Improving estimates of waning immunity rates in stochastic SIRS models with a hierarchical framework

IF 8.8 3区 医学 Q1 Medicine Infectious Disease Modelling Pub Date : 2023-10-14 DOI:10.1016/j.idm.2023.10.002
Punya Alahakoon , James M. McCaw , Peter G. Taylor
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引用次数: 2

Abstract

As most disease causing pathogens require transmission from an infectious individual to a susceptible individual, continued persistence of the pathogen within the population requires the replenishment of susceptibles through births, immigration, or waning immunity.

Consider the introduction of an unknown infectious disease into a fully susceptible population where it is not known how long immunity is conferred once an individual recovers from infection. If, initially, the prevalence of disease increases (that is, the infection takes off), the number of infectives will usually decrease to a low level after the first major outbreak. During this post-outbreak period, the disease dynamics may be influenced by stochastic effects and there is a non-zero probability that the epidemic will die out. Die out in this period following the first major outbreak is known as an epidemic fade-out. If the disease does not die out, the susceptible population may be replenished by the waning of immunity, and a second wave may start.

In this study, we investigate if the rate of waning immunity (and other epidemiological parameters) can be reliably estimated from multiple outbreak data, in which some outbreaks display epidemic fade-out and others do not. We generated synthetic outbreak data from independent simulations of stochastic SIRS models in multiple communities. Some outbreaks faded-out and some did not. We conducted Bayesian parameter estimation under two alternative approaches: independently on each outbreak and under a hierarchical framework. When conducting independent estimation, the waning immunity rate was poorly estimated and biased towards zero when an epidemic fade-out was observed. However, under a hierarchical approach, we obtained more accurate and precise posterior estimates for the rate of waning immunity and other epidemiological parameters. The greatest improvement in estimates was obtained for those communities in which epidemic fade-out was observed.

Our findings demonstrate the feasibility and value of adopting a Bayesian hierarchical approach for parameter inference for stochastic epidemic models.

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用分层框架改进随机SIRS模型中免疫下降率的估计
由于大多数致病病原体需要从感染个体传播给易感个体,因此病原体在人群中的持续存在需要通过出生、移民或免疫力下降来补充易感人群。考虑将一种未知的传染病引入完全易感人群,而不知道一旦个人从感染中恢复,免疫将被赋予多长时间。如果最初疾病流行率上升(即感染开始上升),感染人数通常会在第一次大暴发后下降到较低水平。在这一爆发后时期,疾病动态可能受到随机效应的影响,疫情消失的概率非为零。在第一次重大疫情爆发后的这段时间内死亡被称为流行病消退。如果这种疾病没有消失,易感人群可能会因免疫力的减弱而得到补充,第二波浪潮可能会开始。在这项研究中,我们调查了是否可以从多个暴发数据中可靠地估计免疫力下降率(和其他流行病学参数),其中一些暴发显示流行病消退,而另一些则没有。我们从多个社区的随机SIRS模型的独立模拟中生成了综合暴发数据。有些疫情逐渐消失,有些则没有。我们在两种不同的方法下进行了贝叶斯参数估计:独立于每次爆发和在分层框架下。在进行独立估计时,对免疫率下降的估计不准确,当观察到流行病消退时,免疫率倾向于零。然而,在分层方法下,我们对免疫力下降率和其他流行病学参数获得了更准确和精确的后验估计。在那些观察到流行病逐渐消失的社区中,估计数的改善最大。我们的研究结果证明了采用贝叶斯分层方法进行随机流行病模型参数推断的可行性和价值。
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来源期刊
Infectious Disease Modelling
Infectious Disease Modelling Mathematics-Applied Mathematics
CiteScore
17.00
自引率
3.40%
发文量
73
审稿时长
17 weeks
期刊介绍: Infectious Disease Modelling is an open access journal that undergoes peer-review. Its main objective is to facilitate research that combines mathematical modelling, retrieval and analysis of infection disease data, and public health decision support. The journal actively encourages original research that improves this interface, as well as review articles that highlight innovative methodologies relevant to data collection, informatics, and policy making in the field of public health.
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