The effect of air temperature on mortality from cerebrovascular diseases in Brazil between 1996 and 2017

Mascarenhas, Mikaela Santos; Silva, Diego Duque da; Nogueira, Mário Círio; Farias, William Cossich Marcial de; Ferreira, Cássia de Castro Martins; Ferreira, Letícia de Castro Martins

doi:10.1590/1413-81232022278.05092022

Abstract

Cerebrovascular diseases (CVD) are one of the leading causes of mortality globally. Air temperature is one of the risk factors for CVD; however, few studies have investigated the relationship between air temperature and mortality from these diseases in Brazil. This time series study investigated the relationship between air temperature and CVD mortality in 10 microregions located across Brazil’s five regions during the period 1996 to 2017 using mortality data from the national health information system, DATASUS and daily mean temperature data. The association between mean air temperature and mortality from CVD was measured using generalized additive models with Poisson distribution and relative and attributable risks were estimated together with 95% confidence intervals using distributed lag non-linear models and a 14-day lag. There were 531,733 deaths from CVD during the study period, 21,220 of which (11,138-30,546) were attributable to air temperature. Minimum mortality temperatures ranged from 20.1ºC in Curitiba to 29.6ºC in Belém. Associations between suboptimal air temperatures and increased risk of death from CVD were observed in all of Brazil’s five regions. Relative risk from the cold was highest in Manaus (RR 1.53; 1.22-1.91) and Campo Grande (RR 1.52; 1.18-1.94), while relative risk from heat was highest in Manaus (RR 1.75; 1.35-2.26) and Brasília (RR 1.36; 1.15-1.60).

Key words:
Stroke; Mortality; Temperature; Climate

Introduction

Cerebrovascular diseases, principally strokes, are one of the leading causes of death worldwide¹1 World Health Organization (WHO). Global Health Estimates 2016: Deaths by Cause, Age, Sex, by Country and by Region, 2000-2016. Geneva: WHO; 2018.. Understanding the risk factors for these diseases is vital to reducing morbidity and mortality. Recent studies have shown associations between air temperature and mortality from cerebrovascular diseases²2 Lian H, Ruan Y, Liang R, Liu X, Fan Z. Short-Term Effect of Ambient Temperature and the Risk of Stroke: A Systematic Review and Meta-Analysis. Int J Environ Res Public Health 2015; 12(8):9068-9088.

3 Gasparrini A, Armstrong B. The impact of heat waves on mortality. Epidemiology 2011; 22(1):68-73.

4 Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238.

5 Zhou L, Chen K, Chen X, Jing Y, Ma Z, Bi J, Kinney PL. Heat and mortality for ischemic and hemorrhagic stroke in 12 cities of Jiangsu Province, China. Sci Total Environ 2017; 601-602:271-277.

6 Ban J, Xu D, He MZ, Sun Q, Chen C, Wang W, Zhu P, Li T. The effect of high temperature on cause-specific mortality: A multi-county analysis in China. Environ Int 2017; 106:19-26.^-⁷7 Chen R, Wang C, Meng X, Chen H, Thach TQ, Wong CM, Kan H. Both low and high temperature may increase the risk of stroke mortality. Neurology 2013; 81(12):1064-1070.. The potential health effects of the climate have become such an important issue that temperature extremes were added to the list of leading risk factors for morbidity and mortality globally in the latest edition of the Global Burden of Disease (2019)⁸8 GBD 2019 Risk Factors Collaborators. Global burden of 87 risk factors in 204 countries and territories, 1990-2019: a systematic analysis for the Global Burden of Disease Study 2019. Lancet 2020; 396(10258):1223-1249..

The pathophysiology of the relationship between air temperature and cerebrovascular diseases is multifactorial. Low temperatures stimulate peripheral skin receptors, which causes vasoconstriction and circulatory overload due to the release of catecholamines. In addition, exposure to cold can induce a hypercoagulable state, which can contribute to the development of these diseases⁹9 Chen K, Breitner S, Wolf K, Rai M, Meisinger C, Heier M, Kuch B, Peters A, Schneider A. Projection of Temperature-Related Myocardial Infarction in Augsburg, Germany: Moving on From the Paris Agreement on Climate Change. Dtsch Arztebl Int 2019; 116(31-32):521-527.. In contrast, high temperatures can cause local and systemic inflammation, resulting in the release of pro-inflammatory interleukins, which can give rise to atherosclerotic plaque instability and endothelial dysfunction. In addition, dehydration due to heat causes hemoconcentration, inhibition of the fibrinolytic system, and activation of the pathway of coagulation, which are determining factors for acute vascular events⁹9 Chen K, Breitner S, Wolf K, Rai M, Meisinger C, Heier M, Kuch B, Peters A, Schneider A. Projection of Temperature-Related Myocardial Infarction in Augsburg, Germany: Moving on From the Paris Agreement on Climate Change. Dtsch Arztebl Int 2019; 116(31-32):521-527..

In light of the above, understanding that air temperature is an important risk factor for cerebrovascular diseases is crucial for the development of effective health measures and public policies. Extreme cold and heat warning systems have been shown to be effective in encouraging individuals to protect themselves against temperature extremes, particularly among vulnerable groups¹⁰10 Toloo G, FitzGerald G, Aitken P, Verrall K, Tong S. Evaluating the effectiveness of heat warning systems: systematic review of epidemiological evidence. Int J Public Health 2013; 58(5):667-681.^,¹¹11 Chau PH, Chan KC, Woo J. Hot weather warning might help to reduce elderly mortality in Hong Kong. Int J Biometeorol 2009; 53(5):461-468..

The aim of this study was to provide new evidence of the relationship between air temperature and mortality from cerebrovascular diseases in 10 micro regions in Brazilin order to draw the attention of the public and health professionals and managers to the need to develop measures to address the health effects of extreme temperatures.

Although various countries possess epidemiological data on the effects of air temperature on mortality from cerebrovascular diseases, data in Brazil are scarce and generally limited to specific regions or shorter time intervals. The present study therefore intends to contribute to the body of knowledge on this issue by discussing the effects of air temperature on deaths from cerebrovascular diseases across Brazil’s five regions over a 21-year period (1996-2017).

Methods

Study population

We conducted a time series study to investigate the effect of variations in daily mean temperature on mortality from cerebrovascular diseases. We selected the two largest cities in each of Brazil’s five regions, which correspond to the micro regions defined by the Brazilian Institute of Geography and Statistics (IBGE), except in the Center-West, where the second largest city (Goiânia-GO) was discarded due to its proximity to the largest city (Brasília-DF). The following 10 micro regions were selected, representing the country’s different social and climatic realities: Porto Alegre-RS (South), Curitiba-PR (South), São Paulo-SP (Southeast), Rio de Janeiro-RJ (Southeast), Brasília-DF (Center-West), Campo Grande-MS (Center-West), Salvador-BA (Northeast), Recife-PE (Northeast), Manaus-AM (North), and Belém-PA (North). The study period was January 1996 to December 2017 (21 years).

