Abstract
To help health policy makers gain response time to mitigate infectious disease threats, it is essential to have an efficient epidemic surveillance. One common method of disease surveillance is to carefully select nodes (sentinels, or sensors) in the network to report outbreaks. One would like to choose sentinels so that they discover the outbreak as early as possible. The optimal choice of sentinels depends on the network structure. Studies have addressed this problem for static networks, but this is a first step study to explore designing surveillance systems for early detection on temporal networks. This paper is based on the idea that vaccination strategies can serve as a method to identify sentinels. The vaccination problem is a related question that is much more well studied for temporal networks. To assess the ability to detect epidemic outbreaks early, we calculate the time difference (lead time) between the surveillance set and whole population in reaching 1% prevalence. We find that the optimal selection of sentinels depends on both the network’s temporal structures and the infection probability of the disease. We find that, for a mild infectious disease (low infection probability) on a temporal network in relation to potential disease spreading (the Prostitution network), the strategy of selecting latest contacts of random individuals provide the most amount of lead time. And for a more uniform, synthetic network with community structure the strategy of selecting frequent contacts of random individuals provide the most amount of lead time.
Highlights
To help health policy makers gain response time to mitigate infectious disease threats, it is essential to have an efficient epidemic surveillance
To evaluate our four surveillance strategies on the four temporal networks, we start by analyzing the lead time obtained from simulating SI epidemic model
To design surveillance systems for the early detection of infectious disease outbreak it is important to optimize the set of surveillance sentinels
Summary
To help health policy makers gain response time to mitigate infectious disease threats, it is essential to have an efficient epidemic surveillance. Some traditional surveillance systems, such as the Hong Kong Centers for Health Protection (HP) and the United Kingdom Health Protection Agency (HPA), are based on hospital systems They monitor individuals who see a doctor in sentinel hospitals and report their incidence of infectious disease for early detection[17]. Previous research has designed surveillance strategies for early detection of infectious disease based on topological structures of static contact networks. 11 compared three surveillance strategies (selecting individuals with the highest degree, individuals randomly and friends of random individuals) on three classes of static contact networks (networks with power-law degree distribution, Poisson degree distribution and community structure) They found the optimal strategy depends on the network structures and the basic reproduction number of the disease. Contact networks have topological structures, and temporal structures (e.g., cyclic ones—an individual meeting a friend on a daily basis)[14]
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