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Lung Function Growth in Children with Long-Term Exposure to Air Pollutants in Mexico City

¹ Instituto Nacional de Salud Publica, Cuernavaca, Mexico; ² Instituto Nacional de Enfermedades Respiratorias, Mexico City, Mexico; ³ Universidad Autónoma Metropolitana, Mexico City, Mexico; ⁴ Medical School, UNAM, Mexico City, Mexico; and ⁵ School of Public Health, University of North Carolina, Chapel Hill, North Carolina

Correspondence and requests for reprints should be addressed to Isabelle Romieu, M.D., M.P.H., Sc.D., Instituto Nacional de Salud Publica, 655 Avenida Universidad, Col. Santa Maria Ahuacatitlán, Cuernavaca, Morelos 62508, México. E-mail: iromieu{at}correo.insp.mx

	ABSTRACT

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Rationale: Although short-term exposure to air pollution has been associated with acute, reversible lung function decrements, the impact of long-term exposure has not been well established.

Objectives: To evaluate the association between long-term exposure to ozone (O₃), particulate matter less than 10 µm in diameter (PM₁₀), and nitrogen dioxide (NO₂) and lung function growth in Mexico City schoolchildren.

Methods: A dynamic cohort of 3,170 children aged 8 years at baseline was followed from April 23, 1996, through May 19, 1999. The children attended 39 randomly selected elementary schools located near 10 air quality monitoring stations and were visited every 6 months. Statistical analyses were performed using general linear mixed models.

Measurements and Main Results: After adjusting for acute exposure and other potential confounding factors, deficits in FVC and FEV₁ growth over the 3-year follow-up period were significantly associated with exposure to O₃, PM₁₀, and NO₂. In multipollutant models, an interquartile range (IQR) increase in mean O₃ concentration (IQR, 11.3 ppb) was associated with an annual deficit in FEV₁ of 12 ml in girls and 4 ml in boys, an IQR range (IQR, 36.4 µg/m³) increase in PM₁₀ with an annual deficit in FEV₁ of 11 ml in girls and 15 ml in boys, and an IQR range (IQR, 12.0 ppb) increase in NO₂ with an annual deficit in FEV₁ of 30 ml in girls and 25 ml in boys.

Conclusions: We conclude that long-term exposure to O₃, PM₁₀, and NO₂ is associated with a deficit in FVC and FEV₁ growth among schoolchildren living in Mexico City.

Key Words: lung function growth • air pollution • children

AT A GLANCE COMMENTARY TOP ABSTRACT AT A GLANCE COMMENTARY METHODS RESULTS DISCUSSION REFERENCES   Scientific Knowledge on the Subject Epidemiologic studies addressing the effects of long-term exposure to air pollutants on lung function growth in children are not conclusive. What This Study Adds to the Field Long-term exposure to air pollutants is associated with a significant deficit in lung function growth in children.

 
Epidemiologic studies have shown that acute exposure to ambient air pollution is associated with a range of respiratory events in children (1–3). Although there is growing evidence that air pollution exposure is likely to affect lung growth (4–10), there is controversy on which pollutant is most harmful to health. Long-term exposure to ozone (O₃) has been associated with significantly decreased lung function in retrospective and prospective cohorts of children (6, 11) and young adults (4, 5), and the Children's Health Study (CHS) (7–9) has reported that nitrogen dioxide (NO₂), acid vapor, and elemental carbon had the strongest effect.

The metropolitan area of Mexico City experiences significant air pollution problems. O₃ levels are high, and the average 1-hour daily maximum frequently exceeds 110 ppb (the Mexican standard) (12). Studies conducted among children with asthma who live in Mexico City have shown a decrement in lung functions and an increase in respiratory symptoms (13–16), suggesting that children with lifelong exposure to a heavily polluted environment, mainly to ozone pollution, have detectable abnormalities that could be indicative of small airway disease or decreased total lung capacity.

We conducted a prospective dynamic cohort study to evaluate the long-term effect of ambient air pollution on the lung function growth of Mexico City schoolchildren. Some of the results of this study have been previously reported in the form of abstracts (17, 18).