Data

Data on mortality from cerebrovascular diseases (Codes I60 to I69 of the ICD 10) were obtained from the national health information system, DATASUS¹²12 Brasil. Ministério da Saúde (MS). Banco de dados do Sistema Único de Saúde - DATASUS, Sistema de Informações sobre Mortalidade [Internet]. [acessado 2021 jun 20]. Disponível em https://datasus.saude.gov.br/.
https://datasus.saude.gov.br... . Daily mean temperature was calculated using data from model equations¹³13 Dee DP, Uppala SM, Simmons AJ, Berrisford P, Poli P, Kobayashi S, Andrae U, Balmaseda MA, Balsamo G, Bauer P, Bechtold P, Beljaars ACM, van de Berg L, Bidlot J, Bormann N, Delsol C, Dragani R, Fuentes M, Geer AJ, Haimberger L, Healy SB, Hersbach H, Hólm EV, Isaksen L, Kållberg P, Köhler M, Matricardi M, McNally AP, Monge-Sanz BM, Morcrette J-J, Park B-K, Peubey C, Rosnay P, Tavolato C, Thépaut J-N, Vitart F. The ERA-Interim reanalysis: configuration and performance of the data assimilation system. Quart J Roy Meteor Soc 2011; 137(656):553-597. produced by the European Centre for Medium-Range Weather Forecasts (ECMWF). Reanalysis systems consist of a combination of weather forecasting models and systems that assimilate meteorological data obtained from different platforms, such as ships, aircraft, radiosondes and satellites. Because these observations are unevenly distributed across space and time, the data is assimilated to combine all available information with a weather forecasting model and generate a new analysis of the state of the atmosphere at a specific moment in time¹⁴14 Quadro MFL, Dias MAFS, Herdies DL, Gonçalves LGG. Análise climatológica da precipitação e do transporte de umidade na região da ZCAS através da nova geração de reanálises. Rev Bras Meteorol 2012; 27:152-162.. We calculated daily mean air temperatures at points on a uniform horizontal grid spaced at a distance of 13 km, using the points within each of the micro regions to obtain the daily mean temperature. Despite variations in temperature within each micro region, daily mean temperature provides a good representation of temperature trends⁴4 Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238. and is widely used by studies addressing the relationship between health and climate¹⁵15 Moreira A, Fontana DC, Kuplich TM, Cardoso MA. Dados meteorológicos estimados em condições de clima subtropical e a relação com índices de Vegetação. Rev Bras Cartogr 2018; 70(4):1409-1436.. The performance of the model equations used by the ERA-Interim reanalysis is satisfactory when compared to meteorological data, showing a correlation of equal to or greater than 96% in the state of Rio Grande do Sul¹⁶16 Sun Z, Chen C, Xu D, Li T. Effects of ambient temperature on myocardial infarction: A systematic review and meta-analysis. Environ Pollut 2018; 241:1106-1114.. These data are publically available, meaning that, in accordance with National Health Council Resolution No. 510, the present study did not require ethical approval.

Statistical analysis

The statistical distributions of daily mean air temperature and daily deaths from cerebrovascular diseases by micro region were presented in tables. Boxplot charts showing the monthly distribution of the frequency of deaths and mean temperature were used to visualize differences in the variables in each region.

The association between mean air temperature and mortality from cerebrovascular diseases was measured using generalized additive models with the negative binomial distribution. Time was modelled using a natural cubic spline with eight degrees of freedom per year to adjust for long-term trends and seasonality. Day of the week was included in the models to adjust for days in which mortality from cerebrovascular diseases was higher, such as weekends for example. Non-linear and time interval effects were estimated using distributed lag non-linear models (DLNM)¹⁷17 Gasparrini A, Armstrong B, Kenward MG. Distributed lag non-linear models. Stat Med 2010; 29:2224-2234.. Widely used in time-series studies investigating associations between climatic factors and health outcomes¹⁸18 Jung, J, Lee JY, Lee H, Kim H. Predicted Future Mortality Attributed to Increases in Temperature and PM10 Concentration under Representative Concentration Pathway Scenarios. Int J Environ Res Public Health 2020; 17:2600., DLNM allow researchers to detect non-linear and time lag associations using cross-basis functions. We selected a natural spline with five degrees of freedom for the exposure-response function and a polynomial function with one intercept and four degrees of freedom for the lag-response function to provide greater model flexibility. Maximum lag was set at 14 days. The analyses were performed with the software R, version 4.1.0 using the packages dlnm, mgcv, splines and ggplot2.

The model is represented by the equation below:

Yt~Negativebinomial(μt)log(μt)=α+βTemperaturet,lag+NS(time,gl)+γDayt

Where Y_t is the number of deaths observed on day t; α is the intercept; Temperature_t,lag is a matrix of variables derived from the transformation of temperature into a cross-basis object where β is its vector of coefficients and lag is in days; NS (time, df) is the natural spline of time in days, where df is degrees of freedom per year to control for long-term trends and seasonality.

Cumulative relative risk (RR) of mortality from cerebrovascular diseases was calculated for each micro region for predetermined temperature percentiles (P) relative to minimum mortality temperature - MMT (reference), with a 14-day lag. Percentiles 2.5 and 10 represent extreme and moderate cold, respectively, while 90 and 97.5 represent moderate and extreme heat. Finally, we calculated risks attributable to the temperature intervals between these percentiles: (a) Attributable risk (AR) of extreme cold (between the lowest temperature and percentile 2.5); (b) AR of moderate cold (between percentiles 2.5 and 10); (c) AR of mild cold (between percentile 10 and MMT); (d) AR of mild heat (between MMT and percentile 90); (e) AR of moderate heat (between percentiles 90 and 97.5); (f) AR of extreme heat (between percentile 97.5 and the highest temperature).

Results

Daily mean air temperatures were highest during the summer months and lowest in the winter across all micro regions except Manaus and Belém, where temperatures were highest in the spring, during September and November (Figure 1).

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Figure 1
Boxplot charts showing variations in mean temperatures in each micro region by month (1996-2017).

The highest daily mean air temperature was observed in Fortaleza (Northeast), while the lowest was in Curitiba (South). The North and South showed the highest and lowest mean temperatures, respectively (Table 1).

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Table 1
Distribution of daily mean temperatures (ºC) and daily deaths from cerebrovascular diseases in the 10 micro regions (1996-2017).

The variation in mean daily temperatures was highest in Porto Alegre (standard deviation 4.6°C) and lowest in Fortaleza (standard deviation 0.9°C). (Table 1).

A total of 531,733 deaths from cerebrovascular diseases were analyzed in this study. The number of daily deaths ranged between 0 and 60 across the regions. The largest and smallest number of deaths were recorded in Rio de Janeiro and Campo Grande, respectively (Table 1).

Risk of mortality from cerebrovascular diseases was higher on days with extremet emperatures (both cold and hot) across Brazil’s five regions (Table 2 and Figure 2). Increased risk of mortality was associated with extreme cold in seven of the 10 micro regions, extreme heat in six of the regions, and moderate temperatures in five of the regions.

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Table 2
Relative risk and 95% confidence intervals for mortality from cerebrovascular diseases in the 10 micro regions (1996-2017),

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Figure 2
Relative risk and 95% confidence intervals for mortality from cerebrovascular diseases in the 10 micro regions (1996-2017).

Relative risk (RR) of death from cerebrovascular diseases was highest in Manaus foreach of the four percentiles analyzed by this study. RR of extreme cold was also high in Curitiba (South) and Campo Grande (Center-West), while RR of extreme heat was highest in Manaus (North), followed by Porto Alegre (South), and Brasília (Center-West). Belém was the only micro region not to show increased RR for the temperature percentiles analyzed by this study.

Attributable fractions were highest in Manaus and the micro regions in the South and Center-West in each of temperature percentiles. A significant proportion of deaths in Manaus and Curitiba were attributable to mild cold and mild heat. The proportion of deaths attributable to mild cold and mild heat was higher than that attributable to extreme temperatures because the proportion of days with mild temperatures was generally greater. Despite not having the highest attributable fractions in any of the temperature percentiles, São Paulo and Rio de Janeiro showed the highest number of attributable deaths because they are the most populous cities.

