Abstract
BackgroundThe effects of extreme temperature on infectious diseases are complex and far-reaching. There are few studies to access the relationship of pulmonary tuberculosis (PTB) with extreme temperature. The study aimed to identify whether there was association between extreme temperature and the reported morbidity of PTB in Shandong Province, China, from 2005 to 2016.MethodsA generalized additive model (GAM) was firstly conducted to evaluate the relationship between daily reported incidence rate of PTB and extreme temperature events in the prefecture-level cities. Then, the effect estimates were pooled using meta-analysis at the provincial level. The fixed-effect model or random-effect model was selected based on the result of heterogeneity test.ResultsAmong the 446,016 PTB reported cases, the majority of reported cases occurred in spring. The higher reported incidence rate areas were located in Liaocheng, Taian, Linyi and Heze. Extreme low temperature had an impact on the reported incidence of PTB in only one prefecture-level city, i.e., Binzhou (RR = 0.903, 95% CI: 0.817–0.999). While, extreme high temperature was found to have a positive effect on reported morbidity of PTB in Binzhou (RR = 0.924, 95% CI: 0.856–0.997) and Weihai (RR = 0.910, 95% CI: 0.843–0.982). Meta-analysis showed that extreme high temperature was associated with a decreased risk of PTB (RR = 0.982, 95% CI: 0.966–0.998). However, extreme low temperature was no relationship with the reported incidence of PTB.ConclusionOur findings are suggested that extreme high temperature has significantly decreased the risk of PTB at the provincial levels. The findings have implications for developing strategies to response to climate change.
Highlights
The effects of extreme temperature on infectious diseases are complex and far-reaching
In 14 prefecture-level cities, average surface temperature (AST), average air pressure (AAP), daily maximum air pressure (DMAP), daily minimum air pressure (DMIP), average temperature (AT), daily maximum temperature (DMAT) and daily minimum temperature (DMIT) were strongly correlated with each other (|r| > 0.7)
Strong correlations were detected between average relative humidity (ARH) and minimum relative humidity (MRH), between average wind speed (AWS) and maximum wind speed (MWS), with the absolute value of r lager than 0.7
Summary
The effects of extreme temperature on infectious diseases are complex and far-reaching. Global climate change is one of the biggest challenges which the world is facing, and the problem is the focus of the global community [1]. It is well-known that climate change threatens natural and human systems [2]. According to the assessment reports of the Intergovernmental Panel on Climate Change (IPCC), global climate change, such as climate warming and the increasing frequency of extreme weather events, has become an indisputable fact. The health effects of extreme temperature including extreme high temperature and extreme low temperature, as an extreme weather event, are complex and far-reaching. Extreme temperature has an impact on infectious diseases, such as mumps [10], hand-foot-mouth disease [11], etc
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