Air pollution from forest burning as environmental risk for millions of inhabitants of the Brazilian Amazon: an exposure indicator for human health

Oliveira, Igor Neves de; Oliveira, Beatriz Fátima Alves de; Silveira, Ismael Henrique da; Machado, Lúbia Maieles Gomes; Villardi, Juliana Wotzasek Rulli; Ignotti, Eliane

doi:10.1590/0102-311XEN131422

Abstract:

In this study, we propose an indicator of air pollution exposure to identify potential hazardous areas for human health in the Amazon and Central-West Regions of Brazil from 2010 to 2019. This indicator aggregates both concentrations and time of exposure to fine particulate matter (PM_2.5), according to the current limit recommended by the World Health Organization (WHO). We used daily PM_2.5 averages obtained from the Brazilian Health Integrated Environmental Information System (SISAM) to calculate the percentages of days with PM_2.5 concentrations exceeding the limit of 15µg/m³ per year and per month. From 2010 to 2019, the months from August to October presented the largest areas and the highest percentages of days with unacceptable pollution concentration values, harmful to human health. These areas were concentrated in the Arc of Deforestation. Therefore, 60% of the residents of the Amazon and Central-West regions were subjected to inadequate air quality for approximately six months per year. The proposed indicator is reproducible and appropriate to monitor areas of exposure and risk for human health.

Keywords:
Fires; Particulate Matter; Air Pollution; Conservation of Natural Resources

Resumo:

Este estudo propõe um indicador de exposição à poluição do ar para identificar potenciais áreas de risco para a saúde humana na região amazônica e no Centro-oeste do Brasil de 2010 a 2019. Esse indicador agrega as concentrações e o tempo de exposição à partículas finas de poluição (PM_2.5), de acordo com o limite atual recomendado pela Organização Mundial da Saúde (OMS). Foram utilizadas médias diárias de PM_2.5 obtidas do Sistema de Informações Ambientais Integrado a Saúde (SISAM) para o cálculo dos percentuais de dias cujas concentrações ultrapassaram o limite de 15μg/m³ por ano e por mês. De 2010 a 2019, os meses de agosto a outubro apresentaram as maiores áreas e os maiores percentuais de dias com valores de concentração inaceitáveis para a saúde humana. Tais áreas estavam concentradas na região do arco do desmatamento. Além disso, 60% dos moradores da região amazônica e do Centro-oeste eram expostos a uma qualidade inadequada do ar por aproximadamente seis meses por ano. O indicador proposto é reprodutível e adequado para monitorizar as áreas de exposição e de risco para a saúde humana.

Palavras-chave:
Incêndios; Material Particulado; Poluição do Ar; Conservação dos Recursos Naturais

Resumen:

Este estudio propone un indicador de exposición a la contaminación del aire para identificar posibles áreas de riesgo para la salud humana en la región amazónica y el Medio Oeste de Brasil de 2010 a 2019. Este indicador agrega las concentraciones y el tiempo de exposición a partículas finas de contaminación (PM_2.5), de acuerdo con el límite actual recomendado por la Organización Mundial de la Salud (OMS). Se utilizaron los promedios diarios de PM_2.5 obtenidos del Sistema Integrado de Información Ambiental en Salud (SISAM) para calcular el porcentaje de días cuyas concentraciones superaron el límite de 15μg/m³ por año y por mes. En la década de 2010 a 2019, los meses de agosto a octubre tuvieron las áreas más grandes y los porcentajes más altos de días con valores de concentración inaceptables para la salud humana. Tales áreas se concentraron en la región del arco de la deforestación. Además, el 60% de los residentes de la región amazónica y el Medio Oeste estuvieron sujetos a una calidad del aire inadecuada durante aproximadamente seis meses al año. El indicador propuesto es reproducible y adecuado para monitorizar las áreas de exposición y de riesgo para la salud humana.

Palablas-clave:
Incendios; Material Particulado; Contaminación del Aire; Conservación dos Recursos Naturales

Introduction

Historically, Brazil has been constantly facing critical events of wildfires and burns. Over 36 years (1985-2020), Brazilian fires accounted for an area that is larger than England, burning about 150,957km² per year (1.8% of the country), which represents a cumulative number of 1,672,142km² (19.6%) consumed by burnings and/or wildfires. The most affected biomes, according to area proportion, were the Pantanal (57%), the Cerrado (36%), and the Amazon Forest (16.4%). The latter two represent 85% of the entire burned area ¹1. Rede MapBiomas. A cada ano, Brasil queima área maior que a Inglaterra. https://mapbiomas.org/a-cada-ano-brasil-queima-area-maior-que-a-inglaterra (accessed on 12/Oct/2021).
https://mapbiomas.org/a-cada-ano-brasil-... .

In the Central-West and North regions of Brazil, where fire outbreaks have been more frequent, the upward movement of pollution is caused by the generated heat, the lower density of formed particles, and the gases in the air. These effects, associated with air currents, cause pollution dispersion from the local level to the regional and even continental levels ²2. Freitas SR, Longo KM, Silva Dias MAF, Silva Dias PL. Emissões de queimadas em ecossistemas da América do Sul. Estud Av 2005; 19:167-85.. Fine particulate matter (PM_2.5) is the major pollutant emitted by wildfires smoke, and its negative effects on human health are well known ³3. Reddington CL, Butt EW, Ridley DA, Artaxo P, Morgan WT, Coe H, et al. Air quality and human health improvements from reductions in deforestation-related fire in Brazil. Nat Geosci 2015; 8:768-71.^,⁴4. Ye T, Guo Y, Chen G, Yue X, Xu R, Coêlho MSZS, et al. Risk and burden of hospital admissions associated with wildfire-related PM2.5 in Brazil, 2000-15: a nationwide time-series study. Lancet Planet Health 2021; 5:e599-607., including the increased morbidity and mortality due to cardiovascular and respiratory diseases, which especially affects the more vulnerable population subgroups such as children and older adults ⁵5. Ignotti E, Hacon SS, Junger WL, Mourão D, Longo K, Freitas S, et al. Air pollution and hospital admissions for respiratory diseases in the subequatorial Amazon: a time series approach. Cad Saúde Pública 2010; 26:747-61.^,⁶6. Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Saldiva PHN, et al. Acute effects of particulate matter and black carbon from seasonal fires on peak expiratory flow of schoolchildren in the Brazilian Amazon. PLoS One 2014; 9:e104177.^,⁷7. Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Ponce de Leon ACM. Association between fine particulate matter and the peak expiratory flow of schoolchildren in the Brazilian subequatorial Amazon: a panel study. Environ Res 2012; 117:27-35.^,⁸8. Nunes KVR, Ignotti E, Hacon SS. Circulatory disease mortality rates in the elderly and exposure to PM2.5 generated by biomass burning in the Brazilian Amazon in 2005. Cad Saúde Pública 2013; 29:589-98..