It is estimated that around 1,218 deaths from cerebrovascular diseases per year were attributable to temperatures above or below the MMT (Table 3).

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Table 3
Attributable fraction (%) and 95% confidence intervals, and temperature-attributable deaths from cerebrovascular diseases in the 10 micro regions (1996-2017).

Discussion

This is the first study in Brazil to carry out a comprehensive nationwide analysis of the relationship between mortality from cerebrovascular diseases and air temperature. The findings show an association between mortality and both low and high temperatures across all of Brazil’s five regions. Nine of the 10 micro regions showed a high risk of mortality attributable to temperatures above or below the MMT. The findings show that 1,218 deaths per year could have been avoided in the 10 micro regions by adopting preventive measures to minimize exposure to temperature extremes. It is important to stress that this number is even more alarming when these results are extrapolated nationally, further reinforcing the hypothesis that air temperature is a major risk factor for cerebrovascular diseases.

Previous studies have shown an association between low and high air temperatures and increased mortality in different regions around the world⁶6 Ban J, Xu D, He MZ, Sun Q, Chen C, Wang W, Zhu P, Li T. The effect of high temperature on cause-specific mortality: A multi-county analysis in China. Environ Int 2017; 106:19-26.^,¹⁹19 Guo Y, Gasparrini A, Armstrong B, Li S, Tawatsupa B, Tobias A, Lavigne E, de Sousa Zanotti Stagliorio Coelho M, Leone M, Pan X, Tong S, Tian L, Kim H, Hashizume M, Honda Y, Guo YL, Wu CF, Punnasiri K, Yi SM, Michelozzi P, Saldiva PH, Williams G. Global variation in the effects of ambient temperature on mortality: a systematic evaluation. Epidemiology 2014; 25(6):781-789.

20 Gasparrini A, Guo Y, Hashizume M, Lavigne E, Zanobetti A, Schwartz J, Tobias A, Tong S, Rocklöv J, Forsberg B, Leone M, De Sario M, Bell ML, Guo YL, Wu CF, Kan H, Yi SM, de Sousa Zanotti Stagliorio Coelho M, Saldiva PH, Honda Y, Kim H, Armstrong B. Mortality risk attributable to high and low ambient temperature: a multicountry observational study. Lancet 2015; 386(9991):369-375.^-²¹21 Yang Z, Wang Q, Liu P. Extreme temperature and mortality: evidence from China. Int J Biometeorol 2019; 63:29-50.. A systematic review of 20 international studies investigating the relationship between stroke and both low and high temperatures published in 2015 corroborates our main findings. Lian et al.²2 Lian H, Ruan Y, Liang R, Liu X, Fan Z. Short-Term Effect of Ambient Temperature and the Risk of Stroke: A Systematic Review and Meta-Analysis. Int J Environ Res Public Health 2015; 12(8):9068-9088. concluded that, at high temperatures, a 1°C increase in temperature led to a 1.5% increase in death from stroke, while in the cold the increase was 1.2%²2 Lian H, Ruan Y, Liang R, Liu X, Fan Z. Short-Term Effect of Ambient Temperature and the Risk of Stroke: A Systematic Review and Meta-Analysis. Int J Environ Res Public Health 2015; 12(8):9068-9088..

Gasparrini et al.²⁰20 Gasparrini A, Guo Y, Hashizume M, Lavigne E, Zanobetti A, Schwartz J, Tobias A, Tong S, Rocklöv J, Forsberg B, Leone M, De Sario M, Bell ML, Guo YL, Wu CF, Kan H, Yi SM, de Sousa Zanotti Stagliorio Coelho M, Saldiva PH, Honda Y, Kim H, Armstrong B. Mortality risk attributable to high and low ambient temperature: a multicountry observational study. Lancet 2015; 386(9991):369-375. collected data from the period 1985-2012 for 384 locations across all continents except Africa. The findings show that more deaths were attributable to cold than heat, with extreme cold and extreme heat accounting for 0.86% of total deaths from stroke. Studies in other regions, including China, Ireland, Iran and the US, found similar outcomes, with increased mortality from stroke being higher in the cold⁴4 Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238.^,⁷7 Chen R, Wang C, Meng X, Chen H, Thach TQ, Wong CM, Kan H. Both low and high temperature may increase the risk of stroke mortality. Neurology 2013; 81(12):1064-1070.^,²²22 Zeka A, Browne S, McAvoy, H, Goodman P. The association of cold weather and all-cause and cause-specific mortality in the island of Ireland between 1984 and 2007. Environ Health 2014; 13:104.

23 Gholampour R, Darand M, Halabian AH. Impacts of cold and hot temperatures on mortality rate in Isfahan, Iran. J Thermal Biol 2019; 86:102453.^-²⁴24 Chu SY, Cox M, Fonarow GC, Smith EE, Schwamm L, Bhatt DL, Matsouaka RA, Xian Y, Sheth KN. Temperature and Precipitation Associate With Ischemic Stroke Outcomes in the United States. J Am Heart Assoc 2018; 7(22):e010020.. A study in Porto Rico²⁵25 Méndez-Lázaro PA, Pérez-Cardona CM, Rodríguez E, Martínez O, Taboas M, Bocanegra A, Méndez-Tejeda R. Climate change, heat, and mortality in the tropical urban area of San Juan, Puerto Rico. Int J Biometeorol 2018; 62:699-707. reported that stroke and cardiovascular diseases were the primary causes of death associated with high summer temperatures, while Royé et al.²⁶26 Royé D, Zarrabeitia MT, Riancho J, Santurtún A. A time series analysis of the relationship between apparent temperature, air pollutants and ischemic stroke in Madrid, Spain. Environ Res 2019; 173:349-358. showed that higher risk of mortality from stroke in Spain was associated with high temperatures²⁶26 Royé D, Zarrabeitia MT, Riancho J, Santurtún A. A time series analysis of the relationship between apparent temperature, air pollutants and ischemic stroke in Madrid, Spain. Environ Res 2019; 173:349-358..

A number of studies in China have addressed this issue⁴4 Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238.

5 Zhou L, Chen K, Chen X, Jing Y, Ma Z, Bi J, Kinney PL. Heat and mortality for ischemic and hemorrhagic stroke in 12 cities of Jiangsu Province, China. Sci Total Environ 2017; 601-602:271-277.

6 Ban J, Xu D, He MZ, Sun Q, Chen C, Wang W, Zhu P, Li T. The effect of high temperature on cause-specific mortality: A multi-county analysis in China. Environ Int 2017; 106:19-26.^-⁷7 Chen R, Wang C, Meng X, Chen H, Thach TQ, Wong CM, Kan H. Both low and high temperature may increase the risk of stroke mortality. Neurology 2013; 81(12):1064-1070.^,²⁷27 Yang J, Zhou M, Li M, Yin P, Wang B, Pilot E, Liu Y, van der Hoek W, van Asten L, Krafft T, Liu Q. Diurnal temperature range in relation to death from stroke in China. Environ Res 2018; 164:669-675.

