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地铁出行在流感疫情中的作用:纽约市模拟研究。

The role of subway travel in an influenza epidemic: a New York City simulation.

机构信息

RTI International, 3040 Cornwallis Road, Research Triangle Park, NC 27709, USA.

出版信息

J Urban Health. 2011 Oct;88(5):982-95. doi: 10.1007/s11524-011-9603-4.

DOI:10.1007/s11524-011-9603-4
PMID:21826584
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3191213/
Abstract

The interactions of people using public transportation in large metropolitan areas may help spread an influenza epidemic. An agent-based model computer simulation of New York City's (NYC's) five boroughs was developed that incorporated subway ridership into a Susceptible-Exposed-Infected-Recovered disease model framework. The model contains a total of 7,847,465 virtual people. Each person resides in one of the five boroughs of NYC and has a set of socio-demographic characteristics and daily behaviors that include age, sex, employment status, income, occupation, and household location and membership. The model simulates the interactions of subway riders with their workplaces, schools, households, and community activities. It was calibrated using historical data from the 1957-1958 influenza pandemics and from NYC travel surveys. The surveys were necessary to enable inclusion of subway riders into the model. The model results estimate that if influenza did occur in NYC with the characteristics of the 1957-1958 pandemic, 4% of transmissions would occur on the subway. This suggests that interventions targeted at subway riders would be relatively ineffective in containing the epidemic. A number of hypothetical examples demonstrate this feature. This information could prove useful to public health officials planning responses to epidemics.

摘要

在大城市地区,人们使用公共交通工具的相互作用可能有助于传播流感疫情。我们开发了一个基于代理的计算机模型模拟纽约市(NYC)的五个行政区,该模型将地铁乘客量纳入了易感-暴露-感染-恢复疾病模型框架中。该模型共有 7847465 个虚拟人。每个人都居住在 NYC 的五个行政区之一,具有一系列社会人口特征和日常行为,包括年龄、性别、就业状况、收入、职业以及家庭住址和成员。该模型模拟了地铁乘客与工作场所、学校、家庭和社区活动的相互作用。它使用了来自 1957-1958 年流感大流行和 NYC 旅行调查的历史数据进行校准。这些调查对于将地铁乘客纳入模型是必要的。该模型的结果估计,如果 NYC 发生了具有 1957-1958 年大流行特征的流感疫情,4%的传播将发生在地铁上。这表明针对地铁乘客的干预措施在控制疫情方面相对无效。许多假设的例子证明了这一特征。这些信息可能对公共卫生官员规划疫情应对措施有用。

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