Forest fires are influenced by both climate and human-driven land-use changes. Strengthening environmental policies to control the incidence of fire can improve air quality and reduce negative impacts on public health ³3. Reddington CL, Butt EW, Ridley DA, Artaxo P, Morgan WT, Coe H, et al. Air quality and human health improvements from reductions in deforestation-related fire in Brazil. Nat Geosci 2015; 8:768-71.. In the Brazilian Amazon, the reduction of deforestation rates from 2001 to 2012 resulted in a 30% reduction of PM emissions in wildfires, preventing about 400 to 1,700 premature deaths of adults per year ³3. Reddington CL, Butt EW, Ridley DA, Artaxo P, Morgan WT, Coe H, et al. Air quality and human health improvements from reductions in deforestation-related fire in Brazil. Nat Geosci 2015; 8:768-71.. However, the increasing rates of deforestation from 2014 to 2019 have caused increased fire count and degraded air quality, which resulted in 3,400 (3,300-3,550) additional deaths in 2019 due to increased PM emissions ⁹9. Butt EW, Conibear L, Knote C, Spracklen DV. Large air quality and public health impacts due to Amazonian deforestation fires in 2019. GeoHealth 2021; 5:e2021GH000429..

In Brazil, concerns about the effects of air pollution on human health are mainly directed to metropolitan areas with air quality monitoring, where exposures mostly derive from fossil fuel or industrial production sources ¹⁰10. Pereira BB, Limongi JE. Epidemiologia de desfechos na saúde humana relacionados à poluição atmosférica no Brasil: uma revisão sistemática. Cad Saúde Colet (Rio J.) 2015; 23:91-100.^,¹¹11. Santos UP, Arbex MA, Braga ALF, Mizutani RF, Cançado JED, Terra-Filho M, et al. Poluição do ar ambiental: efeitos respiratórios. J Bras Pneumol 2021; 47:e20200267. The North Region - where most of the Brazilian Amazon is located - and the Central-West Region are less industrialized than other regions of Brazil; however, they present a large territory and 40 million inhabitants ¹²12. Instituto Brasileiro de Geografia e Estatística. Estimativas de população. https://www.ibge.gov.br/estatisticas/sociais/populacao/9103-estimativas-de-populacao.html?=&t=resultados (accessed on 17/Dec/2021).
https://www.ibge.gov.br/estatisticas/soc... . During periods of increased burns, these inhabitants inhale polluted air up to five times higher than the maximum limits recommended by the World Health Organization (WHO) for PM_2.5¹³13. Sant'Anna AB, Alencar A, Téllez-Chávez L, Carvalho A, Guimarães A, Moutinho P. O ar é insuportável: os impactos das queimadas associadas ao desmatamento da Amazônia brasileira na saúde. https://www.hrw.org/pt/report/2020/08/26/376135 (accessed on 17/Dez/2021).
https://www.hrw.org/pt/report/2020/08/26... . This population has limited access to information related to air quality levels. The government, along with environmental and health regulatory agencies, should regularly inform people regarding air quality ¹⁴14. Vormittag EMPAA, Cirqueira SSR, Wicher Neto H, Saldiva PHN. Análise do monitoramento da qualidade do ar no Brasil. Estud Av 2021; 35:7-30.. In the few localities where such information is provided, it is usually limited to daily and annual averages. However, for seasonal exposures caused by biomass burning, such measures may not express the annual magnitude of the exposure to poor air quality to which those residents are exposed since they do not have evidence of the time of exposure.

In 2010, a methodological approach based on the percentage of annual hours of PM_2.5 > 80µg/m³ was proposed as an indicator of air pollution exposure in the Brazilian Amazon ¹⁵15. Ignotti E, Valente JG, Longo KM, Freitas SR, Hacon SDS, Artaxo Netto P. Impact on human health of particulate matter emitted from burnings in the Brazilian Amazon region. Rev Saúde Pública 2010; 44:121-30.. This indicator showed an association with occurrences of respiratory diseases in the Brazilian Amazon region, as well as the feasibility of using an estimated environmental database. However, the application of this indicator was limited due to the unavailability of environmental data. Recently, with the restructuring of the Brazilian Health Integrated Environmental Information System (SISAM) and the availability of PM_2.5 data estimated by the Copernicus Atmosphere Monitoring Service (CAMS), a new indicator to deal with the effects of forest fire on human health is possible. Thus, we propose an indicator of air pollution exposure to identify potential hazardous areas for human health in the Amazon and Central-West regions of Brazil from 2010 to 2019. This indicator aggregates both concentrations and time of exposure to the pollutant fine particulate matter (PM_2.5), according to the current limit of 15µg/m³, recommended by the WHO ¹⁶16. World Health Organization. WHO global air quality guidelines: particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide. Geneva: World Health Organization; 2021..

Material and methods

Study area

The study area included the entire Brazilian Amazon and some surroundings areas, encompassing the three biomes that were most degraded by fire in recent years: the Amazon, the Cerrado, and the Pantanal. The study included all municipalities located in the Federative Units (UF) of the North region (Acre, Amapá, Amazonas, Rondônia, Pará, Roraima, and Tocantins), of the Central-West region (Federal District, Goiás, Mato Grosso, and Mato Grosso do Sul), and the State of Maranhão. Despite not being located in the Brazilian Amazon territory, the cities of the state of Maranhão located east of the meridian 44º were also included because they are part of the Cerrado biome. A total of 1,134 municipalities were included, corresponding to an approximate area of 6 million km², equivalent to 68% of the Brazilian territory, with more than 42 million inhabitants in 2021 ¹²12. Instituto Brasileiro de Geografia e Estatística. Estimativas de população. https://www.ibge.gov.br/estatisticas/sociais/populacao/9103-estimativas-de-populacao.html?=&t=resultados (accessed on 17/Dec/2021).
https://www.ibge.gov.br/estatisticas/soc... ^,¹⁷17. Instituto Brasileiro de Geografia e Estatística. Áreas territoriais. https://www.ibge.gov.br/geociencias/organizacao-do-territorio/estrutura-territorial/15761-areas-dos-municipios.html?=&t=acesso-ao-produto (accessed on 17/Dec/2021).
https://www.ibge.gov.br/geociencias/orga... .