28 Yang J, Liu HZ, Ou CQ, Lin GZ, Zhou Q, Shen GC, Chen PY, Guo Y. Global climate change: impact of diurnal temperature range on mortality in Guangzhou, China. Environ Pollut 2013; 175:131-136.^-²⁹29 Chen K, Huang L, Zhou, L, Ma Z, Bi J, Li T. Spatial analysis of the effect of the 2010 heat wave on stroke mortality in Nanjing, China. Sci Rep 2015; 5:10816., with elevated relative risk at non-optimal temperatures demonstrating that both hot and cold temperatures are risk factors for mortality from stroke in the country⁴4 Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238.^,⁵5 Zhou L, Chen K, Chen X, Jing Y, Ma Z, Bi J, Kinney PL. Heat and mortality for ischemic and hemorrhagic stroke in 12 cities of Jiangsu Province, China. Sci Total Environ 2017; 601-602:271-277.^,⁷7 Chen R, Wang C, Meng X, Chen H, Thach TQ, Wong CM, Kan H. Both low and high temperature may increase the risk of stroke mortality. Neurology 2013; 81(12):1064-1070.. As in the present study, other studies in China found that that relative risk was higher at extreme temperatures⁶6 Ban J, Xu D, He MZ, Sun Q, Chen C, Wang W, Zhu P, Li T. The effect of high temperature on cause-specific mortality: A multi-county analysis in China. Environ Int 2017; 106:19-26.^,⁷7 Chen R, Wang C, Meng X, Chen H, Thach TQ, Wong CM, Kan H. Both low and high temperature may increase the risk of stroke mortality. Neurology 2013; 81(12):1064-1070.. However, moderate temperatures accounted for most deaths, followed by extreme temperatures⁴4 Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238.. This is also consistent with the findings of the present study and may be explained by the fact that the number of days with moderate temperatures was greater than the number with extreme temperatures. The results of a study in India show that attributable risk was higher for mortality from stroke and all other causes at moderately cold temperatures, reinforcing the need for health interventions to focus on both moderate and extreme temperature events³⁰30 Fu SH, Gasparrini A, Rodriguez PS, Jha P. Mortality attributable to hot and cold ambient temperatures in India: a nationally representative case-crossover study. PLoS Med 2018; 15(7):e1002619..

Few studies in Brazil have investigated the relationship between air temperature and morbidity and mortality from cerebrovascular diseases. A time-series study in São Paulo of the period 2002-2011 found an association between mortality from stroke and air temperature, reporting increased risk at temperatures below 10°C³¹31 Ikefuti, P, Barrozo, L, Braga, A. Mean air temperature as a risk factor for stroke mortality in São Paulo, Brazil. Int J Biometeorol 2018; 62(8):1535-1542., especially for hemorrhagic strokes. These findings are consistent with the results of the present study for this micro region. Another study with patients admitted to two different hospitals in São Paulo for strokes or heart attacks over a two-year period showed that 2.8% and 4.9% of admissions, respectively, were due to high temperatures and found associations between the outcomes and air pollution³²32 Rumel D, Riedel L, Latorre M, Duncan B. Infarto do miocárdio e acidente vascular cerebral associados à alta temperatura e monóxido de carbono em área metropolitana do sudeste do Brasil. Rev Saude Publica 1993; 27(1):15-22.. A time-series analysis of the period 1996-2013 in six micro regions distributed across Brazil’s five regions found similar results to the present study, reporting a relationship between air temperature and mortality from heart attacks. The findings reveal increased risk at both low and high temperatures, particularly in the South and Southeast. Although this study analyzed mortality from heart attack rather than cerebrovascular diseases, comparisons can be made with the present study due to the major similarities between the pathology of these diseases³³33 Ferreira LCM, Nogueira MC, Pereira RVB, de Farias WCM, Rodrigues MMS, Teixeira MTB, Carvalho MS. Ambient temperature and mortality due to acute myocardial infarction in Brazil: an ecological study of time-series analyses. Sci Rep 2019; 9(1):13790..

Considering the diversity of this huge country, there are various plausible explanations for the findings of the present study, including the country’s different climates. The climate of each micro region was defined based on the Köppen-Geiger climate classification³⁴34 Alvares C, Stape J, Sentelhas P, Gonçalves J, Sparovek G. Köppen's climate classification map for Brazil. Meteorologische Zeitschrift 2013; 22(6):711-728..

In the North, an association was found in Manaus, but not in Belém. The two micro regions are part of the same homogeneous group when it comes to location and climate, as they are both located in the Amazon and have a humid equatorial climate³⁵35 Conselho Federal de Medicina (CFM). Medicina Intensiva no Brasil: 2018. Brasília: CFM; 2018.. Notable findings in these regions are the low number of mean daily deaths from cerebrovascular diseases and days with extreme temperatures. Another important factor in this region is health care. A survey of intensive care unit (ICU) bed numbers conducted by the Federal Council of Medicine in 2018 showed that the state of Amazonas (Manaus) has 2.40 beds per 10,000 inhabitants, compared to 4.51 in the state of Pará (Belém). This difference in ICU bed numbers may be a possible cause of the association found in Manaus, as cerebrovascular diseases are acute conditions requiring intensive care³⁶36 Muniz L, Pereira J, Ximenes J, Studart T. Classificação climática para o Estado do Ceará utilizando distintos sistemas de caracterização. In: XXII Simpósio Brasileiro de Recursos Hídricos (SBRH). Florianópolis; 2017..

In the Northeast, associations were found in both Fortaleza and Salvador. In Fortaleza, extreme cold was associated with a relative risk of 1.21. Understanding the climate of this micro region can help explain the findings. Fortaleza has a tropical savanna climate with dry winter (Aw)³⁷37 Kottek M, Grieser J, Beck C, Rudolf B, Rubel F. World Map of the Köppen-Geiger climate classification updated. Meteorologische Zeitschrift 2006; 15:259-263. and showed the highest daily mean temperatures among the 10 micro regions and lowest variation in temperature (SD 0.9). It is therefore possible that exposure to extreme cold was the factor that most influenced mortality from cerebrovascular diseases, as the bodies of people living in this region are physiologically adapted to high temperatures and more susceptible to low temperatures. Salvador on the other hand showed an association with extreme heat. Despite both cities being located in the Northeast, the two micro regions have significantly different climates. Although Salvador has a tropical rainforest climate (Am)³⁸38 Santana N. Investigação de Ilhas de Calor em Brasília: Análise Multitemporal com Enfoque na Cobertura do Solo. Rev Bras Geogr Fis 2015; 1044-1054., mean air temperature is lower than in Fortaleza. Frequent episodes of mild temperatures associated with cold fronts may explain the findings in Salvador.

In the Center-West, Brasília showed an association with extreme heat and moderate heat. The climate in the country’s capital is classified as equatorial savannah (Aw)³⁷37 Kottek M, Grieser J, Beck C, Rudolf B, Rubel F. World Map of the Köppen-Geiger climate classification updated. Meteorologische Zeitschrift 2006; 15:259-263. and, due to its location in the middle of country and continentality, the city has higher temperatures, which may have been a more pronounced risk factor in this region. Another important factor in various state capitals in Brazil are the effects of urban heat islands. A study showed that these effects are particularly pronounced in Brasília due to an intense process of urbanization in satellite cities, deforestation and soil exposure³⁹39 Zavattini J, Fratianni S. Os climas Regionais do Brasil. Rev Depart Geogr Progr Pos-Grad Geogr UFAM 2018; 9(32):93-106.. Campo Grande, on the other hand, located further south in the Center-West region, showed an association with extreme cold. Despite having the same climate as Brasília³⁸38 Santana N. Investigação de Ilhas de Calor em Brasília: Análise Multitemporal com Enfoque na Cobertura do Solo. Rev Bras Geogr Fis 2015; 1044-1054., the capital of Mato Grosso do Sul has specific characteristics that can help explain the result observed for this city. While Campo Grande has a generally high mean temperature, temperatures in the winter can be very low, similar to those in cities in the South.

