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Repeated Exposure to Ozone Increases Alveolar Macrophage Recruitment into Asthmatic Airways

Lung Biology Center, Department of Medicine, University of California, San Francisco; and Division of Environmental Health Sciences, School of Public Health, University of California, Berkeley, California

Correspondence and requests for reprints should be addressed to John R. Balmes, M.D., University of California–San Francisco, Box 0843, San Francisco, CA 94143-0843. E-mail: jbalmes{at}itsa.ucsf.edu

	ABSTRACT

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Rationale: Repeated, short-term exposures to ozone (O₃) lead to attenuation of the acute lung function and airway inflammatory responses seen after a single exposure in healthy subjects, but it is unclear whether these acute responses also attenuate in subjects with asthma. Objective: To address this question by exposing 14 subjects with asthma to 0.2 ppm O₃ for either 4 hours on a single day or 4 hours on 4 consecutive days (multiday [MD]). At least 3 weeks later, subjects underwent the alternate exposure. Methods: Spirometry was performed immediately pre- and postexposure and bronchoalveolar lavage (BAL) was obtained 18 hours after each exposure. Main Results: The decrease in FEV₁ was greatest across Day 2 of the MD (MD2) exposure and then gradually declined on successive days of the MD exposure (mean ± SD decrease in FEV₁ of 25.4 ± 18.0% across MD2 compared with 4.2 ± 6.5% across MD4). Respiratory symptoms followed a similar pattern to that of FEV₁. Although the concentration of neutrophils in BAL after the MD4 exposure was not significantly different from that after the single-day exposure (1.7 ± 1.3 x 10⁴ cells/ml vs. 1.2 ± 0.8 x 10⁴ cells/ml, p = 0.20), the concentration of alveolar macrophages did significantly increase in BAL after the MD exposure (19.9 ± 9.7 x 10⁴ cells/ml after MD4 vs. 12.1 ± 6.4 x 10⁴ cells/ml after the single day). Conclusions: Alveolar macrophages are recruited to the airways of subjects with asthma with repeated short-term exposures to O₃, suggesting a possible role for these cells in the chronic response to oxidant-induced injury.

Key Words: airway inflammation • alveolar macrophage • asthma • multiday exposure • ozone

Ozone (O₃), a highly reactive oxidizing agent, is a major component of urban air pollution worldwide. Multiple controlled human exposure studies have documented that short-term inhalation of O₃ causes dose-dependent decrements in lung function (1–4) as well as injury and inflammation in both proximal airways and distal lung (5–8). Repeated, daily short-term exposures to O₃ lead to attenuation of both acute lung function responses and bronchoalveolar lavage (BAL) neutrophilia in healthy persons without asthma (9–12). However, the results of several studies have also suggested that there is a lack of attenuation of airway injury and neutrophilic infiltration of bronchial mucosa with repeated, short-term exposures (11, 12).

Subjects with asthma may be at higher risk of experiencing adverse effects after O₃ exposure than healthy subjects without asthma because of underlying airway inflammation and airway hyperresponsiveness (13–15). Given that persons with asthma constitute a large, potentially vulnerable subpopulation, assessing their responses to O₃ is highly relevant to our biological understanding of the effects of inhaled oxidants and from a public health policy perspective. The results of several epidemiologic studies indicate that high-ambient O₃ concentrations are associated with increased rates of asthma attacks, emergency room visits, and hospital admissions for asthma exacerbation (16–19). In addition, several controlled exposure studies have shown that, although subjects with mild asthma had similar lung function changes after short-term O₃ exposure to those of healthy subjects without asthma, they had greater airway inflammatory responses (20–23). Thus, it appears that subjects with asthma constitute a susceptible subgroup at risk for both O₃-induced exacerbations and enhanced airway inflammatory responses.

To our knowledge, however, there are no data on whether O₃-induced acute inflammatory responses in subjects with asthma persist or attenuate with repeated exposures similar to healthy subjects without asthma. This is a key issue given the potential for chronic lung injury and tissue remodeling from repeated episodes of acute inflammation. Our study was designed to test the hypothesis that repeated daily exposures to O₃ cause a progression of airway inflammation in subjects with asthma. Some of the results of this study have been previously reported in the form of an abstract (24).

	METHODS

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Study Design
This study had a crossover design. Subjects with mild asthma were exposed to 0.2 ppm O₃ for either 4 hours on a single day (1-D) or 4 hours on 4 consecutive days (multiday [MD] exposure) followed by bronchoscopy 18 hours later. At least 3 weeks later, to allow recovery from any inflammation or injury caused by the first exposure and bronchoscopy, subjects underwent the alternate exposure (either 1-D or MD exposure to 0.2 ppm O₃), again followed by bronchoscopy. The order of exposures within the group was counterbalanced and randomized to the extent possible.