Data source

To assess air quality, daily PM_2.5 concentrations were used. Data were obtained from the reanalysis models of the CAMS, from the European Centre for Medium-Range Weather Forecasts (ECMWF) (CAMS-Reanalysis 2010-2017 and CAMS-Nrealtime 2018-2019), provided by Brazil’s SISAM. Data have a resolution of 0.125º and are provided for four times of the day: 12:00am, 06:00am, 12:00pm and 06:00pm, which were used to calculate the daily averages.

Hot spots refer to the points of fires or reference measured by satellites in accumulated quantities for each municipality. Data referring to burns and wildfires were obtained via total number of records of hot spots in the vegetation. These data are also available in the SISAM from 2002 onward.

Calculation of the percentage indicator of days with inadequate air quality

According to the Global Air Quality Guidelines developed by the WHO ¹⁶16. World Health Organization. WHO global air quality guidelines: particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide. Geneva: World Health Organization; 2021., the daily average PM_2.5 concentration has a limit of 15µg/m³. Based on this parameter, we calculated the percentages of days with PM_2.5 concentrations exceeding the recommended limit, considered as “poor air quality” in our study. This indicator was calculated for all municipalities via the following equations - for each year of the studied series (a), for each month considering the entire decade (b), for the decade (c), and the month of each year (d):

(a) = \frac{Σ n u m b e r o f d a y s i n t h e y e a r w i t h {P M}_{2.5} > 15 μ g / m^{3}}{365} * 100 %

(b) = \frac{Σ n u m b e r o f d a y s i n t h e m o n t h (t h e d e c a d e) w i t h {P M}_{2.5} > 15 μ g / m^{3}}{10 * 30} * 100 %

(c) = \frac{Σ n u m b e r o f d a y s i n t h e d e c a d e w i t h {P M}_{2.5} > 15 μ g / m^{3}}{365 * 10} * 100 %

(d) = \frac{Σ n u m b e r o f d a y s i n t h e m o n t h w i t h {P M}_{2.5} > 15 μ g / m^{3}}{30} * 100 %

Data analysis

Maps of PM_2.5 exposure indicators were created using the geostatistical interpolation method based on Inverse Distance Weighting (IDW), weighting by the inverse variance of distance of sample points in the study area. Thus, at the end of processing, it generates a file in raster format with 0.01º of distance to each grid point. The technique consists of predicting values for locations with no information by weighting the values of sample points, which, in this case, are represented by the indicator of each municipality. The method assumes that closer values will have a greater weight in the estimates than farther values ¹⁸18. Murara P. Técnicas de interpolação para a pesquisa em climatologia regional e agroclimatologia. Revista Brasileira de Climatologia 2019; 15(Edição Especial):106-26.. IDW interpolation is deterministic and establishes a known continuous surface ¹⁹19. Mello CR, Lima JM, Silva AM, Mello JM, Oliveira MS. Krigagem e inverso do quadrado da distância para interpolação dos parâmetros da equação de chuvas intensas. Revista Brasileira de Ciência do Solo 2003; 27:925-33.. In this research, IDW interpolation maps were produced showing the annual and monthly percentages of “poor air quality”. Note that the metric error of the interpolation was not estimated. Deterministic interpolations are based directly on measured values close to sampled value and employ arbitrary or empirical models. No model error estimation was performed; thus, there is no strict assumption about the variability of a variable ²⁰20. Hengl T. A Practical guide to geostatistical mapping of environmental variables. Luxembourg: Office for Official Publications of the European Communities; 2007.. Data and graphs were processed in the R programming language, version 4.0.2 (http://www.r-project.org), and the interpolation maps were made in ArcGIS, version 10.5 (http://www.esri.com/software/arcgis/index.html).

Estimate of the population exposed to poor air quality

The total number of residents in the municipalities where percentage of days with poor air quality exceeded 25% per year was summed, equivalent to at least three months per year. Values on the population per municipalities were provided by the Brazilian Institute of Geography and Statistics (IBGE) and made available by the Brazilian Health Informatics Department (DATASUS). Details of the estimates are presented in the Supplementary Material (https://cadernos.ensp.fiocruz.br/static//arquivo/suppl-csp-1314-22_2784.pdf).

Results

The study shows large areas with more than 15% of days with poor air quality in all years. Thus, in two or more months of each year at least 20 million inhabitants were exposed to poor air quality (Figure 1 and Figure S1, Supplementary Material: https://cadernos.ensp.fiocruz.br/static//arquivo/suppl-csp-1314-22_2784.pdf). The largest areas occurred in 2015, with percentages ranging from 35% to 60%, which is equivalent to prolonged exposures of 4 to 6.5 months. The highest percentages were found in the states within the Brazilian Amazon.

Figure 1
Annual percentage of days exceeding 15µg/m³ PM_2.5 concentrations in the Amazon and Central-West regions of Brazil, 2010-2019.

The monthly percentages show the seasonal pattern of exposure (Figure 2). The largest area can be seen from August to December, reaching 80% to 99% of the days of the month (25 to 30 days). The Brazilian Amazon extends from the western end of Acre to the south/southeast of Amazonas, center-south of Pará and Maranhão, on the border between the states of Tocantins and Goiás. It encompasses the entire states of Rondônia and Mato Grosso, reaching the Pantanal in the state of Mato Grosso do Sul. In the first four months of the year, percentages higher than 50% (more than 15 days/month), as well as those considered the highest percentages for the period, from 70% to 80% (20 to 25 days/month), are distributed only in northern Brazil, covering part of the states of Roraima and Amapá and some areas in the north of Amazonas and Pará - above the Equator line. The maps of hot spots complement the analysis about the areas presenting high levels of PM_2.5, by showing the regions more frequently burned in the Brazilian Amazon and its surroundings (Figure S2 and Figure S3, https://cadernos.ensp.fiocruz.br/static//arquivo/suppl-csp-1314-22_2784.pdf).

Figure 2
Monthly percentage of days exceeding 15µg/m³ PM_2.5 concentrations in the Amazon and Central-West regions of Brazil, 2010-2019.