In Rio de Janeiro and São Paulo, the most populous state capitals in the Southeast, risk of death from cerebrovascular diseases was higher in both cold and hot periods. In both São Paulo, which has a humid subtropical climate (Cfa)³⁹39 Zavattini J, Fratianni S. Os climas Regionais do Brasil. Rev Depart Geogr Progr Pos-Grad Geogr UFAM 2018; 9(32):93-106., and Rio de Janeiro, which has a tropical wet-dry climate (Aw)³⁹39 Zavattini J, Fratianni S. Os climas Regionais do Brasil. Rev Depart Geogr Progr Pos-Grad Geogr UFAM 2018; 9(32):93-106., frontal systems and air masses are common, creating distinct trends in air temperature throughout the year. This results in higher variability in temperature, illustrated by a high standard deviation in the air temperature data. However, the climates of the two regions have significant differences. São Paulo has a greater daily thermal amplitude due to continentality. Polar masses have a pronounced effect, causing sharp cold spells. Rio de Janeiro on the other hand has a lower daily and annual thermal amplitude because it is on the coast, meaning that the population is also more susceptible to cold.

The micro regions with the lowest mean temperatures are located in the South, which has a humid subtropical climate (Cfa)⁴⁰40 Silveira R, Alves M, Barreiro M, Bitencourt D. Ondas de calor nas capitais do Sul do Brasil e Montevidéu - Uruguai. Rev Bras Geogr Fis 2019; 12(4):1259-1276.. Porto Alegre showed an association with both cold and heat, while Curitiba showed an association with extreme and moderate cold. A possible explanation for these differences is that mean maximum temperatures were much higher in Porto Alegre than Curitiba, which is partially due to the difference in altitude between the two cities. Curitiba has an altitude of 900 meters above sea level, compared to only 47 meters in Porto Alegre³⁹39 Zavattini J, Fratianni S. Os climas Regionais do Brasil. Rev Depart Geogr Progr Pos-Grad Geogr UFAM 2018; 9(32):93-106.. In addition, heat waves are more frequent and intense in Porto Alegre than in Curitiba³⁹39 Zavattini J, Fratianni S. Os climas Regionais do Brasil. Rev Depart Geogr Progr Pos-Grad Geogr UFAM 2018; 9(32):93-106..

Although the present study did not stratify the population data by age and demographic characteristics, evidence from other studies suggest that the groups that are most vulnerable to death from cerebrovascular diseases at non-optimal temperatures are older persons, women, and people with a low level of education⁵5 Zhou L, Chen K, Chen X, Jing Y, Ma Z, Bi J, Kinney PL. Heat and mortality for ischemic and hemorrhagic stroke in 12 cities of Jiangsu Province, China. Sci Total Environ 2017; 601-602:271-277.^,²⁷27 Yang J, Zhou M, Li M, Yin P, Wang B, Pilot E, Liu Y, van der Hoek W, van Asten L, Krafft T, Liu Q. Diurnal temperature range in relation to death from stroke in China. Environ Res 2018; 164:669-675.^,²⁸28 Yang J, Liu HZ, Ou CQ, Lin GZ, Zhou Q, Shen GC, Chen PY, Guo Y. Global climate change: impact of diurnal temperature range on mortality in Guangzhou, China. Environ Pollut 2013; 175:131-136.. A study in China showed that men and older persons were the most affected and that the proportion of temperature-related deaths decreased with decreasing latitude⁴4 Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238.. Another study in China also showed that people living in rural areas were more vulnerable to the effects of heat waves on mortality from stroke²⁹29 Chen K, Huang L, Zhou, L, Ma Z, Bi J, Li T. Spatial analysis of the effect of the 2010 heat wave on stroke mortality in Nanjing, China. Sci Rep 2015; 5:10816..

Study limitations include the fact that the use of secondary air temperature data ignores the presence of microclimates that can influence apparent temperature in each micro region. In addition, external air temperature does not necessarily correspond to the air temperature felt by individuals, which is influenced by air conditioning and other factors that affect internal ambient temperature. Finally, we did not distinguish between hemorrhagic and ischemic strokes, as some other studies did⁵5 Zhou L, Chen K, Chen X, Jing Y, Ma Z, Bi J, Kinney PL. Heat and mortality for ischemic and hemorrhagic stroke in 12 cities of Jiangsu Province, China. Sci Total Environ 2017; 601-602:271-277.^,³¹31 Ikefuti, P, Barrozo, L, Braga, A. Mean air temperature as a risk factor for stroke mortality in São Paulo, Brazil. Int J Biometeorol 2018; 62(8):1535-1542.^,⁴¹41 Lim YH, Kim H, Hong YC. Variation in mortality of ischemic and hemorrhagic strokes in relation to high temperature. Int J Biometeorol 2013; 57:145-153..

Given the significant impact of extreme and moderate air temperatures on cerebrovascular disorders among the Brazilian population, it is important to stress the importance of stroke prevention measures. In this regard, heat wave and cold spell early warning systems have been adopted in various regions around the world with the aim of reducing morbidity and mortality caused by variations in weather, especially among vulnerable populations¹⁰10 Toloo G, FitzGerald G, Aitken P, Verrall K, Tong S. Evaluating the effectiveness of heat warning systems: systematic review of epidemiological evidence. Int J Public Health 2013; 58(5):667-681.^,¹¹11 Chau PH, Chan KC, Woo J. Hot weather warning might help to reduce elderly mortality in Hong Kong. Int J Biometeorol 2009; 53(5):461-468.^,⁴²42 Bassil KL, Cole DC. Effectiveness of public health interventions in reducing morbidity and mortality during heat episodes: a structured review. Int J Environ Res Public Health 2010; 7(3):991-1001.

43 Lowe D, Ebi KL, Forsberg B. Heatwave early warning systems and adaptation advice to reduce human health consequences of heatwaves. Int J Environ Res Public Health 2011; 8(12):4623-4648.

44 O'Neill MS, Carter R, Kish JK, Gronlund CJ, White-Newsome JL, Manarolla X, Zanobetti A, Schwartz JD. Preventing heat-related morbidity and mortality: new approaches in a changing climate. Maturitas 2009; 64(2):98-103.

45 Casanueva A, Burgstall A, Kotlarski S, Messeri A, Morabito M, Flouris AD, Nybo L, Spirig C, Schwierz C. Overview of Existing Heat-Health Warning Systems in Europe. Int J Environ Res Public Health 2019; 16(15):2657.

46 Public Health England. The Cold Weather Plan for England: Protecting health and reducing harm from cold Weather. London: Public Health England; 2018.^-⁴⁷47 World Meteorological Organization (WMO). World Health Organization (WHO). Heatwaves and Health: Guidance on Warning-System Development. Geneva: WHO; 2015.. These warnings allow individuals to prepare themselves and adapt their homes and daily activities to minimize exposure to extreme temperatures. Although only 9% of Brazilian homes have air conditioning⁴⁸48 Empresa de Pesquisa Energética. Nota Técnica EPE 030/2018 - Uso de Ar Condicionado no Setor Residencial Brasileiro: Perspectivas e contribuições para o avanço em eficiência energética. Brasília, EPE; 2018., the use of these devices appears to be an effective strategy for reducing heat-related deaths⁴⁹49 Sera F, Hashizume M, Honda Y, Lavigne E, Schwartz J, Zanobetti A, Tobias A, Iñiguez C, Vicedo-Cabrera AM, Blangiardo M, Armstrong B, Gasparrini A. Air Conditioning and Heat-related Mortality: A Multi-country Longitudinal Study. Epidemiology 2020; 31(6):779-787. as they regulate internal temperatures and reduce heat stress⁵⁰50 Deschenes O. Temperature, human health, and adaptation: a review of the empirical literature. Energy Econ 2014; 46:606-619.. In addition to warning systems, effective communication campaigns and education initiatives are needed to raise awareness about the health effects of climate⁴³43 Lowe D, Ebi KL, Forsberg B. Heatwave early warning systems and adaptation advice to reduce human health consequences of heatwaves. Int J Environ Res Public Health 2011; 8(12):4623-4648.

