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基于VECTRI模型的气候变化偏差校正CMIP5预测及塞内加尔疟疾影响评估

Bias-Corrected CMIP5 Projections for Climate Change and Assessments of Impact on Malaria in Senegal under the VECTRI Model.

作者信息

Fall Papa, Diouf Ibrahima, Deme Abdoulaye, Diouf Semou, Sene Doudou, Sultan Benjamin, Famien Adjoua Moïse, Janicot Serge

机构信息

Laboratoire Environnement-Ingénierie-Télécommunication-Energies Renouvelables (LEITER), Unité de Formation et de Recherche de Sciences Appliquées et de Technologie, Université Gaston Berger de Saint-Louis, BP 234, Saint-Louis 32000, Senegal.

Laboratoire de Physique de l'Atmosphère et de l'Océan-Siméon Fongang, Ecole Supérieure Polytechnique de l'Université Cheikh Anta Diop (UCAD), BP 5085, Dakar-Fann, Dakar 10700, Senegal.

出版信息

Trop Med Infect Dis. 2023 Jun 6;8(6):310. doi: 10.3390/tropicalmed8060310.

DOI:10.3390/tropicalmed8060310
PMID:37368728
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10300711/
Abstract

On the climate-health issue, studies have already attempted to understand the influence of climate change on the transmission of malaria. Extreme weather events such as floods, droughts, or heat waves can alter the course and distribution of malaria. This study aims to understand the impact of future climate change on malaria transmission using, for the first time in Senegal, the ICTP's community-based vector-borne disease model, TRIeste (VECTRI). This biological model is a dynamic mathematical model for the study of malaria transmission that considers the impact of climate and population variability. A new approach for VECTRI input parameters was also used. A bias correction technique, the cumulative distribution function transform (CDF-t) method, was applied to climate simulations to remove systematic biases in the Coupled Model Intercomparison Project Phase 5 (CMIP5) global climate models (GCMs) that could alter impact predictions. Beforehand, we use reference data for validation such as CPC global unified gauge-based analysis of daily precipitation (CPC for Climate Prediction Center), ERA5-land reanalysis, Climate Hazards InfraRed Precipitation with Station data (CHIRPS), and African Rainfall Climatology 2.0 (ARC2). The results were analyzed for two CMIP5 scenarios for the different time periods: assessment: 1983-2005; near future: 2006-2028; medium term: 2030-2052; and far future: 2077-2099). The validation results show that the models reproduce the annual cycle well. Except for the IPSL-CM5B model, which gives a peak in August, all the other models (ACCESS1-3, CanESM2, CSIRO, CMCC-CM, CMCC-CMS, CNRM-CM5, GFDL-CM3, GFDL-ESM2G, GFDL-ESM2M, inmcm4, and IPSL-CM5B) agree with the validation data on a maximum peak in September with a period of strong transmission in August-October. With spatial variation, the CMIP5 model simulations show more of a difference in the number of malaria cases between the south and the north. Malaria transmission is much higher in the south than in the north. However, the results predicted by the models on the occurrence of malaria by 2100 show differences between the RCP8.5 scenario, considered a high emission scenario, and the RCP4.5 scenario, considered an intermediate mitigation scenario. The CanESM2, CMCC-CM, CMCC-CMS, inmcm4, and IPSL-CM5B models predict decreases with the RCP4.5 scenario. However, ACCESS1-3, CSIRO, NRCM-CM5, GFDL-CM3, GFDL-ESM2G, and GFDL-ESM2M predict increases in malaria under all scenarios (RCP4.5 and RCP8.5). The projected decrease in malaria in the future with these models is much more visible in the RCP8.5 scenario. The results of this study are of paramount importance in the climate-health field. These results will assist in decision-making and will allow for the establishment of preventive surveillance systems for local climate-sensitive diseases, including malaria, in the targeted regions of Senegal.

摘要

在气候与健康问题上,已有研究试图了解气候变化对疟疾传播的影响。洪水、干旱或热浪等极端天气事件会改变疟疾的传播过程和分布范围。本研究旨在利用国际理论物理中心(ICTP)基于社区的病媒传播疾病模型TRIeste(VECTRI),首次在塞内加尔了解未来气候变化对疟疾传播的影响。这个生物学模型是一个用于研究疟疾传播的动态数学模型,考虑了气候和人口变化的影响。同时还采用了一种新的VECTRI输入参数方法。一种偏差校正技术,即累积分布函数变换(CDF-t)方法,被应用于气候模拟,以消除耦合模式比较计划第五阶段(CMIP5)全球气候模型(GCMs)中可能改变影响预测的系统偏差。在此之前,我们使用诸如气候预测中心(CPC)基于全球统一雨量计的日降水量分析、ERA5-land再分析、气候灾害红外降水与站点数据(CHIRPS)以及非洲降雨气候学2.0(ARC2)等参考数据进行验证。针对不同时间段的两个CMIP5情景分析了结果:评估期:1983 - 2005年;近期:2006 - 2028年;中期:2030 - 2052年;远期:2077 - 2099年。验证结果表明,这些模型能很好地再现年周期。除了IPSL - CM5B模型在8月出现峰值外,所有其他模型(ACCESS1 - 3、CanESM2、CSIRO、CMCC - CM、CMCC - CMS、CNRM - CM5、GFDL - CM3、GFDL - ESM2G、GFDL - ESM2M、inmcm4和IPSL - CM5B)在9月出现最大峰值且8 - 10月为强传播期这一点上与验证数据一致。在空间变化方面,CMIP5模型模拟显示南北之间疟疾病例数差异更大。南部的疟疾传播比北部高得多。然而,模型预测的到2100年疟疾发生情况的结果在被视为高排放情景的RCP8.5情景和被视为中等缓解情景的RCP4.5情景之间存在差异。CanESM2、CMCC - CM、CMCC - CMS、inmcm4和IPSL - CM5B模型预测在RCP4.5情景下疟疾会减少。然而,ACCESS1 - 3、CSIRO、NRCM - CM5、GFDL - CM3、GFDL - ESM2G和GFDL - ESM2M预测在所有情景(RCP4.5和RCP8.5)下疟疾都会增加。这些模型预测的未来疟疾减少情况在RCP8.5情景中更为明显。本研究结果在气候与健康领域至关重要。这些结果将有助于决策,并能在塞内加尔的目标地区建立针对包括疟疾在内的当地气候敏感疾病的预防性监测系统。

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