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识别智利南部不同社区类型中与钩端螺旋体病的动物宿主、环境及社会人口统计学相关的驱动因素:基于“同一健康”视角的机器学习算法应用

Identifying the Drivers Related to Animal Reservoirs, Environment, and Socio-Demography of Human Leptospirosis in Different Community Types of Southern Chile: An Application of Machine Learning Algorithm in One Health Perspective.

作者信息

Talukder Himel, Muñoz-Zanzi Claudia, Salgado Miguel, Berg Sergey, Yang Anni

机构信息

Department of Geography and Environmental Sustainability, University of Oklahoma, Norman, OK 73019, USA.

Division of Environmental Health Sciences, School of Public Health, University of Minnesota, Minneapolis, MN 55454, USA.

出版信息

Pathogens. 2024 Aug 14;13(8):687. doi: 10.3390/pathogens13080687.

DOI:10.3390/pathogens13080687
PMID:39204287
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11357164/
Abstract

Leptospirosis is a zoonosis with global public health impact, particularly in poor socio-economic settings in tropical regions. Transmitted through urine-contaminated water or soil from rodents, dogs, and livestock, leptospirosis causes over a million clinical cases annually. Risk factors include outdoor activities, livestock production, and substandard housing that foster high densities of animal reservoirs. This One Health study in southern Chile examined serological evidence of exposure in people from urban slums, semi-rural settings, and farm settings, using the Extreme Gradient Boosting algorithm to identify key influencing factors. In urban slums, age, shrub terrain, distance to -positive households, and neighborhood housing density were contributing factors. Human exposure in semi-rural communities was linked to environmental factors (trees, shrubs, and lower vegetation terrain) and animal variables (-positive dogs and rodents and proximity to -positive households). On farms, dog counts, animal prevalence, and proximity to -contaminated water samples were significant drivers. The study underscores that disease dynamics vary across landscapes, with distinct drivers in each community setting. This case study demonstrates how the integration of machine learning with comprehensive cross-sectional epidemiological and geospatial data provides valuable insights into leptospirosis eco-epidemiology. These insights are crucial for informing targeted public health strategies and generating hypotheses for future research.

摘要

钩端螺旋体病是一种对全球公共卫生有影响的人畜共患病,在热带地区社会经济条件较差的环境中尤为突出。它通过受啮齿动物、狗和牲畜尿液污染的水或土壤传播,每年导致超过100万例临床病例。风险因素包括户外活动、畜牧生产以及滋生高密度动物宿主的不合标准住房。智利南部的这项“同一健康”研究,使用极端梯度提升算法来识别关键影响因素,检测了城市贫民窟、半农村地区和农场地区人群的血清学暴露证据。在城市贫民窟,年龄、灌木地形、与阳性家庭的距离以及邻里住房密度是影响因素。半农村社区的人类暴露与环境因素(树木、灌木和较低植被地形)以及动物变量(阳性狗和啮齿动物以及与阳性家庭的接近程度)有关。在农场,狗的数量、动物患病率以及与受污染水样的接近程度是重要驱动因素。该研究强调,疾病动态在不同地区有所不同,每个社区环境都有不同的驱动因素。本案例研究展示了机器学习与全面的横断面流行病学和地理空间数据相结合,如何为钩端螺旋体病生态流行病学提供有价值的见解。这些见解对于制定有针对性的公共卫生策略和为未来研究提出假设至关重要。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/eb20/11357164/9062b8f542e3/pathogens-13-00687-g006.jpg
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