Avaliação da poluição atmosférica na área do distrito industrial de Maracanaú (CE), Brasil / Assessment of air pollution in the industrial area of the Maracanau district in Ceara state, Brazil

RESUMO A intensificação das atividades industriais e o aumento das emissões veiculares têm contribuído significantemente para o aumento da poluição atmosférica nos centros urbanos. Neste trabalho, avaliou-se a qualidade do ar na área do distrito industrial de Maracanaú, no estado do Ceará, importante área industrial da Região Nordeste do Brasil. As amostragens foram realizadas durante o período de novembro de 2015 a abril de 2016, totalizando 30 coletas com duração de 24 h cada. Realizaram-se coletas para poluentes, como o material particulado total (PTS) e inalável (MP10), NO2, SO2, O3 e metais pesados (Sb, Cd, Pb, Cu, Fe, Mn, Ni e Zn) associados ao PTS e ao MP10. O O3 foi determinado por absorção no ultravioleta (254 nm), e estimaram-se as concentrações dos metais por espectroscopia de absorção atômica. Os valores médios observados para os poluentes foram de: 51,3 µg/m3 de PTS; 46,1 µg/m3 de MP10; 8,9 µg/m3 de SO2; 8,3 µg/m3 de NO2; 38,5 µg/m3 para O3 em 8 horas e 48,4 µg/m3 para O3 em 1 hora. Para os metais, o Fe (14,9 µg/m3) foi o mais abundante em ambos os particulados. Todos os parâmetros encontram-se em conformidade com os valores estabelecidos pela legislação brasileira, e somente o MP10 apresentou em 16,7% das amostras concentrações acima (média de 74,5 µg/m3) do recomendado pela Organização Mundial da Saúde. Em geral, a qualidade do ar na área industrial em estudo pode ser considerada boa, segundo os valores de índice de qualidade do ar (IQAr) recomendado pela agência de proteção ambiental americana.

ABSTRACT The intensification of industrial activities and the increase in vehicular emissions have contributed significantly to the increase in atmospheric pollution in urban centers. In this context, the present study aimed to monitor the air quality in the area of Maracanaú Industrial District, in the state of Ceará, an important industrial area in northeastern region of Brazil. Samples were collected during 24 h from November 2015 to April 2016 for pollutants such as total suspended (TSP) and inhalable particle materials (PM10), NO2, SO2, O3 and heavy metals (Sb, Cd, Pb, Cu, Fe, Mn, Ni, and Zn) associated with TSP and PM10. Ozone (O3) was determined by ultraviolet absorption (254 nm) and the concentration of heavy metals were estimated by atomic absorption spectroscopy. The mean values observed for the pollutant concentrations were: 51.3 μg/m3 for TSP; 46.1 μg/m3 for PM10; 8.9 μg/m3 for SO2; 8.3 μg/m3 for NO2; 38.5 μg/m3 for O3 in 8 hours and 48.4 μg/m3 for O3 in 1 hour. Among metals, Fe (14.9 µg/m3) was the most abundant species in both particulates. All the parameters analyzed are in accordance with the values established by the Brazilian legislation and only PM10 are above the recommended by the World Health Organization in 16.7 % of the samples (mean 74.5 μg/m3). In general, the air quality in the industrial area under study can be considered good, according to the estimates of the air quality index (AQI) recommended by the US Environmental Protection Agency.

Lung injury caused by exposure to the gaseous fraction of exhaust from biomass combustion (cashew nut shells): a mice model.

Currently, to reduce the use of nonrenewable energy sources in energy matrices, some industries have already incorporated biomass as a source of energy for their processes. Additionally, filters are used in an attempt to retain the particulate matter present in exhaust gases. In this work, the emission gases of a cashew nut shell (CNS) combustion reactor and the deleterious effects on the respiratory system of mice exposed to gaseous fraction present in CNS emissions (GF-CNS) are analyzed. The system for CNS combustion is composed of a cylindrical stainless steel burner, and exhaust gases generated by CNS combustion were directed through a chimney to a system containing two glass fiber filters to retain all the PM present in the CNS exhaust and, posteriorly, were directed to a mice exposure chamber. The results show changes in the variables of respiratory system mechanics (G, H, CST, IC, and PV loop area) in oxidative stress (SOD, CAT, and NO2-), as well as in the histopathological analysis and lung morphometry (alveolar collapse, PMN cells, mean alveolar diameter, and BCI). Through our results, it has been demonstrated that even with the use of filters by industries for particulate material retention, special attention should still be given to the gaseous fraction that is released into the environment.