In the Supplementary Material, Table S1 characterizes the time of exposure to “poor air quality” in all studied capitals and ten municipalities (all located in the central region of the Amazon) that presented the highest percentages of days with PM_2.5 above of 15µg/m³. Table S2 complements this information by presenting the descriptive analysis for the capitals and the 10 municipalities (Supplementary Material: https://cadernos.ensp.fiocruz.br/static//arquivo/suppl-csp-1314-22_2784.pdf).

Figure 3 complements the description of the municipalities, as well as the state capitals, showing how the annual and quarterly percentages of high exposures identified in Figure 2 (from January to March and from August to October) are distributed. The period from August to October presented a longer exposure time to poor air quality, with 75% to 100% of the days in the 10 municipalities presented. The months from January to March influenced the exposure time in six municipalities in Amazonas, with percentages around 35%, approximately 30/90 days. For Boa Vista (Roraima State), Belém (Pará State), Macapá (Amapá State), and São Luís (Maranhão State), the estimated pollution levels for the first months of the year contribute to the percentage of days with poor air quality. For the other regions, the estimates for the months from August to October were used.

Figure 3
Distribution of the percentage of days with PM_2.5 > 15µg/m³ in the capitals and municipalities with the highest risk of exposure in the Amazon and Central-West regions, according to the annual period and for the dry and rainy seasons.

For the total population of the study area, at least 24 million inhabitants were exposed to poor air quality for at least three months per year, especially in the Amazon region, where more than half of its population (≅15 million) was subjected to this period of exposure every year. Annual estimates of the exposed population contingent, separately for the Amazon and Central-West regions, are presented in Figure S3a and Figures S3b (Supplementary Material: https://cadernos.ensp.fiocruz.br/static//arquivo/suppl-csp-1314-22_2784.pdf).

Discussion

The percentage indicator of days in which PM_2.5 concentrations exceeded the limits proposed by the WHO made it possible to combine concentration and time of exposure to characterize exposure to poor air quality, identifying areas of risk for human health. The indicator showed that millions of residents in the Brazilian Amazon and its surrounding areas were exposed to poor air quality for long periods every year due to wildfires and burns. The impacts of this exposure on human health have been clearly explained for decades ¹⁶16. World Health Organization. WHO global air quality guidelines: particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide. Geneva: World Health Organization; 2021.. Specifically in the Brazilian Amazon, a series of studies show the harmful effects to health caused by pollution from biomass burning ³3. Reddington CL, Butt EW, Ridley DA, Artaxo P, Morgan WT, Coe H, et al. Air quality and human health improvements from reductions in deforestation-related fire in Brazil. Nat Geosci 2015; 8:768-71.^,⁴4. Ye T, Guo Y, Chen G, Yue X, Xu R, Coêlho MSZS, et al. Risk and burden of hospital admissions associated with wildfire-related PM2.5 in Brazil, 2000-15: a nationwide time-series study. Lancet Planet Health 2021; 5:e599-607.^,⁵5. Ignotti E, Hacon SS, Junger WL, Mourão D, Longo K, Freitas S, et al. Air pollution and hospital admissions for respiratory diseases in the subequatorial Amazon: a time series approach. Cad Saúde Pública 2010; 26:747-61.^,⁶6. Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Saldiva PHN, et al. Acute effects of particulate matter and black carbon from seasonal fires on peak expiratory flow of schoolchildren in the Brazilian Amazon. PLoS One 2014; 9:e104177.^,⁷7. Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Ponce de Leon ACM. Association between fine particulate matter and the peak expiratory flow of schoolchildren in the Brazilian subequatorial Amazon: a panel study. Environ Res 2012; 117:27-35.^,²¹21. Alves NO, Vessoni AT, Quinet A, Fortunato RS, Kajitani GS, Peixoto MS, et al. Biomass burning in the Amazon region causes DNA damage and cell death in human lung cells. Sci Rep 2017; 7:10937..

Despite not being included in the areas with the most critical records of hot spots, six of the ten municipalities with the highest percentages of days with poor air quality during 2010-2019 are in the central portion of the State of Amazonas. It is a region situated in the area of influence of the PM_2.5 dispersion flow, from East to West in the dry season ²2. Freitas SR, Longo KM, Silva Dias MAF, Silva Dias PL. Emissões de queimadas em ecossistemas da América do Sul. Estud Av 2005; 19:167-85., and this is why some areas not involved in burnings are strongly affected by poor air quality ¹⁵15. Ignotti E, Valente JG, Longo KM, Freitas SR, Hacon SDS, Artaxo Netto P. Impact on human health of particulate matter emitted from burnings in the Brazilian Amazon region. Rev Saúde Pública 2010; 44:121-30..

The reduction in fires associated exclusively with deforestation can cause mean surface particulate matter concentrations to decline by approximately 30%, mainly in the dry season ³3. Reddington CL, Butt EW, Ridley DA, Artaxo P, Morgan WT, Coe H, et al. Air quality and human health improvements from reductions in deforestation-related fire in Brazil. Nat Geosci 2015; 8:768-71.. However, the increased number of hot spots in the central portion of the Amazon, known as the Arc of Deforestation, shows the expansion of the deforested and burnt area in the region. The occurrence of hot spots in the Amazon and the practice of deforestation are closely related, even in years of milder droughts, and the main source of ignition is human action ²²22. Silvério D, Silva S, Alencar A, Moutinho P. Amazônia em chamas. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2019. (Nota Técnica, 1).. The dynamics of hot spots, particularly in 2019, also reinforce the recent trend of increased forest burnings and deforestation associated with illegal occupation and land grabbing in this region ²³23. Alencar A, Moutinho P, Arruda V, Balzani C, Ribeiro J. Amazônia em Chamas: onde está o fogo. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2019. (Nota Técnica, 2)..