44 O'Neill MS, Carter R, Kish JK, Gronlund CJ, White-Newsome JL, Manarolla X, Zanobetti A, Schwartz JD. Preventing heat-related morbidity and mortality: new approaches in a changing climate. Maturitas 2009; 64(2):98-103.^-⁴⁵45 Casanueva A, Burgstall A, Kotlarski S, Messeri A, Morabito M, Flouris AD, Nybo L, Spirig C, Schwierz C. Overview of Existing Heat-Health Warning Systems in Europe. Int J Environ Res Public Health 2019; 16(15):2657.^,⁴⁷47 World Meteorological Organization (WMO). World Health Organization (WHO). Heatwaves and Health: Guidance on Warning-System Development. Geneva: WHO; 2015..

Conclusion

The findings of this analysis of 10 micro regions located in Brazil’s five regions show that both low and high non-optimal air temperatures are associated with increased risk of death from cerebrovascular diseases. Preventive and health education measures tailored to local demographic and climate characteristics, such as early warning systems, the provision of information on this problem to health professionals, and the use of air conditioning, should be adopted across different regions in order to reduce mortality from these diseases in Brazil.

References

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Lian H, Ruan Y, Liang R, Liu X, Fan Z. Short-Term Effect of Ambient Temperature and the Risk of Stroke: A Systematic Review and Meta-Analysis. Int J Environ Res Public Health 2015; 12(8):9068-9088.
³
Gasparrini A, Armstrong B. The impact of heat waves on mortality. Epidemiology 2011; 22(1):68-73.
⁴
Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238.
⁵
Zhou L, Chen K, Chen X, Jing Y, Ma Z, Bi J, Kinney PL. Heat and mortality for ischemic and hemorrhagic stroke in 12 cities of Jiangsu Province, China. Sci Total Environ 2017; 601-602:271-277.
⁶
Ban J, Xu D, He MZ, Sun Q, Chen C, Wang W, Zhu P, Li T. The effect of high temperature on cause-specific mortality: A multi-county analysis in China. Environ Int 2017; 106:19-26.
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Chen R, Wang C, Meng X, Chen H, Thach TQ, Wong CM, Kan H. Both low and high temperature may increase the risk of stroke mortality. Neurology 2013; 81(12):1064-1070.
⁸
GBD 2019 Risk Factors Collaborators. Global burden of 87 risk factors in 204 countries and territories, 1990-2019: a systematic analysis for the Global Burden of Disease Study 2019. Lancet 2020; 396(10258):1223-1249.
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Chen K, Breitner S, Wolf K, Rai M, Meisinger C, Heier M, Kuch B, Peters A, Schneider A. Projection of Temperature-Related Myocardial Infarction in Augsburg, Germany: Moving on From the Paris Agreement on Climate Change. Dtsch Arztebl Int 2019; 116(31-32):521-527.
¹⁰
Toloo G, FitzGerald G, Aitken P, Verrall K, Tong S. Evaluating the effectiveness of heat warning systems: systematic review of epidemiological evidence. Int J Public Health 2013; 58(5):667-681.
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Chau PH, Chan KC, Woo J. Hot weather warning might help to reduce elderly mortality in Hong Kong. Int J Biometeorol 2009; 53(5):461-468.
¹²
Brasil. Ministério da Saúde (MS). Banco de dados do Sistema Único de Saúde - DATASUS, Sistema de Informações sobre Mortalidade [Internet]. [acessado 2021 jun 20]. Disponível em https://datasus.saude.gov.br/.
» https://datasus.saude.gov.br
¹³
Dee DP, Uppala SM, Simmons AJ, Berrisford P, Poli P, Kobayashi S, Andrae U, Balmaseda MA, Balsamo G, Bauer P, Bechtold P, Beljaars ACM, van de Berg L, Bidlot J, Bormann N, Delsol C, Dragani R, Fuentes M, Geer AJ, Haimberger L, Healy SB, Hersbach H, Hólm EV, Isaksen L, Kållberg P, Köhler M, Matricardi M, McNally AP, Monge-Sanz BM, Morcrette J-J, Park B-K, Peubey C, Rosnay P, Tavolato C, Thépaut J-N, Vitart F. The ERA-Interim reanalysis: configuration and performance of the data assimilation system. Quart J Roy Meteor Soc 2011; 137(656):553-597.
¹⁴
Quadro MFL, Dias MAFS, Herdies DL, Gonçalves LGG. Análise climatológica da precipitação e do transporte de umidade na região da ZCAS através da nova geração de reanálises. Rev Bras Meteorol 2012; 27:152-162.
¹⁵
Moreira A, Fontana DC, Kuplich TM, Cardoso MA. Dados meteorológicos estimados em condições de clima subtropical e a relação com índices de Vegetação. Rev Bras Cartogr 2018; 70(4):1409-1436.
¹⁶
Sun Z, Chen C, Xu D, Li T. Effects of ambient temperature on myocardial infarction: A systematic review and meta-analysis. Environ Pollut 2018; 241:1106-1114.
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Gasparrini A, Armstrong B, Kenward MG. Distributed lag non-linear models. Stat Med 2010; 29:2224-2234.
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Jung, J, Lee JY, Lee H, Kim H. Predicted Future Mortality Attributed to Increases in Temperature and PM10 Concentration under Representative Concentration Pathway Scenarios. Int J Environ Res Public Health 2020; 17:2600.
¹⁹
Guo Y, Gasparrini A, Armstrong B, Li S, Tawatsupa B, Tobias A, Lavigne E, de Sousa Zanotti Stagliorio Coelho M, Leone M, Pan X, Tong S, Tian L, Kim H, Hashizume M, Honda Y, Guo YL, Wu CF, Punnasiri K, Yi SM, Michelozzi P, Saldiva PH, Williams G. Global variation in the effects of ambient temperature on mortality: a systematic evaluation. Epidemiology 2014; 25(6):781-789.
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Yang J, Zhou M, Li M, Yin P, Wang B, Pilot E, Liu Y, van der Hoek W, van Asten L, Krafft T, Liu Q. Diurnal temperature range in relation to death from stroke in China. Environ Res 2018; 164:669-675.
²⁸
Yang J, Liu HZ, Ou CQ, Lin GZ, Zhou Q, Shen GC, Chen PY, Guo Y. Global climate change: impact of diurnal temperature range on mortality in Guangzhou, China. Environ Pollut 2013; 175:131-136.
²⁹
Chen K, Huang L, Zhou, L, Ma Z, Bi J, Li T. Spatial analysis of the effect of the 2010 heat wave on stroke mortality in Nanjing, China. Sci Rep 2015; 5:10816.
³⁰
Fu SH, Gasparrini A, Rodriguez PS, Jha P. Mortality attributable to hot and cold ambient temperatures in India: a nationally representative case-crossover study. PLoS Med 2018; 15(7):e1002619.
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Ikefuti, P, Barrozo, L, Braga, A. Mean air temperature as a risk factor for stroke mortality in São Paulo, Brazil. Int J Biometeorol 2018; 62(8):1535-1542.
³²
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³⁷
Kottek M, Grieser J, Beck C, Rudolf B, Rubel F. World Map of the Köppen-Geiger climate classification updated. Meteorologische Zeitschrift 2006; 15:259-263.
³⁸
Santana N. Investigação de Ilhas de Calor em Brasília: Análise Multitemporal com Enfoque na Cobertura do Solo. Rev Bras Geogr Fis 2015; 1044-1054.
³⁹
Zavattini J, Fratianni S. Os climas Regionais do Brasil. Rev Depart Geogr Progr Pos-Grad Geogr UFAM 2018; 9(32):93-106.
⁴⁰
Silveira R, Alves M, Barreiro M, Bitencourt D. Ondas de calor nas capitais do Sul do Brasil e Montevidéu - Uruguai. Rev Bras Geogr Fis 2019; 12(4):1259-1276.
⁴¹
Lim YH, Kim H, Hong YC. Variation in mortality of ischemic and hemorrhagic strokes in relation to high temperature. Int J Biometeorol 2013; 57:145-153.
⁴²
Bassil KL, Cole DC. Effectiveness of public health interventions in reducing morbidity and mortality during heat episodes: a structured review. Int J Environ Res Public Health 2010; 7(3):991-1001.
⁴³
Lowe D, Ebi KL, Forsberg B. Heatwave early warning systems and adaptation advice to reduce human health consequences of heatwaves. Int J Environ Res Public Health 2011; 8(12):4623-4648.
⁴⁴
O'Neill MS, Carter R, Kish JK, Gronlund CJ, White-Newsome JL, Manarolla X, Zanobetti A, Schwartz JD. Preventing heat-related morbidity and mortality: new approaches in a changing climate. Maturitas 2009; 64(2):98-103.
⁴⁵
Casanueva A, Burgstall A, Kotlarski S, Messeri A, Morabito M, Flouris AD, Nybo L, Spirig C, Schwierz C. Overview of Existing Heat-Health Warning Systems in Europe. Int J Environ Res Public Health 2019; 16(15):2657.
⁴⁶
Public Health England. The Cold Weather Plan for England: Protecting health and reducing harm from cold Weather. London: Public Health England; 2018.
⁴⁷
World Meteorological Organization (WMO). World Health Organization (WHO). Heatwaves and Health: Guidance on Warning-System Development. Geneva: WHO; 2015.
⁴⁸
Empresa de Pesquisa Energética. Nota Técnica EPE 030/2018 - Uso de Ar Condicionado no Setor Residencial Brasileiro: Perspectivas e contribuições para o avanço em eficiência energética. Brasília, EPE; 2018.
⁴⁹
Sera F, Hashizume M, Honda Y, Lavigne E, Schwartz J, Zanobetti A, Tobias A, Iñiguez C, Vicedo-Cabrera AM, Blangiardo M, Armstrong B, Gasparrini A. Air Conditioning and Heat-related Mortality: A Multi-country Longitudinal Study. Epidemiology 2020; 31(6):779-787.
⁵⁰
Deschenes O. Temperature, human health, and adaptation: a review of the empirical literature. Energy Econ 2014; 46:606-619.

