Your search keyword '"Cibella, F."' showing total 5 results

1. PM2.5 elemental composition in indoor residential environments and co-exposure effects on respiratory health in an industrial area

Author

Canepari, S., primary, Astolfi, M.L., additional, Drago, G., additional, Ruggieri, S., additional, Tavormina, E.E., additional, Cibella, F., additional, and Perrino, C., additional

Published

2023

2. PM 2.5 elemental composition in indoor residential environments and co-exposure effects on respiratory health in an industrial area.

Author

Canepari S, Astolfi ML, Drago G, Ruggieri S, Tavormina EE, Cibella F, and Perrino C

Subjects

Dust analysis, Environmental Monitoring, Particle Size, Particulate Matter analysis, Sicily, Air Pollutants analysis, Air Pollution, Indoor analysis

Abstract

This study aimed to identify and characterise indoor sources of particulate matter (PM) in domestic environments. 74 inhabited apartments located in the urban area of Gela (Sicily, Italy), close to a refinery, and in three villages of the hinterland were evaluated, in real-world conditions, for the elemental composition of PM 2.5 . The samples were collected simultaneously inside and outside each apartment for 48 h. In addition, two of the apartments were simultaneously studied for four weeks. The elemental composition of PM 2.5 was determined by applying a chemical fractionation procedure followed by inductively-coupled plasma spectrometry analysis, with both optical emission and mass detection. The extractable, more bio-accessible fraction ( ext ), and the mineralised residual fraction ( res ) of each element were determined, thus increasing the selectivity of elements as source tracers. Indoor air in the considered apartments was affected by both outdoor pollution and specific indoor emission sources. The behaviour of each source was studied in detail, identifying a reliable tracer: Ti res for soil, As ext for industrial sources, V ext for heavy oil combustion, Ce for cigarette smoking and Mo for the use of vacuum dust cleaners. As ext and V ext showed an excellent infiltration capacity, while the concentration of Ti res was affected by a low infiltration capacity and by the contribution of particles re-suspension caused by the residents' movements. In the case of Ce and Mo, indoor concentrations were much higher than outdoor with a high variability among the apartments, due to the inhabitants' habits concerning cigarette smoke and use of electric appliances. To test the overall effect of the concomitant exposure to the identified sources on Wh12 M and on DDA, a WQS analysis was conducted. Cigarette smoking and heavily oil combustion driven the Wh12 M odds increase, while the DDA odds increase was mainly driven by heavily oil combustion and the use of vacuum dust cleaners., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022. Published by Elsevier Inc.)

Published

2023

3. Exposure to ambient air pollution in the first 1000 days of life and alterations in the DNA methylome and telomere length in children: A systematic review.

Author

Isaevska E, Moccia C, Asta F, Cibella F, Gagliardi L, Ronfani L, Rusconi F, Stazi MA, and Richiardi L

Subjects

Child, Epigenome, Female, Humans, Infant, Newborn, Maternal Exposure adverse effects, Particulate Matter analysis, Pregnancy, Telomere genetics, Air Pollutants analysis, Air Pollutants toxicity, Air Pollution adverse effects, Air Pollution analysis

Abstract

Background: Exposure to air pollution during the first 1000 days of life (from conception to the 2nd year of life) might be of particular relevance for long-term child health. Changes in molecular markers such as DNA methylation and telomere length could underlie the association between air pollution exposure and pollution-related diseases as well as serve as biomarkers for past exposure. The objective of this systematic review was to assess the association between air pollution exposure during pregnancy and the first two years of life and changes in DNA methylation or telomere length in children., Methods: PubMed was searched in October 2020 by using terms relative to ambient air pollution exposure, DNA methylation, telomere length and the population of interest: mother/child dyads and children. Screening and selection of the articles was completed independently by two reviewers. Thirty-two articles matched our criteria. The majority of the articles focused on gestational air pollution exposure and measured DNA methylation/telomere length in newborn cord blood or placental tissue, to study global, candidate-gene or epigenome-wide methylation patterns and/or telomere length. The number of studies in children was limited., Results: Ambient air pollution exposure during pregnancy was associated with global loss of methylation in newborn cord blood and placenta, indicating the beginning of the pregnancy as a potential period of susceptibility. Candidate gene and epigenome-wide association studies provided evidence that gestational exposure to air pollutants can lead to locus-specific changes in methylation, in newborn cord blood and placenta, particularly in genes involved in cellular responses to oxidative stress, mitochondrial function, inflammation, growth and early life development. Telomere length shortening in newborns and children was seen in relation to gestational pollutant exposure., Conclusions: Ambient air pollution during pregnancy is associated with changes in both global and locus-specific DNA methylation and with telomere length shortening. Future studies need to test the robustness of the association across different populations, to explore potential windows of vulnerability and assess the role of the methylation and telomere length as mediators in the association between early exposure to ambient air pollutants and specific childhood health outcomes., (Copyright © 2020. Published by Elsevier Inc.)