The increasing deforestation of the Amazon biome and its surroundings in recent years ²⁴24. Instituto Nacional de Pesquisas Espaciais. Taxas de desmatamento. http://terrabrasilis.dpi.inpe.br/app/dashboard/deforestation/biomes/legal_amazon/rates (accessed on 19/Sep/2021).
http://terrabrasilis.dpi.inpe.br/app/das... , mainly the expansion of the Arc of Deforestation revealed by the Socio-environmental Institute ²⁵25. Instituto Socioambiental. O arco do desmatamento e suas flechas. https://acervo.socioambiental.org/sites/default/files/documents/prov0115.pdf (accessed on 21/Aug/2020).
https://acervo.socioambiental.org/sites/... , may cause this region to accumulate more combustible material, leading to increasingly severe fire seasons during the dry season ²⁶26. Moutinho P, Alencar A, Rattis L, Arruda V, Castro I, Artaxo P. Amazônia em chamas: desmatamento e fogo em tempos de Covid-19. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2020. (Nota Técnica, 4).. Consequently, we estimate the occurrence of long periods with poor air quality, as our results indicate municipalities with daily PM_2.5 concentrations much above the acceptable level, with averages higher than 1,000µg/m³. The research highlights that the city of São Paulo, located in the southeast region of the country, presents around 80% of days with PM_2.5 averages above the acceptable limit of 15µg/m³ from June to September, that is, between the winter and the beginning of spring, when rains are less frequent and temperature inversions occur. Even so, the maximum daily PM_2.5 concentrations have not exceeded 70µg/m³ in the monitoring stations of the metropolitan area ²⁷27. Companhia Ambiental do Estado de São Paulo. Qualoidade do ar no Estado de São Paulo. https://cetesb.sp.gov.br/ar/wp-content/uploads/sites/28/2021/05/Relatorio-de-Qualidade-do-Ar-no-Estado-de-Sao-Paulo-2020.pdf (accessed on 29/May/2022).
https://cetesb.sp.gov.br/ar/wp-content/u... . In the Brazilian Amazon, air pollutant emissions generated by fires can expose children and adolescents to a PM_2.5 concentration that is twice as high as the safe limit, which adverse health effects are not observed ²⁸28. Oliveira BFA, Ignotti E, Artarxo P, Saldiva PHN, Junger WL, Hacon S. Risk assessment of PM2.5 to child residents in Brazilian Amazon region with biofuel production. Environ Health 2012; 11:64..

Studies conducted in municipalities of the Amazon and Central-West regions have reported the association between acute effects (immediate, lagged, and cumulative) on respiratory health, mainly in children and older adults, and exposure to increased PM_2.5 concentrations (gradients of 3.5µg/m³, 5μg/m³ and 10µg/m³) ⁴4. Ye T, Guo Y, Chen G, Yue X, Xu R, Coêlho MSZS, et al. Risk and burden of hospital admissions associated with wildfire-related PM2.5 in Brazil, 2000-15: a nationwide time-series study. Lancet Planet Health 2021; 5:e599-607.^,⁵5. Ignotti E, Hacon SS, Junger WL, Mourão D, Longo K, Freitas S, et al. Air pollution and hospital admissions for respiratory diseases in the subequatorial Amazon: a time series approach. Cad Saúde Pública 2010; 26:747-61.^,⁶6. Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Saldiva PHN, et al. Acute effects of particulate matter and black carbon from seasonal fires on peak expiratory flow of schoolchildren in the Brazilian Amazon. PLoS One 2014; 9:e104177.^,⁷7. Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Ponce de Leon ACM. Association between fine particulate matter and the peak expiratory flow of schoolchildren in the Brazilian subequatorial Amazon: a panel study. Environ Res 2012; 117:27-35.^,²⁹29. Carmo CN, Hacon S, Longo KM, Freitas S, Ignotti E, Ponce de Leon A, et al. Associação entre material particulado de queimadas e doenças respiratórias na região sul da Amazônia brasileira. Rev Panam Salud Pública 2010; 27:10-6.^,³⁰30. Carmo CN, Alves MB, Hacon SS. Impact of biomass burning and weather conditions on children's health in a city of Western Amazon region. Air Quality Atmosphere & Health 2013; 6:517-25.^,³¹31. Silva AMC, Mattos IE, Ignotti E, Hacon SS. Material particulado originário de queimadas e doenças respiratórias. Rev Saúde Pública 2013; 47:345-52.^,³²32. Machin AB, Nascimento LFC. Efeitos da exposição a poluentes do ar na saúde das crianças de Cuiabá, Mato Grosso, Brasil. Cad Saúde Pública 2018; 34:e00006617.^,³³33. Machin AB, Nascimento LF, Mantovani K, Machin EB. Effects of exposure to fine particulate matter in elderly hospitalizations due to respiratory diseases in the South of the Brazilian Amazon. Braz J Med Biol Res 2019; 52:e8130.^,³⁴34. Menezes RAM, Pavanitto DR, Nascimento LFC. Exposição a poluentes do ar e doença respiratória em meninos e meninas. Rev Paul Pediatr 2019; 37:166-72.^,³⁵35. Santana DP, Santos VM, Silva AMC, Shimoya-Bittencourt W. Influence of air pollutants on pneumonia hospitalizations among children in a town in the Brazilian Legal Amazon region: a time series study. São Paulo Med J 2020; 138:126-32..

Other studies have shown the relationship between these particulates and increased risks for development of chronic problems. Silva et al. ³⁶36. Silva AMC, Moi GP, Mattos IE, Hacon SS. Low birth weight at term and the presence of fine particulate matter and carbon monoxide in the Brazilian Amazon: a population-based retrospective cohort study. BMC Pregnancy Childbirth 2014; 14:309. identified associations between exposure to high PM_2.5 concentrations and low-weight newborns in municipalities located in the Amazon and the Cerrado. Alves et al. ²¹21. Alves NO, Vessoni AT, Quinet A, Fortunato RS, Kajitani GS, Peixoto MS, et al. Biomass burning in the Amazon region causes DNA damage and cell death in human lung cells. Sci Rep 2017; 7:10937. found that exposure of human lung cells to inhalable particles in the Amazon significantly increases DNA damage and cell death, elucidating lung cancer development mechanisms mediated by aerosols from burns and wildfires.

The social problems faced by the regions increase the populations’ vulnerability to this environmental problem, as the most affected areas show few high-complexity hospitals and primary care services, which hinders access, mainly in the western portion of the Amazon, in the Arc of Deforestation (in southeastern Pará and northern Mato Grosso), and throughout the Pantanal biome ³⁷37. Observatório do Clima, Instituto de Comunicação e Informação Científica e Tecnológica em Saúde, Fundação Oswaldo Cruz. Covid-19 e queimadas na Amazônia Legal e no Pantanal: aspectos cumulativos e vulnerabilidades. Rio de Janeiro: Fundação Oswaldo Cruz; 2020. (Nota Técnica)..

