Climate Change Projections for Stroke Incidence in Taiwan: Impact of 2 °C and 4 °C Global Warming Level.

IF 3.8 4区医学 Q1 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH

Journal of Epidemiology and Global Health Pub Date : 2024-09-02 DOI:10.1007/s44197-024-00289-3

Wei-Te Wu, Miku Kono, Chuan-Pin Lee, Yu-Yin Chang, Yao-Hsu Yang, Ching-Chun Lin, Tzu-Ming Liu, Hsin-Chi Li, Yung-Ming Chen, Pau-Chung Chen

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引用次数: 0

Abstract

Objectives: This study aimed to establish the exposure-lag-response effect between daily maximum temperature and stroke-related emergency department visits and to project heat-induced stroke impacts under global warming levels (GWL) of 2 °C and 4 °C.

Methods: Stroke-related emergency department visits in Taiwan from 2001 to 2020 were identified using the National Health Insurance Research Database (NHIRD). The study population consisted of 1,100,074 initial stroke cases matched with 2,200,148 non-stroke controls. We employed Distributed Lag Nonlinear Models (DLNM) in a case-crossover study to investigate the association between temperature and stroke. Generalized Estimating Equations (GEE) models with a Poisson function were used to correlate high-temperature exposure with annual stroke incidence rates. Projections were made under two global warming scenarios, GWL 2.0 °C and 4.0 °C, using Coupled General Circulation Model (GCMs). Baseline data from 1995 to 2014 were transformed for spatial distribution at the township level. Geographic Information System (GIS) spatial analysis was performed using Quantum GIS 3.2.0 software.

Results: DLNM exposure-lag-response effect revealed that daily maximum temperature exceeding 34 °C significantly increased the risk of stroke-related emergency department visits, particularly for ischemic stroke. Under the 2 °C GWL scenario, the frequency of days with temperatures surpassing 34 °C is projected to rise substantially by the median year of 2042, with a further increase to 92.6 ± 18.0 days/year by 2065 under the 4 °C GWL scenario. Ischemic stroke showed the highest increase in temperature-related incidence rates, notably rising from 7.80% under the GWL 2 °C to 36.06% under the GWL 4 °C. Specifically, the annual temperature-related incidence rate for ischemic stroke is expected to increase significantly by 2065. Regions such as Taichung, Hsinchu, Yilan, and Taitung demonstrated pronounced changes in heat-related ischemic stroke incidence under the GWL 4 °C.

Conclusions: The findings emphasize the importance of addressing temperature-related stroke risks, particularly in regions projected to experience significant temperature increases. Effective mitigation strategies are crucial to reduce the impact of rising temperatures on stroke incidence and safeguard public health.

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气候变化对台湾中风发病率的预测：2 °C和4 °C全球变暖水平的影响。

目的：本研究旨在确定日最高气温与中风相关急诊就诊之间的暴露-滞后-反应效应，并预测全球变暖水平（GWL）为 2 ℃ 和 4 ℃ 时热诱发中风的影响：方法：利用国家健康保险研究数据库（NHIRD）对 2001 年至 2020 年台湾地区与中风相关的急诊就诊情况进行了识别。研究人群包括 1,100,074 例初始中风病例和 2,200,148 例非中风对照。我们在病例交叉研究中采用了分布式滞后非线性模型（DLNM）来研究体温与中风之间的关系。采用泊松函数的广义估计方程 (GEE) 模型将高温暴露与中风年发病率联系起来。利用耦合大气环流模型（GCMs）对两种全球变暖情景（GWL 2.0 °C和4.0 °C）进行了预测。对 1995 年至 2014 年的基线数据进行了转换，以便在乡镇一级进行空间分布。使用 Quantum GIS 3.2.0 软件进行了地理信息系统（GIS）空间分析：DLNM暴露-滞后-反应效应显示，日最高气温超过34 °C会显著增加中风相关急诊就诊风险，尤其是缺血性中风。在 2 °C GWL 情景下，预计到 2042 年的中位数年，气温超过 34 °C 的天数频率将大幅上升，在 4 °C GWL 情景下，到 2065 年将进一步增加到 92.6 ± 18.0 天/年。缺血性中风与温度相关的发病率增幅最大，从全球升温潜能值 2 °C 下的 7.80% 显著上升到全球升温潜能值 4 °C 下的 36.06%。具体而言，预计到 2065 年，缺血性中风与温度相关的年发病率将显著增加。在 GWL 4 °C 下，台中、新竹、宜兰和台东等地区与高温相关的缺血性中风发病率有明显变化：研究结果强调了应对与温度相关的中风风险的重要性，尤其是在预计气温将显著升高的地区。有效的缓解策略对于降低气温升高对中风发病率的影响和保障公众健康至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Epidemiology and Global Health Medicine-Epidemiology

CiteScore

10.70

自引率

1.40%

发文量

审稿时长

19 weeks

期刊介绍： The Journal of Epidemiology and Global Health is an esteemed international publication, offering a platform for peer-reviewed articles that drive advancements in global epidemiology and international health. Our mission is to shape global health policy by showcasing cutting-edge scholarship and innovative strategies.

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