Predicting mosquito-borne disease outbreaks using poisson and negative binomial models: A comparative study

IF 4 3区医学 Q1 INFECTIOUS DISEASES

Journal of Infection and Public Health Pub Date : 2025-07-18 DOI:10.1016/j.jiph.2025.102906

Abdullah Al-Manji , Adil Al Wahaibi , Mohammed Al-Azri , Moon Fai Chan

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引用次数: 0

Abstract

Background

Dengue fever, a major mosquito-borne disease (MBD), continues to impose a growing global burden fueled by urbanization, climate change, and increased human mobility. Accurate predictive models are crucial for early detection and outbreak mitigation. This study aimed to develop and compare hierarchical models, with and without lagged predictors, for forecasting dengue cases in Oman.

Methods

A retrospective analysis was conducted using weekly data from 2020 to 2024 across multiple districts. Predictors included climate variables (temperature, humidity, wind, rainfall), mosquito surveillance indicators (trap positivity, mosquito density), and population demographics. Four hierarchical Bayesian models were developed: Poisson without lag, Poisson with lag, Negative Binomial without lag, and Negative Binomial with lag. Models incorporated fixed effects and random intercepts for epidemiological week, district, governorate, year, and seasonal components. Model performance was evaluated through convergence diagnostics, Mean Squared Error (MSE), Area Under the Curve (AUC), confusion matrices, and Leave-One-Out Information Criterion (LOOIC).

Results

All models demonstrated excellent convergence and fit the historical weekly data (2020–2024) accurately. The Negative Binomial model with lagged variables performed best, achieving the highest AUC (0.881, 95 % CI: 0.858–0.902), the lowest LOOIC (3234.6 ± 109.4), and the smallest MSE. Mosquito trap positivity was consistently the strongest predictor, while wind speed showed a moderate positive effect and temperature showed significant delayed negative effects. Rainfall, humidity, and population size were not significant predictors. Importantly, short-term forecasts for the first weeks of 2025 closely matched the observed case counts, confirming that the models’ prediction metrics reflected both retrospective fit and real-world forecasting performance.

Conclusions

Incorporating delayed climatic and entomological factors using a Negative Binomial hierarchical framework significantly enhanced dengue outbreak prediction in Oman. The findings support the integration of lagged predictors and hierarchical modeling into early warning systems for mosquito-borne diseases, facilitating timely public health interventions and improved outbreak preparedness.

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用泊松和负二项模型预测蚊媒疾病暴发：一项比较研究

登革热是一种主要的蚊媒疾病（MBD），在城市化、气候变化和人类流动性增加的推动下，登革热继续给全球带来越来越大的负担。准确的预测模型对于早期发现和缓解疫情至关重要。这项研究旨在开发和比较有滞后预测因子和没有滞后预测因子的分层模型，用于预测阿曼的登革热病例。方法采用2020 - 2024年多区每周数据进行回顾性分析。预测因子包括气候变量（温度、湿度、风、降雨）、蚊虫监测指标（诱蚊器阳性率、蚊虫密度）和人口统计数据。建立了无滞后泊松模型、带滞后泊松模型、无滞后负二项模型和带滞后负二项模型。模型纳入了流行病学周、地区、省、年份和季节组成部分的固定效应和随机截点。通过收敛诊断、均方误差（MSE）、曲线下面积（AUC）、混淆矩阵和遗漏信息准则（LOOIC）来评估模型的性能。结果各模型均具有较好的收敛性，能较好地拟合2020-2024年的周数据。具有滞后变量的负二项模型表现最好，AUC最高（0.881,95 % CI: 0.858-0.902）， LOOIC最低（3234.6±109.4），MSE最小。诱蚊器的积极性始终是最强的预测因子，而风速表现出中等的积极影响，温度表现出显著的延迟性消极影响。降雨量、湿度和种群规模不是显著的预测因子。重要的是，2025年头几周的短期预测与观察到的病例数非常吻合，证实了模型的预测指标既反映了回顾性拟合，也反映了现实世界的预测性能。结论利用负二项分级框架综合延迟气候和昆虫学因素，显著提高了对阿曼登革热疫情的预测。这些发现支持将滞后预测因子和分层模型整合到蚊媒疾病的早期预警系统中，促进及时的公共卫生干预和改进疫情防范。

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

Journal of Infection and Public Health PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH -INFECTIOUS DISEASES

CiteScore

13.10

自引率

1.50%

发文量

203

审稿时长

96 days

期刊介绍： The Journal of Infection and Public Health, first official journal of the Saudi Arabian Ministry of National Guard Health Affairs, King Saud Bin Abdulaziz University for Health Sciences and the Saudi Association for Public Health, aims to be the foremost scientific, peer-reviewed journal encompassing infection prevention and control, microbiology, infectious diseases, public health and the application of healthcare epidemiology to the evaluation of health outcomes. The point of view of the journal is that infection and public health are closely intertwined and that advances in one area will have positive consequences on the other. The journal will be useful to all health professionals who are partners in the management of patients with communicable diseases, keeping them up to date. The journal is proud to have an international and diverse editorial board that will assist and facilitate the publication of articles that reflect a global view on infection control and public health, as well as emphasizing our focus on supporting the needs of public health practitioners. It is our aim to improve healthcare by reducing risk of infection and related adverse outcomes by critical review, selection, and dissemination of new and relevant information in the field of infection control, public health and infectious diseases in all healthcare settings and the community.