2025年广州市冬春季蚊虫孳生情况及其影响因素分析

doi:10.12183/j.scjpm.2026.0248

华南预防医学 ›› 2026, Vol. 52 ›› Issue (3): 248-252.doi: 10.12183/j.scjpm.2026.0248

2025年广州市冬春季蚊虫孳生情况及其影响因素分析

周金华, 何时雨, 程志飞, 李晓宁, 江毅民, 刘通, 李魁彪

广州市疾病预防控制中心（广州市卫生监督所）消毒与病媒生物防制部,广东广州 510440

收稿日期:2025-07-09 出版日期:2026-03-20 发布日期:2026-04-07
通讯作者: 李魁彪,E-mail：kuibiao@outlook.com
作者简介:周金华（1988—）,男,硕士研究生,副主任医师,主要从事病媒生物监测与防制工作
基金资助:
广州市卫生健康科技一般引导项目（20241A011067）; 广州市科技计划项目（2023A03J0454）; 广州市医学重点学科（2025—2027-11）

Analysis of mosquito breeding conditions and influencing factors in Guangzhou during the winter and spring of 2025

Zhou Jinhua, He Shiyu, Cheng Zhifei, Li Xiaoning, Jiang Yimin, Liu Tong, Li Kuibiao

Department of Disinfection and Vector Control, Guangzhou Center for Disease Control and Prevention (Guangzhou Health Supervision Institute), Guangzhou, Guangdong 510440, China

Received:2025-07-09 Online:2026-03-20 Published:2026-04-07

摘要/Abstract

摘要： 目的了解广州市冬春季蚊虫孳生地现状,并研究其影响因素,为冬春季蚊虫的防制提供科学依据。方法 2025年1—2月在广州市采集室外各类容器内积水,同时记录采样的环境类型、积水容器类型、水质情况、气象条件（温度和湿度）等,送实验室孵化和鉴定蚊虫,比较不同环境类型、容器类型、积水类型和水质情况等的蚊虫孵化情况,采用二元logistic回归模型分析蚊虫孵化阳性率的影响因素。结果共采集水样979份,其中白纹伊蚊和库蚊的孵化阳性率分别为4.49%（44份）和3.88%（38份）。单因素分析结果显示不同区域、环境类型、容器类型、水质情况和采样时积水容器周边有无成蚊停落的白纹伊蚊孵化阳性率差异均有统计学意义（均P<0.05）;环境类型、水质情况和采样时积水容器周边有无成蚊停落的库蚊孵化阳性率差异均有统计学意义（均P<0.05）;不同温度和湿度的白纹伊蚊和库蚊孵化阳性率差异均无统计学意义（均P>0.05）。二元logistic回归分析结果显示,城镇蚊虫孳生地白纹伊蚊孵化阳性率低于郊区（RR=0.515）;盆景、水生植物的孵化阳性率高于闲置容器（RR=2.682）;浑浊水体的白纹伊蚊孵化阳性率高于清澈水体（RR=3.380）;采样时有成蚊停落于积水容器周边白纹伊蚊孵化阳性率高于没有成蚊停落（RR=4.422）。相对于城镇居民区,农村自然村（RR=3.420）和其他环境（RR=3.010）的蚊虫孳生地库蚊孵化阳性率较高;浑浊水体库蚊孵化阳性率高于清澈水体（RR=2.215）;采样时有成蚊停落于积水容器周边库蚊孵化阳性率高于没有成蚊停落（RR=3.949）（均P<0.05）。结论应加强冬春季蚊虫孳生地监测,积极做好盆景、水生植物等重点蚊虫孳生地的清理,为全年蚊虫的控制打下坚实的基础。

关键词: 白纹伊蚊, 库蚊, 越冬, 孳生地, 孵化阳性率

Abstract: Objective To investigate the current status of overwintering mosquito breeding sites in Guangzhou and analyze their influencing factors, so as to provid a scientific basis for mosquito control during the overwintering period. Methods During January and February in 2025, stagnant water from various outdoor containers in Guangzhou was collected. Concurrently, environmental factors such as the sampling site type, container type, water quality, and meteorological conditions (temperature and humidity) were recorded.The collected water samples were then transported to laboratory for mosquito incubation and species identification.The hatching rates of mosquitoes were compared across different environment types, container types, water types, and water quality conditions. Logistic regression analysis was employed to assess the influencing factors on the positivity rate of mosquito hatching. Results A total of 979 water samples were collected, with a hatching positive rate of 4.49% for Aedes albopictus and 3.88% for Culex. Univariate analysis revealed that the Aedes albopictus hatch positive rates showed statistically significant differences across different regions, environmental types, container types, water quality conditions, and the presence or absence of adult mosquitoes resting around the water containers during sampling (P<0.05). Similarly, the Culex hatch positive rates showed statistically significant differences across different environmental types, water quality conditions, and the presence or absence of adult mosquitoes resting around the water containers during sampling (P<0.05). There was no statistically significant difference in the positive hatching rates of Aedes albopictus and Culex mosquitoes at different temperatures and humidity levels (P>0.05). Binary logistic regression analysis showed that the hatching positive rate of Aedes albopictus in urban breeding sites was significantly lower than in suburban areas (RR=0.515). Containers with potted plants, aquatic plants or aquatic vegetation had a higher likelihood of Aedes albopictus breeding compared to idle containers (RR=2.682). The hatching positive rate was higher in turbid water than in clear water (RR=3.380). Samples collected from water containers with adult mosquitoes resting nearby had a higher Aedes albopictus positive rate than those without (RR=4.422). Compared to urban residential areas, rural villages (RR=3.420) and other environments (RR=3.010) exhibited significantly higher Culex hatching positive rates in breeding sites. Turbid water bodies showed a higher Culex hatching positive rate than clear water (RR=2.215). Water samples collected from containers with adult mosquitoes resting nearby had a higher Culex hatching positive rate than those without (RR=3.949). Conclusion It is essential to enhance the monitoring of overwintering mosquito breeding sites. Proactively remove potential mosquito breeding grounds, including potted plants and aquatic plants. These efforts will lay a solid foundation for effective mosquito control throughout the year.

Key words: Aedes albopictus, Culex, Overwintering, Breeding sites, Hatch positive rates

中图分类号:

R195.4

周金华, 何时雨, 程志飞, 李晓宁, 江毅民, 刘通, 李魁彪. 2025年广州市冬春季蚊虫孳生情况及其影响因素分析[J]. 华南预防医学, 2026, 52(3): 248-252.

Zhou Jinhua, He Shiyu, Cheng Zhifei, Li Xiaoning, Jiang Yimin, Liu Tong, Li Kuibiao. Analysis of mosquito breeding conditions and influencing factors in Guangzhou during the winter and spring of 2025[J]. South China Journal of Preventive Medicine, 2026, 52(3): 248-252.

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2025年广州市冬春季蚊虫孳生情况及其影响因素分析

Analysis of mosquito breeding conditions and influencing factors in Guangzhou during the winter and spring of 2025

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