Assessing the Impacts of Meteorological Factors on COVID-19 Pandemic Using Generalized Estimating Equations

Shengnan Lin; Jia Rui; Fang Xie; Meirong Zhan; Qiuping Chen; Bin Zhao; Yuanzhao Zhu; Zhuoyang Li; Bin Deng; Shanshan Yu; An Li; Yanshu Ke; Wenwen Zeng; Yanhua Su; Yi-Chen Chiang; Tianmu Chen

doi:10.3389/fpubh.2022.920312

Assessing the Impacts of Meteorological Factors on COVID-19 Pandemic Using Generalized Estimating Equations

Front Public Health. 2022 Jul 1:10:920312. doi: 10.3389/fpubh.2022.920312. eCollection 2022.

Authors

Shengnan Lin¹, Jia Rui^{1

2}, Fang Xie¹, Meirong Zhan³, Qiuping Chen^{1

2}, Bin Zhao⁴, Yuanzhao Zhu¹, Zhuoyang Li¹, Bin Deng¹, Shanshan Yu¹, An Li¹, Yanshu Ke¹, Wenwen Zeng¹, Yanhua Su¹, Yi-Chen Chiang¹, Tianmu Chen¹

Affiliations

¹ School of Public Health, Xiamen University, Xiamen, China.
² Cirad, UMR 17, Intertryp, Université de Montpellier, Montpellier, France.
³ Fujian Provincial Center for Disease Control and Prevention, Fuzhou, China.
⁴ Clinical Medical Laboratory, Xiang'an Hospital of Xiamen University, Xiamen, China.

Abstract

Background: Meteorological factors have been proven to affect pathogens; both the transmission routes and other intermediate. Many studies have worked on assessing how those meteorological factors would influence the transmissibility of COVID-19. In this study, we used generalized estimating equations to evaluate the impact of meteorological factors on Coronavirus disease 2019 (COVID-19) by using three outcome variables, which are transmissibility, incidence rate, and the number of reported cases.

Methods: In this study, the data on the daily number of new cases and deaths of COVID-19 in 30 provinces and cities nationwide were obtained from the provincial and municipal health committees, while the data from 682 conventional weather stations in the selected provinces and cities were obtained from the website of the China Meteorological Administration. We built a Susceptible-Exposed-Symptomatic-Asymptomatic-Recovered/Removed (SEIAR) model to fit the data, then we calculated the transmissibility of COVID-19 using an indicator of the effective reproduction number (R_eff ). To quantify the different impacts of meteorological factors on several outcome variables including transmissibility, incidence rate, and the number of reported cases of COVID-19, we collected panel data and used generalized estimating equations. We also explored whether there is a lag effect and the different times of meteorological factors on the three outcome variables.

Results: Precipitation and wind speed had a negative effect on transmissibility, incidence rate, and the number of reported cases, while humidity had a positive effect on them. The higher the temperature, the lower the transmissibility. The temperature had a lag effect on the incidence rate, while the remaining five meteorological factors had immediate and lag effects on the incidence rate and the number of reported cases.

Conclusion: Meteorological factors had similar effects on incidence rate and number of reported cases, but different effects on transmissibility. Temperature, relative humidity, precipitation, sunshine hours, and wind speed had immediate and lag effects on transmissibility, but with different lag times. An increase in temperature may first cause a decrease in virus transmissibility and then lead to a decrease in incidence rate. Also, the mechanism of the role of meteorological factors in the process of transmissibility to incidence rate needs to be further explored.

Keywords: COVID-19; generalized estimating equations; lagged effect; meteorological factors; transmissibility.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

COVID-19* / epidemiology
Humans
Humidity
Meteorological Concepts
Pandemics*
Weather