Few studies conducted in Brazil have used indicators that combine level and time of exposure to investigate the association between air pollution and health outcomes in the Amazon. The annual percentage of hours with critical PM_2.5 concentrations (> 80µg/m³), used by Ignotti et al. ¹⁵15. Ignotti E, Valente JG, Longo KM, Freitas SR, Hacon SDS, Artaxo Netto P. Impact on human health of particulate matter emitted from burnings in the Brazilian Amazon region. Rev Saúde Pública 2010; 44:121-30. and Silva et al. ³⁸38. Silva AMC, Mattos IE, Freitas SR, Longo KM, Hacon SS. Particulate matter (PM2.5) of biomass burning emissions and respiratory diseases in the South of the Brazilian Amazon. Rev Bras Epidemiol 2010; 13:337-51., as well as the annual percentage of hours with PM_2.5 concentrations above 25µg/m³, used by Nunes et al. ⁸8. Nunes KVR, Ignotti E, Hacon SS. Circulatory disease mortality rates in the elderly and exposure to PM2.5 generated by biomass burning in the Brazilian Amazon in 2005. Cad Saúde Pública 2013; 29:589-98., were associated with hospitalizations due to respiratory and cardiovascular problems in susceptible groups. These findings suggest the possibility of using the indicator in epidemiological studies, in analyses of the health situation for environmental health surveillance, or, at least, in risk communications to the population and decision-makers.

According to Urrutia-Pereira et al. ³⁹39. Urrutia-Pereira M, Rizzo LV, Chong-Neto HJ, Solé D. Impacto da exposição à fumaça da queima de biomassa na Floresta Amazônica na saúde humana. J Bras Pneumol 2021; 47:e20210219., despite the health impact caused by biomass burning in the Amazon Forest, the region still lacks public policies to improve the actions of health professionals and the transmission of information, aiming at protecting the population and improving the quality of life. We highlight that, today, few states have an air quality monitoring network based on low-cost PurpleAir PA-II-SP sensors (https://www2.purpleair.com/), and only in Acre State it is supported by the Public Prosecutor’s Office and by universities, among other collaborators (http://www.acrequalidadedoar.info). Other states, such as Mato Grosso State and Pará State, whose populations are extremely exposed and affected by the emission of air pollutants, do not have air quality monitoring systems.

In regions lacking monitoring stations, the use of modeled data can be a valid alternative. However, the lack of measured or observed data prevents the validation and/or application of correction factors to estimated exposure data, which is the main limitation of our study. Thus, the relevance of modeled data is undeniable, given the territorial and population scope of the estimates and their strategic use in the creation of public health policies. We emphasize the importance of ensuring that the 99th percentile of the annual distribution of average daily PM_2.5 concentrations for 24 hours, as standardized by the WHO ¹⁶16. World Health Organization. WHO global air quality guidelines: particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide. Geneva: World Health Organization; 2021., must not exceed 3 to 4 days over the 15µg/m³ limit per year. In this study, we evaluated the frequency that this value is exceeded. For this reason, the excluding data above the 99th percentile does not result in differences in the percentage of days with exceeding 15µg/m³ PM_2.5 concentrations . In other words, the period of exposure to high levels of PM_2.5 is continuous and reaches, at least, three months every year in most regions.

The proposed indicator is reproducible and appropriate to monitor areas of exposure and risk for human health. The research shows that half of the Brazilian Amazon and Central-West Region population was exposed annually and for long periods to inadequate daily PM_2.5 concentrations. We recommend the use of this indicator in epidemiological studies to investigate its relationship to health outcomes. Its application in environmental health surveillance systems and in the elaboration of effective monitoring policies/plans for the control of burns and wildfires is also important.

Acknowledgments

We would like to thank the institutions involved and the funder (Brazilian Coordination for the Improvement of Higher Education Personnel - CAPES). Financing source CAPES 155, of August 10, 2022, PDPG Consolidation Programs 3-4 process 88881.710435/2022-01.