Publication Dates

Publication in this collection
22 July 2022
Date of issue
Aug 2022

History

Received
17 Nov 2021
Accepted
25 Apr 2022
Published
27 Apr 2022

Este é um artigo publicado em acesso aberto sob uma licença Creative Commons

[1] ¹
World Health Organization (WHO). Global Health Estimates 2016: Deaths by Cause, Age, Sex, by Country and by Region, 2000-2016. Geneva: WHO; 2018.

[2] ²
Lian H, Ruan Y, Liang R, Liu X, Fan Z. Short-Term Effect of Ambient Temperature and the Risk of Stroke: A Systematic Review and Meta-Analysis. Int J Environ Res Public Health 2015; 12(8):9068-9088.

[3] ³
Gasparrini A, Armstrong B. The impact of heat waves on mortality. Epidemiology 2011; 22(1):68-73.

[4] ⁴
Yang J, Yin P, Zhou M, Ou CQ, Li M, Li J, Liu X, Gao J, Liu Y, Qin R, Xu L, Huang C, Liu Q. The burden of stroke mortality attributable to cold and hot ambient temperatures: Epidemiological evidence from China. Environ Int 2016; 92-93:232-238.

[5] ⁵
Zhou L, Chen K, Chen X, Jing Y, Ma Z, Bi J, Kinney PL. Heat and mortality for ischemic and hemorrhagic stroke in 12 cities of Jiangsu Province, China. Sci Total Environ 2017; 601-602:271-277.

[6] ⁶
Ban J, Xu D, He MZ, Sun Q, Chen C, Wang W, Zhu P, Li T. The effect of high temperature on cause-specific mortality: A multi-county analysis in China. Environ Int 2017; 106:19-26.

[7] ⁷
Chen R, Wang C, Meng X, Chen H, Thach TQ, Wong CM, Kan H. Both low and high temperature may increase the risk of stroke mortality. Neurology 2013; 81(12):1064-1070.

[8] ⁸
GBD 2019 Risk Factors Collaborators. Global burden of 87 risk factors in 204 countries and territories, 1990-2019: a systematic analysis for the Global Burden of Disease Study 2019. Lancet 2020; 396(10258):1223-1249.

[9] ⁹
Chen K, Breitner S, Wolf K, Rai M, Meisinger C, Heier M, Kuch B, Peters A, Schneider A. Projection of Temperature-Related Myocardial Infarction in Augsburg, Germany: Moving on From the Paris Agreement on Climate Change. Dtsch Arztebl Int 2019; 116(31-32):521-527.

[10] ¹⁰
Toloo G, FitzGerald G, Aitken P, Verrall K, Tong S. Evaluating the effectiveness of heat warning systems: systematic review of epidemiological evidence. Int J Public Health 2013; 58(5):667-681.

[11] ¹¹
Chau PH, Chan KC, Woo J. Hot weather warning might help to reduce elderly mortality in Hong Kong. Int J Biometeorol 2009; 53(5):461-468.

[12] ¹²
Brasil. Ministério da Saúde (MS). Banco de dados do Sistema Único de Saúde - DATASUS, Sistema de Informações sobre Mortalidade [Internet]. [acessado 2021 jun 20]. Disponível em https://datasus.saude.gov.br/.
» https://datasus.saude.gov.br

[13] ¹³
Dee DP, Uppala SM, Simmons AJ, Berrisford P, Poli P, Kobayashi S, Andrae U, Balmaseda MA, Balsamo G, Bauer P, Bechtold P, Beljaars ACM, van de Berg L, Bidlot J, Bormann N, Delsol C, Dragani R, Fuentes M, Geer AJ, Haimberger L, Healy SB, Hersbach H, Hólm EV, Isaksen L, Kållberg P, Köhler M, Matricardi M, McNally AP, Monge-Sanz BM, Morcrette J-J, Park B-K, Peubey C, Rosnay P, Tavolato C, Thépaut J-N, Vitart F. The ERA-Interim reanalysis: configuration and performance of the data assimilation system. Quart J Roy Meteor Soc 2011; 137(656):553-597.

[14] ¹⁴
Quadro MFL, Dias MAFS, Herdies DL, Gonçalves LGG. Análise climatológica da precipitação e do transporte de umidade na região da ZCAS através da nova geração de reanálises. Rev Bras Meteorol 2012; 27:152-162.

[15] ¹⁵
Moreira A, Fontana DC, Kuplich TM, Cardoso MA. Dados meteorológicos estimados em condições de clima subtropical e a relação com índices de Vegetação. Rev Bras Cartogr 2018; 70(4):1409-1436.

[16] ¹⁶
Sun Z, Chen C, Xu D, Li T. Effects of ambient temperature on myocardial infarction: A systematic review and meta-analysis. Environ Pollut 2018; 241:1106-1114.

