Abstract
In the absence of drugs and vaccines, policymakers use non-pharmaceutical interventions such as social distancing to decrease rates of disease-causing contact, with the aim of reducing or delaying the epidemic peak. These measures carry social and economic costs, so societies may be unable to maintain them for more than a short period of time. Intervention policy design often relies on numerical simulations of epidemic models, but comparing policies and assessing their robustness demands clear principles that apply across strategies. Here we derive the theoretically optimal strategy for using a time-limited intervention to reduce the peak prevalence of a novel disease in the classic Susceptible-Infectious-Recovered epidemic model. We show that broad classes of easier-to-implement strategies can perform nearly as well as the theoretically optimal strategy. But neither the optimal strategy nor any of these near-optimal strategies is robust to implementation error: small errors in timing the intervention produce large increases in peak prevalence. Our results reveal fundamental principles of non-pharmaceutical disease control and expose their potential fragility. For robust control, an intervention must be strong, early, and ideally sustained.
Highlights
In the absence of drugs and vaccines, policymakers use non-pharmaceutical interventions such as social distancing to decrease rates of disease-causing contact, with the aim of reducing or delaying the epidemic peak
Policy design for allocating non-pharmaceutical resources during the COVID-19 pandemic relied heavily on numerical simulations of epidemic models[10,11]; it is difficult to compare predictions or assess robustness without broad principles that apply across strategies
We consider the standard SIR epidemic model[21], which describes the fractions of susceptible S(t), infectious I(t), and recovered R(t) individuals in the population at time t22
Summary
In the absence of drugs and vaccines, policymakers use non-pharmaceutical interventions such as social distancing to decrease rates of disease-causing contact, with the aim of reducing or delaying the epidemic peak These measures carry social and economic costs, so societies may be unable to maintain them for more than a short period of time. In the absence of drugs and vaccines, mitigation efforts to reduce or delay the peak (flattening the curve7,8) rely on nonpharmaceutical interventions[9] such as social distancing[10] that decrease rates of disease-transmitting contact These measures carry social and economic costs, and so societies may be unable to maintain them for more than a short period of time. A number of studies of COVID-19 have used optimal control theory—an approach that relies on numerical optimization to study continuous error correction[15,16]
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