Xiaoxu Wu scite author profile

Climate change refers to long-term shifts in weather conditions and patterns of extreme weather events. It may lead to changes in health threat to human beings, multiplying existing health problems. This review examines the scientific evidences on the impact of climate change on human infectious diseases. It identifies research progress and gaps on how human society may respond to, adapt to, and prepare for the related changes. Based on a survey of related publications between 1990 and 2015, the terms used for literature selection reflect three aspects--the components of infectious diseases, climate variables, and selected infectious diseases. Humans' vulnerability to the potential health impacts by climate change is evident in literature. As an active agent, human beings may control the related health effects that may be effectively controlled through adopting proactive measures, including better understanding of the climate change patterns and of the compound disease-specific health effects, and effective allocation of technologies and resources to promote healthy lifestyles and public awareness. The following adaptation measures are recommended: 1) to go beyond empirical observations of the association between climate change and infectious diseases and develop more scientific explanations, 2) to improve the prediction of spatial-temporal process of climate change and the associated shifts in infectious diseases at various spatial and temporal scales, and 3) to establish locally effective early warning systems for the health effects of predicated climate change.

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How environmental conditions impact mosquito ecology and Japanese encephalitis: An eco-epidemiological approach

Tian

Cazelles

et al. 2015

Environment International

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Anthropogenically driven environmental changes shift the ecological dynamics of hemorrhagic fever with renal syndrome

Tian

Yu²,

Bjørnstad

et al. 2017

PLoS Pathog

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Zoonoses are increasingly recognized as an important burden on global public health in the 21st century. High-resolution, long-term field studies are critical for assessing both the baseline and future risk scenarios in a world of rapid changes. We have used a three-decade-long field study on hantavirus, a rodent-borne zoonotic pathogen distributed worldwide, coupled with epidemiological data from an endemic area of China, and show that the shift in the ecological dynamics of Hantaan virus was closely linked to environmental fluctuations at the human-wildlife interface. We reveal that environmental forcing, especially rainfall and resource availability, exert important cascading effects on intra-annual variability in the wildlife reservoir dynamics, leading to epidemics that shift between stable and chaotic regimes. Our models demonstrate that bimodal seasonal epidemics result from a powerful seasonality in transmission, generated from interlocking cycles of agricultural phenology and rodent behavior driven by the rainy seasons.

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Climate change and dengue fever transmission in China: Evidences and challenges

Liu

et al. 2018

Science of The Total Environment

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Deceleration efficiencies of shrub windbreaks in a wind tunnel

Zou

Zhou

et al. 2015

Aeolian Research

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Natural and human environment interactively drive spread pattern of COVID-19: A city-level modeling study in China

Yin

et al. 2021

Science of The Total Environment

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A novel Coronavirus COVID-19 has caused high morbidity and mortality in China and worldwide. A few studies have explored the impact of climate change or human activity on the disease incidence in China or a city. The integrated study concerning environment impact on the emerging disease is rarely reported. Therefore, based on the two-stage modeling study, we investigate the effect of both natural and human environment on COVID-19 incidence at a city level. Besides, the interactive effect of different factors on COVID-19 incidence is analyzed using Geodetector; the impact of effective factors and interaction terms on COVID-19 is simulated with Geographically Weighted Regression (GWR) models. The results find that mean temperature (MeanT), Destination proportion in population flow from Wuhan (WH), Migration scale (MS), and WH*MeanT, are generally promoting for COVID-19 incidence before Wuhan’s shutdown (T1); the WH and MeanT play a determinant role in the disease spread in T1. The effect of environment on COVID-19 incidence after Wuhan’s shutdown (T2) includes more factors (including relative humidity, precipitation, travel intensity within a city (TC), and their interactive terms) than T1, and their effect shows distinct spatial heterogeneity. Interestingly, the dividing line of positive-negative effect of MeanT and Pre on COVID-19 incidence is 8.5°C and 1mm, respectively. In T2, WH has weak impact, but the MS has the strongest effect. The COVID-19 incidence in T2 without quarantine is also modeled using the developed GWR model, and the modeled incidence shows an obvious increase for 75.6% cities compared with reported incidence in T2 especially for some mega cities. This evidences national quarantine and traffic control take determinant role in controlling the disease spread. The study indicates that both natural environment and human factors integratedly affect the spread pattern of COVID-19 in China.

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Impact of global change on transmission of human infectious diseases

Tian

Zhou

et al. 2013

Sci. China Earth Sci.

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Modeling and projection of dengue fever cases in Guangzhou based on variation of weather factors

Wang

et al. 2017

Science of The Total Environment

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Xiaoxu Wu

Impact of climate change on human infectious diseases: Empirical evidence and human adaptation

How environmental conditions impact mosquito ecology and Japanese encephalitis: An eco-epidemiological approach

Anthropogenically driven environmental changes shift the ecological dynamics of hemorrhagic fever with renal syndrome

Climate change and dengue fever transmission in China: Evidences and challenges

Deceleration efficiencies of shrub windbreaks in a wind tunnel

Natural and human environment interactively drive spread pattern of COVID-19: A city-level modeling study in China

Impact of global change on transmission of human infectious diseases

Modeling and projection of dengue fever cases in Guangzhou based on variation of weather factors

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