Published

2021

4. Relationship between domestic smoking and metals and rare earth elements concentration in indoor PM 2.5 .

Author

Drago G, Perrino C, Canepari S, Ruggieri S, L'Abbate L, Longo V, Colombo P, Frasca D, Balzan M, Cuttitta G, Scaccianoce G, Piva G, Bucchieri S, Melis M, Viegi G, Cibella F, Balzan M, Bilocca D, Borg C, Montefort S, Zammit C, Bucchieri S, Cibella F, Colombo P, Cuttitta G, Drago G, Ferrante G, L'Abbate L, Grutta S, Longo V, Melis MR, Ruggieri S, Viegi G, Minardi R, Piva G, Ristagno R, Rizzo G, and Scaccianoce G

Subjects

Adolescent, Air Pollution, Indoor statistics & numerical data, Child, Humans, Italy, Metals chemistry, Air Pollutants chemistry, Housing statistics & numerical data, Metals, Rare Earth chemistry, Particulate Matter chemistry, Smoking

Abstract

Cigarette smoke is the main source of indoor chemical and toxic elements. Cadmium (Cd), Thallium (Tl), Lead (Pb) and Antimony (Sb) are important contributors to smoke-related health risks. Data on the association between Rare Earth Elements (REE) Cerium (Ce) and Lanthanum (La) and domestic smoking are scanty. To evaluate the relationship between cigarette smoke, indoor levels of PM 2.5 and heavy metals, 73 children were investigated by parental questionnaire and skin prick tests. The houses of residence of 41 "cases" and 32 "controls" (children with and without respiratory symptoms, respectively) were evaluated by 48-h PM 2.5 indoor/outdoor monitoring. PM 2.5 mass concentration was determined by gravimetry; the extracted and mineralized fractions of elements (As, Cd, Ce, La, Mn, Pb, Sb, Sr, Tl) were evaluated by ICP-MS. PM 2.5 and Ce, La, Cd, and Tl indoor concentrations were higher in smoker dwellings. When corrected for confounding factors, PM 2.5 , Ce, La, Cd, and Tl were associated with more likely presence of respiratory symptoms in adolescents. We found that: i) indoor smoking is associated with increased levels of PM 2.5 , Ce, La, Cd, and Tl and ii) the latter with increased presence of respiratory symptoms in children., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

5. Effect of indoor nitrogen dioxide on lung function in urban environment.

Author

Cibella F, Cuttitta G, Della Maggiore R, Ruggieri S, Panunzi S, De Gaetano A, Bucchieri S, Drago G, Melis MR, La Grutta S, and Viegi G

Subjects

Adolescent, Child, Cities, Cross-Sectional Studies, Environment, Environmental Monitoring, Female, Humans, Italy, Male, Respiratory Function Tests, Respiratory Tract Diseases chemically induced, Seasons, Socioeconomic Factors, Air Pollutants toxicity, Air Pollution, Indoor, Environmental Exposure, Lung drug effects, Lung physiopathology, Nitrogen Dioxide toxicity, Respiratory Tract Diseases physiopathology

Abstract

Background: High levels of indoor NO2 are associated with increased asthma symptoms and decreased expiratory peak flows in children. We investigated the association of exposure to domestic indoor NO2, objectively measured in winter and spring, with respiratory symptoms and lung function in a sample of adolescents from a southern Mediterranean area., Methods: From a large school population sample (n=2150) participating in an epidemiological survey in the urban area of the City of Palermo (southern Italy), a sub-sample of 303 adolescents was selected which furnished an enriched sample for cases of current asthma. All subjects were evaluated by a health questionnaire, skin prick tests and spirometry. One-week indoor NO2 monitoring of their homes was performed by diffusive sampling during spring and again during winter., Results: We found that about 25% of subjects were exposed to indoor NO2 levels higher than the 40µg/m(3) World Health Organization limit, during both spring and winter. Moreover, subjects exposed to the highest indoor NO2 concentrations had increased frequency of current asthma (p=0.005), wheeze episodes in the last 12 months (p<0.001), chronic phlegm (p=0.013), and rhinoconjunctivitis (p=0.008). Finally, subjects with a personal history of wheeze ever had poorer respiratory function (FEF25-75%, p=0.01) when exposed to higher indoor NO2 concentrations., Conclusions: Home exposure to high indoor NO2 levels frequently occurs in adolescents living in a southern Mediterranean urban area and is significantly associated with the risks for increased frequency of both respiratory symptoms and reduced lung function., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015