References

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²
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³
Reddington CL, Butt EW, Ridley DA, Artaxo P, Morgan WT, Coe H, et al. Air quality and human health improvements from reductions in deforestation-related fire in Brazil. Nat Geosci 2015; 8:768-71.
⁴
Ye T, Guo Y, Chen G, Yue X, Xu R, Coêlho MSZS, et al. Risk and burden of hospital admissions associated with wildfire-related PM2.5 in Brazil, 2000-15: a nationwide time-series study. Lancet Planet Health 2021; 5:e599-607.
⁵
Ignotti E, Hacon SS, Junger WL, Mourão D, Longo K, Freitas S, et al. Air pollution and hospital admissions for respiratory diseases in the subequatorial Amazon: a time series approach. Cad Saúde Pública 2010; 26:747-61.
⁶
Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Saldiva PHN, et al. Acute effects of particulate matter and black carbon from seasonal fires on peak expiratory flow of schoolchildren in the Brazilian Amazon. PLoS One 2014; 9:e104177.
⁷
Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Ponce de Leon ACM. Association between fine particulate matter and the peak expiratory flow of schoolchildren in the Brazilian subequatorial Amazon: a panel study. Environ Res 2012; 117:27-35.
⁸
Nunes KVR, Ignotti E, Hacon SS. Circulatory disease mortality rates in the elderly and exposure to PM2.5 generated by biomass burning in the Brazilian Amazon in 2005. Cad Saúde Pública 2013; 29:589-98.
⁹
Butt EW, Conibear L, Knote C, Spracklen DV. Large air quality and public health impacts due to Amazonian deforestation fires in 2019. GeoHealth 2021; 5:e2021GH000429.
¹⁰
Pereira BB, Limongi JE. Epidemiologia de desfechos na saúde humana relacionados à poluição atmosférica no Brasil: uma revisão sistemática. Cad Saúde Colet (Rio J.) 2015; 23:91-100.
¹¹
Santos UP, Arbex MA, Braga ALF, Mizutani RF, Cançado JED, Terra-Filho M, et al. Poluição do ar ambiental: efeitos respiratórios. J Bras Pneumol 2021; 47:e20200267
¹²
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» https://www.ibge.gov.br/estatisticas/sociais/populacao/9103-estimativas-de-populacao.html?=&t=resultados
¹³
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» https://www.hrw.org/pt/report/2020/08/26/376135
¹⁴
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¹⁵
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¹⁶
World Health Organization. WHO global air quality guidelines: particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide. Geneva: World Health Organization; 2021.
¹⁷
Instituto Brasileiro de Geografia e Estatística. Áreas territoriais. https://www.ibge.gov.br/geociencias/organizacao-do-territorio/estrutura-territorial/15761-areas-dos-municipios.html?=&t=acesso-ao-produto (accessed on 17/Dec/2021).
» https://www.ibge.gov.br/geociencias/organizacao-do-territorio/estrutura-territorial/15761-areas-dos-municipios.html?=&t=acesso-ao-produto
¹⁸
Murara P. Técnicas de interpolação para a pesquisa em climatologia regional e agroclimatologia. Revista Brasileira de Climatologia 2019; 15(Edição Especial):106-26.
¹⁹
Mello CR, Lima JM, Silva AM, Mello JM, Oliveira MS. Krigagem e inverso do quadrado da distância para interpolação dos parâmetros da equação de chuvas intensas. Revista Brasileira de Ciência do Solo 2003; 27:925-33.
²⁰
Hengl T. A Practical guide to geostatistical mapping of environmental variables. Luxembourg: Office for Official Publications of the European Communities; 2007.
²¹
Alves NO, Vessoni AT, Quinet A, Fortunato RS, Kajitani GS, Peixoto MS, et al. Biomass burning in the Amazon region causes DNA damage and cell death in human lung cells. Sci Rep 2017; 7:10937.
²²
Silvério D, Silva S, Alencar A, Moutinho P. Amazônia em chamas. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2019. (Nota Técnica, 1).
²³
Alencar A, Moutinho P, Arruda V, Balzani C, Ribeiro J. Amazônia em Chamas: onde está o fogo. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2019. (Nota Técnica, 2).
²⁴
Instituto Nacional de Pesquisas Espaciais. Taxas de desmatamento. http://terrabrasilis.dpi.inpe.br/app/dashboard/deforestation/biomes/legal_amazon/rates (accessed on 19/Sep/2021).
» http://terrabrasilis.dpi.inpe.br/app/dashboard/deforestation/biomes/legal_amazon/rates
²⁵
Instituto Socioambiental. O arco do desmatamento e suas flechas. https://acervo.socioambiental.org/sites/default/files/documents/prov0115.pdf (accessed on 21/Aug/2020).
» https://acervo.socioambiental.org/sites/default/files/documents/prov0115.pdf
²⁶
Moutinho P, Alencar A, Rattis L, Arruda V, Castro I, Artaxo P. Amazônia em chamas: desmatamento e fogo em tempos de Covid-19. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2020. (Nota Técnica, 4).
²⁷
Companhia Ambiental do Estado de São Paulo. Qualoidade do ar no Estado de São Paulo. https://cetesb.sp.gov.br/ar/wp-content/uploads/sites/28/2021/05/Relatorio-de-Qualidade-do-Ar-no-Estado-de-Sao-Paulo-2020.pdf (accessed on 29/May/2022).
» https://cetesb.sp.gov.br/ar/wp-content/uploads/sites/28/2021/05/Relatorio-de-Qualidade-do-Ar-no-Estado-de-Sao-Paulo-2020.pdf
²⁸
Oliveira BFA, Ignotti E, Artarxo P, Saldiva PHN, Junger WL, Hacon S. Risk assessment of PM2.5 to child residents in Brazilian Amazon region with biofuel production. Environ Health 2012; 11:64.
²⁹
Carmo CN, Hacon S, Longo KM, Freitas S, Ignotti E, Ponce de Leon A, et al. Associação entre material particulado de queimadas e doenças respiratórias na região sul da Amazônia brasileira. Rev Panam Salud Pública 2010; 27:10-6.
³⁰
Carmo CN, Alves MB, Hacon SS. Impact of biomass burning and weather conditions on children's health in a city of Western Amazon region. Air Quality Atmosphere & Health 2013; 6:517-25.
³¹
Silva AMC, Mattos IE, Ignotti E, Hacon SS. Material particulado originário de queimadas e doenças respiratórias. Rev Saúde Pública 2013; 47:345-52.
³²
Machin AB, Nascimento LFC. Efeitos da exposição a poluentes do ar na saúde das crianças de Cuiabá, Mato Grosso, Brasil. Cad Saúde Pública 2018; 34:e00006617.
³³
Machin AB, Nascimento LF, Mantovani K, Machin EB. Effects of exposure to fine particulate matter in elderly hospitalizations due to respiratory diseases in the South of the Brazilian Amazon. Braz J Med Biol Res 2019; 52:e8130.
³⁴
Menezes RAM, Pavanitto DR, Nascimento LFC. Exposição a poluentes do ar e doença respiratória em meninos e meninas. Rev Paul Pediatr 2019; 37:166-72.
³⁵
Santana DP, Santos VM, Silva AMC, Shimoya-Bittencourt W. Influence of air pollutants on pneumonia hospitalizations among children in a town in the Brazilian Legal Amazon region: a time series study. São Paulo Med J 2020; 138:126-32.
³⁶
Silva AMC, Moi GP, Mattos IE, Hacon SS. Low birth weight at term and the presence of fine particulate matter and carbon monoxide in the Brazilian Amazon: a population-based retrospective cohort study. BMC Pregnancy Childbirth 2014; 14:309.
³⁷
Observatório do Clima, Instituto de Comunicação e Informação Científica e Tecnológica em Saúde, Fundação Oswaldo Cruz. Covid-19 e queimadas na Amazônia Legal e no Pantanal: aspectos cumulativos e vulnerabilidades. Rio de Janeiro: Fundação Oswaldo Cruz; 2020. (Nota Técnica).
³⁸
Silva AMC, Mattos IE, Freitas SR, Longo KM, Hacon SS. Particulate matter (PM2.5) of biomass burning emissions and respiratory diseases in the South of the Brazilian Amazon. Rev Bras Epidemiol 2010; 13:337-51.
³⁹
Urrutia-Pereira M, Rizzo LV, Chong-Neto HJ, Solé D. Impacto da exposição à fumaça da queima de biomassa na Floresta Amazônica na saúde humana. J Bras Pneumol 2021; 47:e20210219.

Publication Dates

Publication in this collection
28 July 2023
Date of issue
2023

History

Received
15 July 2022
Reviewed
04 Jan 2023
Accepted
30 Mar 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Rede MapBiomas. A cada ano, Brasil queima área maior que a Inglaterra. https://mapbiomas.org/a-cada-ano-brasil-queima-area-maior-que-a-inglaterra (accessed on 12/Oct/2021).
» https://mapbiomas.org/a-cada-ano-brasil-queima-area-maior-que-a-inglaterra

[2] ²
Freitas SR, Longo KM, Silva Dias MAF, Silva Dias PL. Emissões de queimadas em ecossistemas da América do Sul. Estud Av 2005; 19:167-85.