Subjects
Subjects were initially recruited for this study by public advertisements. Inclusion criteria were as follows: self-report of physician-diagnosed asthma, airway hyperresponsiveness to inhaled methacholine (provocative concentration of methacholine resulting in a 20% decrease in FEV₁ compared with baseline [PC₂₀] 8.0 mg/ml) verified in our laboratory according to a standard protocol (25), and ability to perform moderately strenuous exercise. All subjects were nonsmokers who denied any history of cardiac or pulmonary diseases other than asthma or any respiratory infections within 6 weeks of the onset of each exposure. In addition, all subjects were atopic, although atopy was not an inclusion criterion in our study. They were required to be off oral steroid medications for at least 3 months and inhaled steroids for at least 2 weeks before all sessions. No other medications were withheld. No subject used supplemental vitamin C or E during the study. The subjects were informed of the risks of the experimental protocol and signed a consent form approved by the Committee on Human Research of the University of California, San Francisco. All of the subjects received financial compensation for their participation. Fourteen subjects completed the experimental protocol. Characteristics of individual study participants are listed in Table 1.

On exposure days, each subject's spirometry and peak expiratory flow were measured immediately before and after each exposure. Spirometry was performed on a dry rolling-seal spirometer. The best values for FVC and FEV₁ were used from three acceptable FVC maneuvers (26) obtained approximately 30 seconds apart. The subjects exercised for the first 30 minutes of each hour and then rested for the remaining 30 minutes of the hour. The exercise consisted of either walking/running on a treadmill or pedaling a cycle ergometer. The exercise intensity was adjusted for each subject to achieve the targeted E. During exercise, E was calculated from VT and breathing frequency, measured using a pneumotachograph, at the 10- and 20-minute intervals of each 30-minute exercise period. Peak expiratory flow was measured 10 minutes into each 30-minute rest period to monitor for possible bronchoconstriction. Subjects remained inside the chamber for the entire 4-hour exposure period.

Exposure Chamber and Atmospheric Monitoring
All exposures took place in a chamber ventilated with filtered air at 20°C and 50% relative humidity, to which O₃ was added. The stainless steel and glass chamber, 2.5 x 2.5 x 2.4 m, was custom-built and designed to maintain chamber temperature and relative humidity within 2.0°C and 4%, respectively, of the set points (5). Relative humidity and temperature were recorded every 30 seconds and averaged over each exposure.

O₃ was produced using a corona-discharge O₃ generator (Model T408; Polymetrics, Inc., San Jose, CA) and its concentration was monitored every 30 seconds with an ultraviolet light photometer (Model 1004AH; Dasibi, Glendale, CA). The O₃ analyzer was calibrated with an O₃ transfer standard by the California Air Resources Board.

Respiratory Symptoms
A self-administered symptom questionnaire was completed immediately before and immediately after each exposure. The symptom questionnaire consists of a 5-point rating scale (0 = none and 4 = severe) for 12 symptoms, including lower respiratory (chest discomfort/tightness, chest pain on deep inspiration, shortness of breath, cough, phlegm or sputum production, and wheezing), upper respiratory (throat irritation and nasal irritation), and nonrespiratory (anxiety, eye irritation, headache, and nausea) symptoms.

Bronchoscopy and Lavage Procedures
Bronchoscopies were performed 18 ± 2 hours after the 1-D exposure and after the MD Day 4 (MD4) exposure. The 18 ± 2–hour postexposure time was chosen because previous studies by both our laboratory and other investigators have documented the presence of an O₃-induced inflammatory response in many subjects at this time point (5, 6, 27). Our laboratory's procedures of bronchoscopy and BAL have been previously discussed in detail (5, 27). Briefly, intravenous access was established, supplemental O₂ was delivered, and the upper airways were anesthetized with topical lidocaine. Sedation with intravenous midazolam and fentanyl was used as needed for subject comfort. The bronchoscope was introduced through the mouth and vocal cords into the airways. The bronchoscope was then directed into the right middle lobe where lavage was performed with two 50-ml aliquots of 0.9% saline warmed to 37°C. The first 15 ml of fluid returned from the first 50-ml aliquot was collected separately and designated bronchial fraction (BFx), whereas the remaining fluid returned was designated BAL. Both lavage samples were immediately put on ice. Multiple endobronchial biopsies were obtained from segmental orifices for potential immunohistochemical analyses of cellular infiltration and protein expression. After bronchoscopy, each subject was observed for an approximate 2-hour recovery period.

