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季节性流感在偏远岛屿人群中的传播动力学。

Transmission dynamics of seasonal influenza in a remote island population.

机构信息

School of Tropical Medicine and Global Health, Nagasaki University, Nagasaki, Japan.

Department of Infectious Disease Epidemiology, Faculty of Epidemiology and Population Health, London School of Hygiene and Tropical Medicine, London, UK.

出版信息

Sci Rep. 2023 Apr 3;13(1):5393. doi: 10.1038/s41598-023-32537-0.

DOI:10.1038/s41598-023-32537-0
PMID:37012350
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10068240/
Abstract

Seasonal influenza outbreaks remain an important public health concern, causing large numbers of hospitalizations and deaths among high-risk groups. Understanding the dynamics of individual transmission is crucial to design effective control measures and ultimately reduce the burden caused by influenza outbreaks. In this study, we analyzed surveillance data from Kamigoto Island, Japan, a semi-isolated island population, to identify the drivers of influenza transmission during outbreaks. We used rapid influenza diagnostic test (RDT)-confirmed surveillance data from Kamigoto island, Japan and estimated age-specific influenza relative illness ratios (RIRs) over eight epidemic seasons (2010/11 to 2017/18). We reconstructed the probabilistic transmission trees (i.e., a network of who-infected-whom) using Bayesian inference with Markov-chain Monte Carlo method and then performed a negative binomial regression on the inferred transmission trees to identify the factors associated with onwards transmission risk. Pre-school and school-aged children were most at risk of getting infected with influenza, with RIRs values consistently above one. The maximal RIR values were 5.99 (95% CI 5.23, 6.78) in the 7-12 aged-group and 5.68 (95%CI 4.59, 6.99) in the 4-6 aged-group in 2011/12. The transmission tree reconstruction suggested that the number of imported cases were consistently higher in the most populated and busy districts (Tainoura-go and Arikawa-go) ranged from 10-20 to 30-36 imported cases per season. The number of secondary cases generated by each case were also higher in these districts, which had the highest individual reproduction number (R: 1.2-1.7) across the seasons. Across all inferred transmission trees, the regression analysis showed that cases reported in districts with lower local vaccination coverage (incidence rate ratio IRR = 1.45 (95% CI 1.02, 2.05)) or higher number of inhabitants (IRR = 2.00 (95% CI 1.89, 2.12)) caused more secondary transmissions. Being younger than 18 years old (IRR = 1.38 (95%CI 1.21, 1.57) among 4-6 years old and 1.45 (95% CI 1.33, 1.59) 7-12 years old) and infection with influenza type A (type B IRR = 0.83 (95% CI 0.77, 0.90)) were also associated with higher numbers of onwards transmissions. However, conditional on being infected, we did not find any association between individual vaccination status and onwards transmissibility. Our study showed the importance of focusing public health efforts on achieving high vaccine coverage throughout the island, especially in more populated districts. The strong association between local vaccine coverage (including neighboring regions), and the risk of transmission indicate the importance of achieving homogeneously high vaccine coverage. The individual vaccine status may not prevent onwards transmission, though it may reduce the severity of infection.

摘要

季节性流感爆发仍然是一个重要的公共卫生问题,会导致高危人群住院和死亡人数增加。了解个体传播的动态对于设计有效的控制措施至关重要,最终可以减少流感爆发造成的负担。在这项研究中,我们分析了日本神户岛的监测数据,该岛是一个半隔离的岛屿人群,以确定在爆发期间流感传播的驱动因素。我们使用了来自日本神户岛的快速流感诊断检测(RDT)确认的监测数据,并在八个流行季节(2010/11 至 2017/18 年)估计了特定年龄的流感相对发病率(RIR)。我们使用贝叶斯推理和马尔可夫链蒙特卡罗方法重建了概率传播树(即谁感染了谁的网络),然后对推断的传播树进行了负二项式回归,以确定与传播风险相关的因素。学龄前和学龄儿童感染流感的风险最高,RIR 值持续高于 1。2011/12 年,7-12 岁年龄组的最大 RIR 值为 5.99(95%CI 5.23,6.78),4-6 岁年龄组为 5.68(95%CI 4.59,6.99)。传播树重建表明,人口最多和最繁忙的地区(田浦区和有川区)的输入病例数量一直较高,每个季节输入病例数量为 10-20 至 30-36 例。这些地区产生的二级病例数量也较高,其个体繁殖数(R:1.2-1.7)在整个季节中最高。在所有推断的传播树中,回归分析表明,在当地疫苗接种率较低(发病率比 IRR=1.45(95%CI 1.02,2.05))或居民人数较多(IRR=2.00(95%CI 1.89,2.12))的地区报告的病例会导致更多的二次传播。年龄小于 18 岁(4-6 岁年龄组的发病率比 IRR=1.38(95%CI 1.21,1.57),7-12 岁年龄组的发病率比 IRR=1.45(95%CI 1.33,1.59))和感染甲型流感(B 型流感的发病率比 IRR=0.83(95%CI 0.77,0.90))也与更多的继发传播有关。然而,在感染的情况下,我们没有发现个体疫苗接种状况与传播能力之间存在任何关联。我们的研究表明,集中精力提高整个岛屿的疫苗接种覆盖率,特别是在人口较多的地区,对公共卫生工作非常重要。当地疫苗接种覆盖率(包括邻近地区)与传播风险之间的强烈关联表明,实现均匀高疫苗接种覆盖率非常重要。个体疫苗接种状况可能无法阻止继发传播,但可以减轻感染的严重程度。

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