rates expected in a pandemic that is similar to the Asian influenza pandemic of 1957–58, for which the overall illness attack rate was estimated at 0.33, with an influenza death rate of 0.58/1,000 persons (25). A list of the initial settings of all the parameters used in these models is provided below.

The simulated epidemic started with a small number of infective persons. The transmission process continued until no further infected persons remained in the community. At the end of each simulated epidemic, the program determined the proportion of persons who became ill as well as the proportions of hospitalizations and deaths in the community. We ran 200 simulations and calculated the means of the above 3 proportions over these simulated epidemics.

Pandemic illness rates by age group (used for calibration of transmission rates and contact parameters): 0–4 years, 36%; 5–18 years, 62%; 19–64 years, 25%; >65 years, 21%; overall rate, 33%.

Probability of illness given infection = 0.67.

Relative infectiousness of infected persons who do not become ill = 0.50.

Rate of withdrawal due to "severe" symptoms: in children, 0.75; in adults, 0.50.

Relative contact rate when withdrawn due to "severe" symptoms = 0.50.

We assumed that the transmission rate (transmission probability per 1 minute of contact) might vary by the ages of the infected and susceptible persons but not by the mixing group or by weekday versus weekend day. The values of the transmission rates, which are presented in Table A1, were determined in a calibration process so that the above illness attack rates were obtained.

For the purpose of estimating the hospitalization and death probabilities, we used 9 age groups. We started with data on influenza-related hospitalization and death rates for an average seasonal influenza epidemic (22–44). We then adjusted these rates so that we obtained the predicted overall rates for a pandemic (247 and 70 per 100,000, respectively, based on Meltzer et al. [26]). To determine the conditional probabilities for ill persons we divided these rates by the expected pandemic illness rates listed in section A. The conditional probabilities are presented in Table A2.

Each LTCF resident made contacts with 4 other residents for an average of 120 minutes (on weekdays and on weekend days) and with 2 members of the LTCF staff for 120 minutes (weekdays and weekend days). In addition, this person has contact with 1 family member for 60 minutes on weekdays and with 2 family members for 120 minutes each on weekend days.

To illustrate the computation of the daily infection probabilities, we assume that person A is a susceptible school-aged child (stratum 2) who lives in a household with 2 parents (ages 19–64, stratum 3) and a younger preschool child (stratum 1). We now calculate the probability that A will become infected on a given weekday. For this illustration we make the simplifying assumption that every person with whom A makes contact is infectious on this day. Person A makes contact in the household, in his or her school and in the community.

In the household, A makes contacts lasting a total of d₂₁ = 60 minutes (Table A3) with the preschool child. The per-minute transmission rate from infectious younger child to person A is λ_{21 =} 0.00062 (Table A1). Therefore the probability that A escapes infection from that child is exp(–0.00062 x 60) = exp(–0.0372) = 0.9635. Person A also makes contact with his or her parents. The total duration of the contacts with each parent is d₂₃ = 120 minutes (Table A3), and the transmission rate from the infected parent is λ₂₃ = 0.00053 (Table A1). Therefore, the escape probability from each parent is exp (-0.00053 x 120) = 0.9384. The probability that A escapes infection from all the household members is 0.9635 x 0.9384² = 0.8485.

In the school, person A makes contact with 10 other schoolchildren (^c₂₂ (school) = 10 , where the total duration of the contacts that each child makes is 120 minutes (^d₂₂ (school) = 120). The per-minute transmission rate is ^λ₂₂ = 0.00061. Therefore the escape probability from all school contacts is [exp(-0.00061 x 120)]¹⁰ = 0.4809.

In the community, person A makes contact with 1 preschool child (^c₂₁(community) = 1 , Table A4) lasting a total of 30 minutes ( ^d₂₁(community) = 30, Table A4), and with 2 school-aged children ( ^c₂₂(community) = 2), for a total of 60 minutes each (^d₂₂(community) = 60. The per-minute transmission rates from the preschool child and from each school-aged child are ^λ₂₁ =0.00062 and ^λ₂₂ =0.00061, respectively. Hence the escape probability from all the community contacts is [exp(-0.00062 x 30)] x [exp(-0.00061 ^{x 60})]² = 0.9123.

Thus, the overall probability that person A becomes infected on this day 1- 0.8485 x 0.4809 x 0.9123 = 0.6277 is. (This very high daily probability of infection is the result of the assumption that all the persons with whom A makes contact on this day are infectious.) To determine if A actually becomes infected, a random number between 0 and 1 is generated, and if this number does not exceed 0.6277, then the simulation program determines that A becomes infected on this day.