Total cells were counted on uncentrifuged aliquots of BFx and BAL using a hemocytometer. Differential cell counts were obtained from slides prepared using a cytocentrifuge, 25 x g for 5 minutes, and stained with Diff-Quik (Dade Behring, Düdingen, Switzerland) as previously described (27). Cells were counted by two independent observers; the average of the two counts was used in data analysis. BFx and BAL fluids were then centrifuged at 180 x g for 15 minutes, and the supernatant was separated and recentrifuged at 1,200 x g for 15 minutes to remove any cellular debris before freezing at –80°C.

Measurement of Biochemical Constituents of BFx and BAL Supernatants
Biochemical assays were performed on BFx and BAL supernatants that had been frozen at –80°C from 13 subjects. Two markers of neutrophilic inflammation, interleukin 8 (IL-8) and myeloperoxidase, and one marker of acute phase reaction, IL-6, were measured with commercially available immunoassays (R&D Systems, Minneapolis, MN). Total protein was measured using the BCA Protein Assay kit (Pierce, Rockford, IL).

Statistical Analysis
All data were entered into a database developed in Microsoft Access 2000 (Microsoft, Redmond, WA). Processed data were then analyzed using Stata 7.0 software (StataCorp, College Station, TX).

For the analysis of spirometric responses to O₃ across each exposure, we performed paired Student's t tests using preexposure minus postexposure values. For the analysis of symptoms (a categoric outcome variable) across each exposure, we performed Wilcoxon's signed-rank tests. Correlation of respiratory symptoms and FEV₁ was evaluated using the Spearman coefficient. To compare cell counts and biochemical constituents between the lavage fluids obtained after 1-D and MD4, we also used paired Student's t tests. For the analysis of spirometric and respiratory symptom data among different exposure days, we performed a multivariable linear regression that included random subject effects to account for clustering by subject (repeated measures) in the model. A p value of 0.05 was considered statistically significant in all data analyses.

The sample size for this study was calculated on the basis of our laboratory's previous data for O₃ exposure in subjects with asthma (21). Single-day O₃ exposure results in neutrophilia of 23.6 ± 14.3 and 10.7 ± 8.0% (mean ± SD) in BFx and BAL, respectively. Our null hypothesis was that, similar to healthy subjects without asthma (11), the neutrophilia would attenuate toward levels seen after filtered air exposure (mean ± SD: 6.6 ± 11.9 and 3.3 ± 1.2% in BFx and BAL, respectively) (21). The alternate hypothesis was that MD exposure to O₃ would result in continued neutrophilia in BFx and BAL at least at the same level as 1-D exposure. On the basis of these numbers, and for a two-sided type I error of 0.05 and power of 0.8, the sample size would be 8 and 12 subjects for the outcomes of BFx and BAL neutrophilia, respectively. We chose a conservative sample size of 14.

	RESULTS

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Exposure Data
Mean O₃ concentrations were not significantly different from each other on any exposure day (mean ± SD: 0.208 ± 0.005 ppm for 1-D exposure and 0.209 ± 0.005 ppm on the 4 days of MD exposures). The subjects' exercise E was not different between 1-D and MD1 exposures (mean ± SD: 41.3 ± 7.2 vs. 41.3 ± 8.2 L, respectively). E, however, decreased slightly on MD2 exposure (40.6 ± 7.4 L), and then increased slightly on MD3 and MD4 exposures (43.7 ± 7.0 L on MD4). The median time interval between exposure arms (1-D and MD) was 41 days (interquartile range, 31–90 days). The exposure order had no effect on any outcome variable in the multivariable regression models.

Spirometry
The preexposure values for, and the changes across exposure in, FVC, FEV₁, maximal midexpiratory flow rate (FEF_25–75), and FEF after 75% of expelled volume (FEF₇₅) are shown in Table 2. There were no statistically significant differences in any of these values between the 1-D and MD1 exposures.

View larger version (19K): [in this window] [in a new window]   Figure 1. The percentage of change in FEV1 across consecutive days of ozone exposure. Scatterplot representation of percentage decrease in FEV1 across each exposure of multiday (MD) arm of experiment (MD1–MD4). Mean values are presented in parentheses for each day. *p = 0.016 and p = 0.003 for comparisons with MD1 based on multivariable regression analysis.

	DISCUSSION

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Inhaled O₃ at high ambient concentrations can induce recruitment of neutrophils into the airway lumen, resulting in an increase in both the concentration and percentage of neutrophils in the respiratory tract lining fluid (RTLF). Many other irritants as well as viral infections that can cause asthma exacerbation also induce an initial neutrophilia in RTLF (31–33). Our hypothesis was that repeated short-term exposure to oxidative injury by O₃ would cause augmentation of this RTLF neutrophilia, which may in turn result in asthma exacerbation. Our previous data from healthy individuals without asthma using an identical MD O₃-exposure protocol showed an attenuation of RTLF neutrophilia (11). In this experiment, we expected the subjects with asthma to respond differently because they are an especially susceptible group with preexisting airway inflammation and increased airway oxidative burden (13–15, 34). The response of individuals with asthma to MD O₃ exposure may indeed be different from that of individuals without asthma because we observed no significant attenuation of RTLF neutrophilia in our subjects. It is important to note that, although we showed no progression of RTLF neutrophilia with MD O₃ exposure, progressive oxidative injury or inflammation might still be occurring in the airways given that we and others have observed persistent elevated concentrations of markers of injury and inflammation in RTLF (11, 12, 35, 36).