	METHODS

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Study Design
We selected 10 fixed-site air monitoring stations in Mexico City and randomly selected 39 elementary schools from among those located within 2 km of the stations. The study cohort consisted of students of the selected schools who were 8 years of age at the beginning of the study, who had not been diagnosed as having asthma, and whose parents had signed a consent letter. A substantial number of children entered or left the cohort during the course of the study. At baseline, a questionnaire was completed by the parents of 1,819 children, and a spirometric test was administered to each child (phase 1). An additional 1,351 participants of the same age (±1 mo) as the previously enrolled children were added to the cohort in subsequent phases. The cohort was followed every 6 months (spring and fall) for 3 years with spirometric tests and two questionnaires, one completed by the parents and the other by the children and their teachers. Lung function testing was conducted by trained technicians following American Thoracic Society standards (19), using computerized dry rolling-seal spirometers (model 922; SensorMedics, Yorba Linda, CA). The spirometry quality control program has been previously reported (20).

Air Pollution Monitoring
We obtained measurements of NO₂, SO₂, particulate matter with a mass median diameter of less than 10 µm (PM₁₀), ambient O₃ and weather variables (relative humidity and minimum, maximum, and daily average temperature) from 10 government air monitoring stations. We calculated 8-hour means (between 10 A.M. and 6 P.M.) for O₃ and 24-hour means for PM₁₀ and NO₂ for each day for which hourly data were available for more than 75% of the time. The selected schools were located within 2 km of 10 fixed-site monitoring stations. Children's exposure assessment was based on data from the station closest to their school. Five monitoring stations (Plateros, Hangares, Taxqueña, Lagunilla, and San Agustín) were not equipped with a TEOM and therefore could not be used to assign PM₁₀ exposure. The PM₁₀ exposure of children attending the schools concerned was based on data from the nearest station measuring PM₁₀ (Pedregal, Merced, Cerro de la Estrella, Merced, and Tlalnepantla). The maximum distance between these schools and the PM₁₀ monitoring stations was 6 km.

Long-term exposure for each day of the study period was estimated as the averages over the previous 6 months of the daily O₃ 8-hour mean, PM₁₀ 24-hour means, and NO₂ 24-hour means averaged over the previous 6 months. These averages vary depending on the station assigned to each school. Only low concentrations of SO₂ and CO were registered, so their effects were not analyzed.

Statistical Analysis
General linear mixed models were used to evaluate the association between air pollutant concentrations and deficits in lung function growth over time. The outcome variables were the spirometric parameters FVC; FEV₁; forced expiratory flow, midexpiratory phase (FEF_25–75%); and FEV₁/FVC from a total of 14,545 test results for 3,170 children. A three-level model was used to distinguish the sources of variation in the response: a first level to identify the variation between phases within children nested within monitoring stations, a second level to identify the variation between subjects within monitoring stations, and a third level to identify the variation between monitoring station variables. We fitted sex-specific models because of the presence of a statistically significant interaction term between time (study phase) and sex (p < 0.001). Annual lung function growth was defined as the slope obtained from mixed models given by the coefficient of the interaction term of time with air pollutant concentrations, specifying the variance-covariance matrix as unstructured with random intercept and slope. Our final model included the following variables (based on Akaike's information criteria from the model): time since first test; O₃ averaged over 6 months (O₃-6); previous-day O₃; PM₁₀ averaged over 6 months (PM₁₀-6); previous-day PM₁₀; NO₂ averaged over 6 months (NO₂-6); previous-day NO₂; interaction terms of study phase with O₃-6, PM₁₀-6, and NO₂-6; age; body mass index; height; height by age; weekday time spent in outdoor activities; and environmental tobacco smoke. Longitudinal analysis was performed using the PROC MIXED procedure of SAS 8.2 (SAS Institute, Inc., Cary, NC) (for further details of methods used, see the online supplement).

	RESULTS

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Table 1 and Table E1 in the online supplement present the characteristics of the study population (n = 3,170) by study phase and sex. Anthropometric measurements and lung function variables increased over time for both sexes. Figure 1 presents the location of the monitoring stations used in the study. Air pollutant concentrations over the 3-year study period were higher in spring than in fall (Table E2). Over the study period, 8-hour mean O₃ concentrations ranged from 60 ppb (SD, 25) in the northeast area to 90 ppb (SD, 34) in the southwest, and 24-hour mean PM₁₀ concentrations ranged from 53 µg/m³ (SD, 32) in the southwest to 97 µg/m³ (SD, 49) in the northeast (Table 2). O₃ was negatively associated with PM₁₀ (r = –0.23; p < 0.001) and positively associated with NO₂ (r = 0.166; p < 0.001).

