Case-crossover study on association between temperature and non-accidental mortality in Tibet Plateau, China

Guoxia Bai; Junle WU; Heng Shi; Zhuoma Pingcuo; Yajie LI; Cangjue Gama; Jianxiong HU; Zhixing LI; Tao Liu; Wenjun MA

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Case-crossover study on association between temperature and non-accidental mortality in Tibet Plateau, China

VernacularTitle:西藏高原地区气温对人群非意外死亡影响的病例交叉研究
Author: Guoxia BAI ¹ ; Junle WU ² ; Heng SHI ¹ ; Zhuoma PINGCUO ¹ ; Yajie LI ¹ ; Cangjue GAMA ¹ ; Jianxiong HU ² ; Zhixing LI ³ ; Tao LIU ³ ; Wenjun MA ^{3
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Author Information

1. Institute of Non-communicable Diseases Prevention and Control, Tibet Center for Disease Control and Prevention, Lhasa, Tibet 850002, China.
2. Guangdong Provincial Institute of Public Health, Guangdong Provincial Center for Disease Control and Prevention, Guangzhou, Guangdong 511430, China.
3. School of Medicine, Jinan University, Guangzhou, Guangdong 510632, China.
4. Guangdong Provincial Institute of Public Health, Guangdong Provincial Center for Disease Control and Prevention, Guangzhou, Guangdong 511430, China
Publication Type:Specialcolumn:Mechanismsunderlyinghumanhealtheffectsofclimatechange
Keywords: Tibet; temperature; mortality risk; vulnerable population; case-crossover study
From: Journal of Environmental and Occupational Medicine 2022;39(3):261-267
CountryChina
Language:Chinese
Abstract: Background Under the background of global climate change, temperature has increased dramatically. Most studies about association between temperature and human health are conducted in low-altitude areas, but rarely focus on plateau areas. Objective To examine the association between temperature and non-accidental mortality risk in Tibet Plateau, China and to identify vulnerable populations for formulating targeted policies of climate change adaptation. Methods The mortality data, meteorological data, and pollutant data of Tibet area between 2013 to 2019 were collected. Based on time-stratified case-crossover design, conditional logistic regression models were used to analyze the exposure-response relationship between temperature and cause-specific mortality, which was linearized to obtain excess risk for 1 ℃ change; attributable fraction was calculated for assessing burden attributable to temperature; and stratified analyses were further conducted by gender, age (＜65 years old, ≥65 years old), and causes of death (cardiovascular diseases, cerebrovascular diseases, and respiratory diseases). Sensitivity analyses were conducted by adjusting model parameters and variables. Results A total of 26 045 non-accidental deaths were collected in Tibet during 2013 and 2019, and the P₅₀ of temperature was 5.0 ℃. The non-accidental mortality risk increased as temperature become colder. A 1 ℃ decrease in temperature was associated with a 2.01% (95%CI: 0.94%-3.07%) increase in total non-accidental mortality, while the association changed to 2.05% (95%CI: 0.62%-3.47%) for male and 1.96% (95%CI: 0.34%-3.56%) for female, both of statistial significance; 1.45% (95%CI: −0.10%-2.98%) for the people <65 years old (not of significance) and 2.52% (95% CI : 1.04%-3.99%) for the people ≥65 years old (of significance); the excess risk for cardiovascular mortality was 2.65% (95%CI: 1.03%-4.24%), for cerebrovascular mortality was 3.70% (95%CI: 0.74%-6.57%), both of statistical significance, and for respiratory mortality was 2.18% (95%CI: −0.14%-4.44%), without significance. The total attribution number of non-accidental mortality was 5340 (95%CI: 2719-7528), and the total attributable fraction was 20.50% (95%CI: 10.44%-28.91%). The attributable fractions were higher in specific subgroups like male (20.72%), people ≥65 years (23.33%), and people with cardiovascular diseases (26.07%). Conclusion The exposure-response relationship between temperature and non-accidental mortality in Tibet showes that the non-accidental mortality risk increase as temperature become colder. The attributable burden of disease is heavy. Residents being male, ≥65 years, with cardiovascular diseases and respiratory diseases may be vulnerable to nonoptimal temperature.