Despite the epidemiologic findings of increased rates of asthma exacerbation with episodes of air pollution (16–19), repeated short-term exposures appeared to blunt the effect of O₃ on respiratory symptoms in our study. After the initial worsening of respiratory symptoms across MD1 exposure (similar to 1-D exposure), the subjects' symptoms gradually improved starting with MD3 exposure, and by MD4, the subjects had no change in symptoms across the exposure, indicating the development of a sort of "tolerance" toward the O₃-induced oxidative injury. The close correlation between respiratory symptoms and the change in FEV₁ suggests that the increase in acute asthma exacerbations observed after O₃ exposure may be related in part to decreases in spirometric values (37). In our previous study of healthy subjects without asthma, we found a similar pattern of respiratory symptoms and lung function changes (11), suggesting the possibility that increased symptomatic morbidity from acute O₃ exposure in individuals with asthma may be related to lower baseline lung function. Thus, the acute O₃-induced worsening of respiratory symptoms in individuals with asthma may be unrelated to the underlying eosinophilic airway inflammatory process often considered responsible for asthma exacerbations.

Perhaps the most intriguing finding in our experiment is the increase in the concentration of alveolar macrophages in RTLF with successive days of O₃ exposure. As noted above, these macrophages demonstrate features associated with "activation," including large cytoplasm with foamy, granular microscopic appearance (29). In our previous study of healthy subjects without asthma, we found a similar pattern of increase in the concentration of macrophages in BFx, but not in BAL (35% increase in concentration of alveolar macrophages in BFx [p < 0.05] vs. 7% decrease in BAL from 1-D to MD4 exposure) (11). An increase in RTLF alveolar macrophages with recurrent O₃ exposures also has been previously reported in some animal studies (35, 38, 39). Taken together, the data from the current study and from previous animal studies suggest that repeated oxidative injury can result in continued recruitment and activation of macrophages into the airways. In addition, the greater macrophage response in individuals with asthma may be due to their altered airway inflammatory response to oxidative injury (34, 40, 41).

These alveolar macrophages may either produce or prevent further oxidative injury. They may be involved in suppression of the initial O₃-induced neutrophilic inflammation and/or may be directly involved in the antioxidant defense of the lungs. Recently, an alternative activation pathway of macrophages has gained attention, suggesting a possible role for alveolar macrophages in Th2 inflammatory responses, including asthma (42). In addition to increasing risk of asthma exacerbation, exposure to O₃ has been shown to be a risk factor for new-onset asthma in children (43), and alveolar macrophages may play a role in these responses. In a previous study, we showed that chronic long-term exposure to O₃ is associated with lower spirometric values in healthy individuals without asthma (44). The mechanisms of these chronic changes are not known, but likely involve airway remodeling. Alveolar macrophages have been implicated in airway remodeling processes (45) and thus may be involved in the long-term effects of O₃-induced oxidative injury. Further research is necessary to elucidate the role of alveolar macrophages in both asthma and oxidative injury.

The major limitation of our study was the relatively small sample size. This is a generic problem in controlled human exposure studies involving bronchoscopy. Despite the small sample size, however, we still had adequate power to detect significant differences in several lavage endpoints between 1-D and MD exposures. Another limitation, again inherent in controlled exposure studies, is that we were only able to study subjects with relatively mild asthma.

In conclusion, alveolar macrophages are recruited to the airways of subjects with asthma with repeated short-term exposures to O₃. On the other hand, neutrophil recruitment into the RTLF of these subjects did not increase with repeated exposures. O₃-induced oxidative airway injury, however, may continue to occur, and persistence of such injury may lead to airway remodeling. Our results suggest the need for further investigation of the role of alveolar macrophages in oxidant-induced airway remodeling.

	Acknowledgments

 
The authors thank Drs. Peter Bacchetti and David Glidden for their assistance with the statistical analysis and Robert Montanti for his assistance with bronchoscopy.

	FOOTNOTES

 
Supported by the National Institutes of Health (R01 ES08970 and M01RR00083–41), American Lung Association (Research Training Fellowship), and Chest Foundation (Clinical Research Training Grant).

Conflict of Interest Statement: None of the authors have a financial relationship with a commercial entity that has an interest in the subject of this manuscript.

Received in original form February 18, 2005; accepted in final form May 11, 2005

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