View larger version (41K): [in this window] [in a new window]   Figure 1. Air monitoring stations in Mexico City. CE = central; CES = Cerro de la Estrella; HAN = Hangares; LAG = Lagunilla; MER = Merced; NE = northeast; NW = northwest; PED = Pedregal; PLA = Plateros; SAG = San Agustín; SE = southeast; SW = southwest; TAX = Taxqueña; TLA, Tlalnepantla; XAL = Xalostoc.

View larger version (49K): [in this window] [in a new window]   Figure 2. Estimated annual growth in (A) FVC; (B) FEV1; (C) forced expiratory flow, midexpiratory phase (FEF25–75%) of long-term ozone; particulate matter less than 10 µm in diameter (PM10), and nitrogen dioxide (NO2) in girls and boys. Mexico City, 1996–1999 (multipollutant models). Adjusted for age, body mass index, height, height by age, weekday time spent in outdoor activities, environmental tobacco smoke exposure, previous-day mean air pollutant concentration, and study phase. Percentiles 25, 50, 75 of ozone (O3), PM10, and NO2 correspond to 6-month mean concentrations of 64.3, 69.3, and 75.7 ppb; 56.42, 67.63, and 92.22 µg/m3; and 28.92, 34.57, and 40.85 ppb, respectively.

	DISCUSSION

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Our study revealed significant deficits in lung function growth in children with long-term exposure to air pollutants. In one-pollutant models, O₃, PM₁₀, and NO₂ were associated with a significant deficit in FVC and FEV₁ growth in girls and boys. The FEV₁/FVC ratio increased because exposure had a greater impact on FVC than on FEV₁. An association between O₃ and a deficit in FEF_25–75% growth was observed only among girls with a low FEF_25–75%/FVC ratio. The effect on FEV₁ during the 3 years of follow-up was slightly greater than that reported for exposure to maternal smoking among children in the United States (22, 23).

A deficit in FVC and FEV₁ growth was observed for O₃, PM₁₀, and NO₂ after adjusting for the acute effect of these pollutants (previous-day concentrations) and for confounding factors. In multipollutant models, O₃ and NO₂ had the strongest effect among girls. These results are in part consistent with previous results from the CHS, which revealed a deficit in growth mostly with exposure to PM_2.5, NO₂, and inorganic acid vapor (7, 9, 15). In the CHS, O₃ exposure was associated with a growth deficit in peak expiratory flow rate in fourth graders followed for only 4 of the 8 years of follow-up (8, 22). Lower lung functions in children exposed to higher O₃ concentrations have been reported in cross-sectional studies (24), including one based on CHS data that observed lower peak expiratory flow rate and maximal midexpiratory flow particularly in girls spending more time outdoors (25) and in retrospective (11) and prospective (6) cohort studies. Deficit in lung growth was associated with a set of pollutants including O₃, PM₁₀, and NO₂. Their main source, particularly that of NO₂ and O₃, is traffic related: The former is directly emitted from tailpipes, and the latter is a photochemical reaction to exhaust gases (26). Because the pollutants are correlated, independent effects could not be accurately estimated.

The mechanism of action by which long-term exposure to air pollution produces changes in lung development has not been established. Human and animal studies have demonstrated several changes in lung morphology related to O₃ exposure (27–29), particularly with a predominantly restrictive pattern (30). Calderon and colleagues (16) have suggested that chronic and sustained inhalation of a complex mixture of air pollutants, including O₃ and PM, might be associated with small airway disease. Recently, oxidative stress resulting from increased exposure to oxidant compounds (O₃, NO₂, and particulate components) has been identified as a major feature underlying the toxic effects of air pollutants (31–33). The resulting increased expression of proinflammatory cytokines leads to an enhanced inflammatory response (32) and potential chronic lung damage. It is not clear whether this might result in permanent loss or whether the pattern of exposure (repeated peak exposure versus average exposure) is relevant. Because of the shortness of the 3-year follow-up period and the nonlinear pattern of childhood lung function growth (34), we were unable to estimate the impact on lung function attained in early adulthood.

