Association between the concentration and the elemental composition of outdoor PM2. 5 and respiratory diseases in schoolchildren : a multicenter study in the Mediterranean area

Asthma is a worldwide health problem and its prevalence has been increasing in many countries, especially in young children [1]. Asthma prevalence is particularly high in industrialized countries, even though a change in trend was noticed in the most recent years [2]. Multiple genetic factors increase the risk of developing asthma, whilst environmental conditions play a fundamental role in the expression of its symptoms [3]. In fact, the avoidance of air pollution has been suggested as a nonpharmacological intervention for the prevention of asthma exacerbations in the latest Global Initiative for Asthma (GINA) Guidelines [1]. Exposure to outdoor air pollution increases asthma symptoms, and asthmatic children are at increased risk of adverse effects from poor air quality [4,5]. The World Health Organization (WHO) stated that a high level of outdoor pollutant concentration is a determinant of worsening asthma symptoms in both children and adults [6]. In particular, high airborne particulate matter (PM) concentration has been associated with worsening of symptoms, especially in sensitive children [7], and the prevalence of allergic respiratory diseases is higher in urban areas and still on the rise [8]. Children vulnerability to atmospheric pollution was attributed to their high breath rate and to both physiological and anatomical immaturity [9]. A number of studies have demonstrated an association between respiratory symptoms, the diagnosis of asthma, and proximity of residences to industrial settlements such as oil refineries, petrochemical plants [10–12], and power plants [13,14]. Thus, living in urban environments or in proximity to industrial complexes may worsen respiratory health in children. The aim of the study was to assess the potential role of residing in different areas which had varying levels of pollution on current allergic respiratory diseases in schoolchildren. Thus, by means of a multicenter cross-sectional study, we evaluated children living in areas close to petrochemical and power plants in a southern Mediterranean area, comparing them with those living in rural and urban areas of Sicily and Malta. We used a modified ISAAC (International Study of Asthma and Allergies in Childhood) questionnaire to collect data on individual characteristics and respiratory and allergic symptoms. We also evaluated children exposure to a set of elements measured in outdoor PM with aerodynamic diameter <2.5 µm (PM2.5) through a semi-ecological approach.peer-reviewe

Indoor air quality in schools of a highly polluted south Mediterranean area

This study aimed at surveying lower secondary schools in southern Italy, in a highly polluted area. A community close to an industrial area and three villages in rural areas was investigated. Indoor temperature, relative humidity (RH), gaseous pollutants (CO 2 and NO 2 ), selected biological pollutants in indoor dust, and the indoor/outdoor mass concentration and elemental composition of PM 2.5 were ascertained. Temperature and RH were within, or close to, the comfort range, while CO 2 frequently exceeded the threshold of 1000&nbsp;ppm, indicating inadequate air exchange rate. In all the classrooms, median NO 2 levels were above the WHO threshold value. Dermatophagoides p. allergen concentration was below the sensitizing threshold, while high endotoxin levels were detected in the classrooms, suggesting schools may produce significant risks of endotoxin exposure. Concentration and solubility of PM 2.5 elements were used to identify the sources of indoor particles. Indoor concentration of most elements was higher than outdoors. Resuspension was responsible for the indoor increase in soil components. For elements from industrial emission (Cd, Co, Ni, Pb, Sb, Tl, V), the indoor concentration depended on penetration from the outside. For these elements, differences in rural vs industrial concentrations were found, suggesting industrial sources may influence indoor air quality nearby schools

Indoor air quality in schools of a highly polluted south Mediterranean area

This study aimed at surveying lower secondary schools in southern Italy, in a highly polluted area. A community close to an industrial area and three villages in rural areas was investigated. Indoor temperature, relative humidity (RH), gaseous pollutants (CO 2 and NO 2 ), selected biological pollutants in indoor dust, and the indoor/outdoor mass concentration and elemental composition of PM 2.5 were ascertained. Temperature and RH were within, or close to, the comfort range, while CO 2 frequently exceeded the threshold of 1000&nbsp;ppm, indicating inadequate air exchange rate. In all the classrooms, median NO 2 levels were above the WHO threshold value. Dermatophagoides p. allergen concentration was below the sensitizing threshold, while high endotoxin levels were detected in the classrooms, suggesting schools may produce significant risks of endotoxin exposure. Concentration and solubility of PM 2.5 elements were used to identify the sources of indoor particles. Indoor concentration of most elements was higher than outdoors. Resuspension was responsible for the indoor increase in soil components. For elements from industrial emission (Cd, Co, Ni, Pb, Sb, Tl, V), the indoor concentration depended on penetration from the outside. For these elements, differences in rural vs industrial concentrations were found, suggesting industrial sources may influence indoor air quality nearby schools