[17] ¹⁷
Gasparrini A, Armstrong B, Kenward MG. Distributed lag non-linear models. Stat Med 2010; 29:2224-2234.

[18] ¹⁸
Jung, J, Lee JY, Lee H, Kim H. Predicted Future Mortality Attributed to Increases in Temperature and PM10 Concentration under Representative Concentration Pathway Scenarios. Int J Environ Res Public Health 2020; 17:2600.

[19] ¹⁹
Guo Y, Gasparrini A, Armstrong B, Li S, Tawatsupa B, Tobias A, Lavigne E, de Sousa Zanotti Stagliorio Coelho M, Leone M, Pan X, Tong S, Tian L, Kim H, Hashizume M, Honda Y, Guo YL, Wu CF, Punnasiri K, Yi SM, Michelozzi P, Saldiva PH, Williams G. Global variation in the effects of ambient temperature on mortality: a systematic evaluation. Epidemiology 2014; 25(6):781-789.

[20] ²⁰
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Micro region		Min	Q1	Q2	Q3	Max	Mean	SD	Total
Mean temperature
	Belém	23.5	26.1	26.9	27.9	30.7	27.0	1.2	-
	Manaus	22.0	25.7	26.5	27.3	31.8	26.6	1.2	-
	Fortaleza	23.7	26.7	27.4	27.9	29.7	27.3	0.9	-
	Salvador	21.3	24.4	25.7	26.8	29.5	25.6	1.5	-
	Rio de Janeiro	13.8	21.2	23.4	25.7	31.3	23.4	3.0	-
	São Paulo	8.4	18.4	20.8	23.1	29.0	20.6	3.2	-
	Brasília	15.3	21.5	22.7	24.1	29.7	22.8	2.0	-
	Campo Grande	8.3	22.8	24.8	26.5	32.7	24.3	3.4	-
	Curitiba	4.5	16.1	19.0	21.7	27.6	18.7	3.8	-
	Porto Alegre	4.9	16.0	19.8	23.0	31.9	19.3	4.6	-
Deaths
	Belém	0	1	3	4	11	2.7	1.7	21,629
	Manaus	0	1	1	2	9	1.6	1.3	13,036
	Fortaleza	0	2	4	5	14	3.8	2.1	30,733
	Salvador	0	3	4	5	13	4.1	2.0	32,799
	Brasília	0	1	2	3	11	2.4	1.6	18,894
	Campo Grande	0	0	1	2	7	1.1	1.1	9,210
	Rio de Janeiro	5	17	21	24	60	21.0	5.3	168,480
	São Paulo	5	16	19	22	38	19.0	4.8	152,919
	Curitiba	0	2	4	5	13	3.9	2.0	31,481
	Porto Alegre	0	5	6	8	24	6.5	2.8	52,552

Micro region	Mean pop,	MMT (ºC)	Extreme cold	Moderate cold	Moderate heat	Extreme heat
Belém	2,047,823	29.6	1.14 (0.82-1.58)	1.12 (0.83-1.5)	1.08 (0.84-1.39)	1.03 (0.93-1.15)
Manaus	1,874,377	26.9	1.53 (1.22-1.91)	1.34 (1.11-1.63)	1.40 (1.14-1.72)	1.75 (1.35-2.26)
Fortaleza	3,181,555	26.6	1.21 (1.04-1.41)	1.04 (0.96-1.12)	1.08 (0.96-1.22)	1.10 (0.96-1.26)
Salvador	3,367,078	24.7	1.04 (0.89-1.21)	1.02 (0.91-1.14)	1.14 (0.99-1.3)	1.19 (1.01-1.4)
Brasília	2,411,607	23.3	1.13 (0.95-1.33)	1.07 (0.92-1.23)	1.24 (1.05-1.46)	1.36 (1.15-1.60)
Campo Grande	820,080	23.6	1.52 (1.18-1.94)	1.19 (0.96-1.47)	1.11 (0.92-1.34)	1.14 (0.91-1.43)
Rio de Janeiro	11,210,710	25.1	1.22 (1.15-1.3)	1.13 (1.08-1.19)	1.11 (1.07-1.16)	1.29 (1.22-1.37)
São Paulo	13,468,222	23.4	1.25 (1.17-1.34)	1.15 (1.09-1.22)	1.04 (1.01-1.06)	1.17 (1.11-1.24)
Curitiba	2,977,460	20.1	1.52 (1.32-1.74)	1.31 (1.16-1.47)	1.07 (0.94-1.22)	1.07 (0.93-1.22)
Porto Alegre	3,598,691	21.6	1.28 (1.14-1.43)	1.16 (1.05-1.28)	1.15 (1.05-1.27)	1.38 (1.24-1.54)

Micro region		Extreme cold	Moderate cold	Mild cold	Mild heat	Moderate heat	Extreme heat	Total
Temperature-attributable fraction (%)
	Belém	-	-	-	-	-	-	-
	Manaus	0.9 (0.4-1.3)	2.0 (1.0-2.8)	8.4 (1.9-14.3)	3.1 (0.9-4.9)	2.9 (1.6-4.0)	1.3 (0.8-1.8)	-
	Fortaleza	0.6 (0.1-1.0)	-	-	-	-	-	-
	Salvador	-	-	-	-	-	-	-
	Brasília	-	-	-	2.1 (0.2-3.9)	1.8 (0.8-2.8)	0.7 (0.3-1.0)	-
	Campo Grande	1.2 (0.7-1.7)	1.9 (0.3-3.2)	-	-	-	-	-
	Rio de Janeiro	0.7 (0.5-0.9)	1.1 (0.8-1.5)	3.3 (1.2-5.2)	0.6 (0.1-1.1)	1.1 (0.8-1.4)	0.8 (0.6-0.9)	-
	São Paulo	0.7 (0.4-0.9)	1.3 (0.9-1.7)	-	-	0.6 (0.4-0.8)	0.5 (0.4-0.7)	-
	Curitiba	1.2 (0.8-1.5)	2.4 (1.7-3.1)	5.1 (0.6-9.4)	-	-	-	-
	Porto Alegre	0.8 (0.5-1.1)	1.5 (0.8-2.2)	3.7 (0.0-7.0)	-	1.3 (0.88-1.9)	1.0 (0.8-1.2)	-
Temperature-attributable deaths
	Belém	-	-	-	-	-	-	-
	Manaus	123 (62-167)	256 (124-373)	1.098 (167-1861)	398 (135-630)	376 (212-508)	174 (98-227)	2.425
	Fortaleza	186 (31-296)	-	-	-	-	-	186
	Salvador	-	-	-	-	-	-	-
	Brasília	-	-	-	392 (12-714)	342 (120-515)	130 (56-189)	864
	Campo Grande	114 (59-155)	179 (34-294)	-	-	-	-	293
	Rio de Janeiro	1.108 (792-1411)	1.922 (1291-2477)	5.491 (2166-8747)	1.079 (178-1968)	1.852 (1353-2325)	1.286 (1034-1518)	12.738
	São Paulo	1.005 (664-1293)	1978 (1393-2588)	-	-	891 (572-1211)	840 (585-1079)	4.714
	Curitiba	374 (244-472)	766 (523-982)	374 (248-465)	1.615 (186-2906)	-	-	3.129
	Porto Alegre	426 (239-584)	794 (410-1156)	-	-	708 (406-1002)	528 (406-637)	2.456

Saúde Pública

Saúde Pública

The effect of air temperature on mortality from cerebrovascular diseases in Brazil between 1996 and 2017

Abstract

Introduction

Methods

Study population

Data

Statistical analysis

Results

Discussion

Conclusion

References

Publication Dates

History