In our study, exposure to pollutants was associated with a higher FEV₁/FVC ratio, suggesting a restrictive pattern similar to that already described in animals (30) and humans (35). However, the effect of air pollution on the resulting functional pattern has been inconsistent (36, 37), and inflammatory changes in small airways have been observed (11).

Several factors need to be considered when interpreting our results. The exposure values used in studies on the long-term effects of air pollution on lung function growth are usually fixed-site monitoring station data that have been averaged over communities. To reduce exposure misclassification, our study was based on schools located within 2 km of the monitoring stations. In addition, we conducted microenvironmental and personal exposure assessments in a randomly selected subsample of 60 children, using passive O₃ samplers and personal PM₁₀ monitors. PM₁₀ and O₃ concentrations from personal, indoor, and outdoor monitors were significantly correlated with the measurements obtained from the fixed-site air monitoring stations (38). Our results were not substantially modified when we adjusted our models for potential confounding factors. However, we did not have information on variables such as smoking during pregnancy, birth weight, and atopy, which have been associated with reduced lung function growth (39, 40). Because socioeconomic status might have a differential distribution across monitoring stations and pollution concentrations and might be a determinant of lung function in our population, we tested for interactions between maternal and paternal education levels and air pollutant effects. None of these interactions was significant, suggesting that socioeconomic status could not explain our results.

Lung function testing was conducted by trained technicians, and all spirometry test results were reviewed by a pulmonologist blinded to the location of the school attended by the child. The reproducibility of the tests was good and has been previously reported (20). In the event of missing lung function data, if the data were missing in one phase but not in the next the rate of change could be imputed from the mixed model because the coefficients obtained from the mixed model analysis estimated mean effects.

Conclusions
The results of this 3-year study support the hypothesis that long-term exposure to ambient air pollutants is associated with deficits in lung growth in children. Although we could not identify specific sources, the effect is likely to be due to vehicular exhaust, as observed in the CHS (9). Although it is unclear whether the deficits are permanent, previous studies have reported long-term deficits in lung function associated with air pollutants (9, 11). In addition to the important impact on lung health, early lung function deficits may increase the risk of developing chronic obstructive lung disease later in life as well as increased cardiovascular morbidity and general mortality (41, 42). There is a clear need for stricter air pollution control measures in Mexico City to protect lung growth in children living there.

	Acknowledgments

 
The authors thank Steve Marshall, Kiros Berhane, James Gauderman, Nino Kuenzli, and Rob McConnell for their important input on this study; the Mexico City monitoring network (RAMA) and the field team for providing high-quality data; and the school principals, teachers, students and parents for their participation. They also thank Garth Evans for reviewing the English manuscript.

	FOOTNOTES

 
Supported by the Mexican Sciences and Technology Council (CONACYT), SALUD-2005-01-13956 and by the National Center for Environmental Health–Centers for Disease Control and Prevention, Atlanta, GA.

This article has an online supplement, which is accessible from this issue's table of contents at www.atsjournals.org

Originally Published in Press as DOI: 10.1164/rccm.200510-1678OC on April 19, 2007

Conflict of Interest Statement: R.R.-M. does not have a financial relationship with a commercial entity that has an interest in the subject of this manuscript. R.P.-P. does not have a financial relationship with a commercial entity that has an interest in the subject of this manuscript. G.O.-F. does not have a financial relationship with a commercial entity that has an interest in the subject of this manuscript. L.M.-A. does not have a financial relationship with a commercial entity that has an interest in the subject of this manuscript. H.M-M. does not have a financial relationship with a commercial entity that has an interest in the subject of this manuscript. T.F. does not have a financial relationship with a commercial entity that has an interest in the subject of this manuscript. W.M. received $21,000 from API in 2006 as a contract to develop and publish ozone exposure-response models. D.L. does not have a financial relationship with a commercial entity that has an interest in the subject of this manuscript. I.R. does not have a financial relationship with a commercial entity that has an interest in the subject of this manuscript.

Received in original form October 27, 2005; accepted in final form April 19, 2007

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