[3] ³
Reddington CL, Butt EW, Ridley DA, Artaxo P, Morgan WT, Coe H, et al. Air quality and human health improvements from reductions in deforestation-related fire in Brazil. Nat Geosci 2015; 8:768-71.

[4] ⁴
Ye T, Guo Y, Chen G, Yue X, Xu R, Coêlho MSZS, et al. Risk and burden of hospital admissions associated with wildfire-related PM2.5 in Brazil, 2000-15: a nationwide time-series study. Lancet Planet Health 2021; 5:e599-607.

[5] ⁵
Ignotti E, Hacon SS, Junger WL, Mourão D, Longo K, Freitas S, et al. Air pollution and hospital admissions for respiratory diseases in the subequatorial Amazon: a time series approach. Cad Saúde Pública 2010; 26:747-61.

[6] ⁶
Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Saldiva PHN, et al. Acute effects of particulate matter and black carbon from seasonal fires on peak expiratory flow of schoolchildren in the Brazilian Amazon. PLoS One 2014; 9:e104177.

[7] ⁷
Jacobson LSV, Hacon SS, Castro HA, Ignotti E, Artaxo P, Ponce de Leon ACM. Association between fine particulate matter and the peak expiratory flow of schoolchildren in the Brazilian subequatorial Amazon: a panel study. Environ Res 2012; 117:27-35.

[8] ⁸
Nunes KVR, Ignotti E, Hacon SS. Circulatory disease mortality rates in the elderly and exposure to PM2.5 generated by biomass burning in the Brazilian Amazon in 2005. Cad Saúde Pública 2013; 29:589-98.

[9] ⁹
Butt EW, Conibear L, Knote C, Spracklen DV. Large air quality and public health impacts due to Amazonian deforestation fires in 2019. GeoHealth 2021; 5:e2021GH000429.

[10] ¹⁰
Pereira BB, Limongi JE. Epidemiologia de desfechos na saúde humana relacionados à poluição atmosférica no Brasil: uma revisão sistemática. Cad Saúde Colet (Rio J.) 2015; 23:91-100.

[11] ¹¹
Santos UP, Arbex MA, Braga ALF, Mizutani RF, Cançado JED, Terra-Filho M, et al. Poluição do ar ambiental: efeitos respiratórios. J Bras Pneumol 2021; 47:e20200267

[12] ¹²
Instituto Brasileiro de Geografia e Estatística. Estimativas de população. https://www.ibge.gov.br/estatisticas/sociais/populacao/9103-estimativas-de-populacao.html?=&t=resultados (accessed on 17/Dec/2021).
» https://www.ibge.gov.br/estatisticas/sociais/populacao/9103-estimativas-de-populacao.html?=&t=resultados

[13] ¹³
Sant'Anna AB, Alencar A, Téllez-Chávez L, Carvalho A, Guimarães A, Moutinho P. O ar é insuportável: os impactos das queimadas associadas ao desmatamento da Amazônia brasileira na saúde. https://www.hrw.org/pt/report/2020/08/26/376135 (accessed on 17/Dez/2021).
» https://www.hrw.org/pt/report/2020/08/26/376135

[14] ¹⁴
Vormittag EMPAA, Cirqueira SSR, Wicher Neto H, Saldiva PHN. Análise do monitoramento da qualidade do ar no Brasil. Estud Av 2021; 35:7-30.

[15] ¹⁵
Ignotti E, Valente JG, Longo KM, Freitas SR, Hacon SDS, Artaxo Netto P. Impact on human health of particulate matter emitted from burnings in the Brazilian Amazon region. Rev Saúde Pública 2010; 44:121-30.

[16] ¹⁶
World Health Organization. WHO global air quality guidelines: particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide. Geneva: World Health Organization; 2021.

[17] ¹⁷
Instituto Brasileiro de Geografia e Estatística. Áreas territoriais. https://www.ibge.gov.br/geociencias/organizacao-do-territorio/estrutura-territorial/15761-areas-dos-municipios.html?=&t=acesso-ao-produto (accessed on 17/Dec/2021).
» https://www.ibge.gov.br/geociencias/organizacao-do-territorio/estrutura-territorial/15761-areas-dos-municipios.html?=&t=acesso-ao-produto

[18] ¹⁸
Murara P. Técnicas de interpolação para a pesquisa em climatologia regional e agroclimatologia. Revista Brasileira de Climatologia 2019; 15(Edição Especial):106-26.

[19] ¹⁹
Mello CR, Lima JM, Silva AM, Mello JM, Oliveira MS. Krigagem e inverso do quadrado da distância para interpolação dos parâmetros da equação de chuvas intensas. Revista Brasileira de Ciência do Solo 2003; 27:925-33.

[20] ²⁰
Hengl T. A Practical guide to geostatistical mapping of environmental variables. Luxembourg: Office for Official Publications of the European Communities; 2007.

[21] ²¹
Alves NO, Vessoni AT, Quinet A, Fortunato RS, Kajitani GS, Peixoto MS, et al. Biomass burning in the Amazon region causes DNA damage and cell death in human lung cells. Sci Rep 2017; 7:10937.

[22] ²²
Silvério D, Silva S, Alencar A, Moutinho P. Amazônia em chamas. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2019. (Nota Técnica, 1).

[23] ²³
Alencar A, Moutinho P, Arruda V, Balzani C, Ribeiro J. Amazônia em Chamas: onde está o fogo. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2019. (Nota Técnica, 2).

[24] ²⁴
Instituto Nacional de Pesquisas Espaciais. Taxas de desmatamento. http://terrabrasilis.dpi.inpe.br/app/dashboard/deforestation/biomes/legal_amazon/rates (accessed on 19/Sep/2021).
» http://terrabrasilis.dpi.inpe.br/app/dashboard/deforestation/biomes/legal_amazon/rates

[25] ²⁵
Instituto Socioambiental. O arco do desmatamento e suas flechas. https://acervo.socioambiental.org/sites/default/files/documents/prov0115.pdf (accessed on 21/Aug/2020).
» https://acervo.socioambiental.org/sites/default/files/documents/prov0115.pdf

[26] ²⁶
Moutinho P, Alencar A, Rattis L, Arruda V, Castro I, Artaxo P. Amazônia em chamas: desmatamento e fogo em tempos de Covid-19. Brasília: Instituto de Pesquisa Ambiental da Amazônia; 2020. (Nota Técnica, 4).

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