Predator-Prey Trophic Interactions and Seasonality of Highly Pathogenic Avian Influenza Virus in Denmark, 2016-2023.

IF 2.3 2区农林科学 Q3 INFECTIOUS DISEASES

Zoonoses and Public Health Pub Date : 2025-10-14 DOI:10.1111/zph.70019

Gemma Hancock, Carsten Kirkeby, Lene Jung Kjær, Timme Nyegaard, Anette Ella Boklund, Michael P Ward

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引用次数: 0

Abstract

Introduction: Trophic interactions between populations of birds are assumed to facilitate the transmission of highly pathogenic avian influenza virus (HPAIV). However, evidence from the field is lacking to support the hypothesis of trophic AIV transmission.

Methods: We compared the timing of predatory versus prey wild bird HPAIV cases reported in Denmark (primarily via passive surveillance) between 2016 and 2023. We classified the species reported as 'predator' (case) or 'prey' (control). Spatial clusters of predator reports were identified using the scan statistic. Logistic regression models were fit.

Results: Predator species were found more likely to be reported as HPAIV cases in winter (odds ratio (OR) 5.7, 95% confidence interval (CI) 2.4-13.8), spring (14.1, 5.8-34.5) and summer (10.2, 2.1-49.6) than in autumn. Controlling for temporal (year of report) and spatial clustering, the estimated risk of predator reports increased in winter (12.1, 3.7-39.2) and spring (OR 21.5, 5.8-79.6) compared to autumn.

Conclusions: Our results suggest that predator species become infected later during the transmission season than prey species, which has implications for the design of HPAIV surveillance systems. For example, in active surveillance resources could be more focused on prey species in autumn, and predator species in winter and spring. Likewise, in passive surveillance public messaging could reflect this species shift. The sensitivity of surveillance might further be increased by considering potential seasonal changes in the spatial distribution of species affected by HPAIV.

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2016-2023年丹麦高致病性禽流感病毒的食饵-食饵营养相互作用和季节性

鸟类种群之间的营养相互作用被认为促进了高致病性禽流感病毒（HPAIV）的传播。然而，缺乏实地证据来支持营养性AIV传播的假设。方法：我们比较了2016年至2023年丹麦报告的捕食性和被食性野鸟HPAIV病例的时间（主要通过被动监测）。我们将报告的物种分为“捕食者”（病例）和“猎物”（对照）。利用扫描统计量确定捕食者报告的空间集群。Logistic回归模型拟合。结果：捕食者在冬季（优势比（OR） 5.7, 95%可信区间（CI） 2.4 ~ 13.8）、春季（14.1,5.8 ~ 34.5）和夏季（10.2,2.1 ~ 49.6）报告HPAIV病例的可能性大于秋季。控制时间（报告年份）和空间聚类，与秋季相比，冬季（12.1,3.7-39.2）和春季（21.5,5.8-79.6）捕食者报告的估计风险增加。结论：本研究结果提示，在传播季节，捕食者比被捕食者更晚感染HPAIV，这对HPAIV监测系统的设计具有指导意义。例如，在主动监测中，资源可以更多地集中在秋季的猎物种类上，而在冬季和春季的捕食者种类上。同样，在被动监控中，公共信息可以反映这种物种转变。通过考虑受HPAIV影响的物种空间分布的潜在季节性变化，可以进一步提高监测的敏感性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Zoonoses and Public Health 医学-传染病学

CiteScore

5.30

自引率

4.20%

发文量

115

审稿时长

6-12 weeks

期刊介绍： Zoonoses and Public Health brings together veterinary and human health researchers and policy-makers by providing a venue for publishing integrated and global approaches to zoonoses and public health. The Editors will consider papers that focus on timely collaborative and multi-disciplinary research in zoonoses and public health. This journal provides rapid publication of original papers, reviews, and potential discussion papers embracing this collaborative spirit. Papers should advance the scientific knowledge of the sources, transmission, prevention and control of zoonoses and be authored by scientists with expertise in areas such as microbiology, virology, parasitology and epidemiology. Articles that incorporate recent data into new methods, applications, or approaches (e.g. statistical modeling) which enhance public health are strongly encouraged.