Abstract
Inhalation of organic dust from swine houses causes an intense inflammatory reaction in the respiratory tract, and increased bronchial responsiveness to methacholine in healthy subjects. The aims of the present study were to investigate whether exhaled nitric oxide (NO) is a marker of the inflammation caused by exposure to organic dust (swine dust), whether there is a relationship between an increase in exhaled NO and bronchial responsiveness, and also whether wearing a half-mask influences the airway reaction (assessed by exhaled NO) and the increased bronchial responsiveness.
Thirty-three healthy nonatopic, nonsmoking subjects were exposed during 3 h of light work in a swine confinement building. Eleven of the subjects were wearing a half-mask and 22 were unprotected. Lung function, bronchial responsiveness and exhaled NO were measured before and after exposure.
The provocative concentration causing a 20% fall in forced expiratory volume in one second fell by 2.7 (2.1–4.1) (median (25th–75th percentiles)) doubling concentration steps in subjects without a half-mask and by 1.5 (0.9–2.9) doubling concentration steps in subject wearing a mask. Exhaled NO increased from 7.5 (5.7–13.7) parts per billion (ppb) before to 13.4 (10.5–17.5) ppb after exposure in the unprotected group and was unaltered (8.3 (6.1–14.1) to 8.6 (6.6–14.6) ppb) in the group wearing a half-mask. There was no correlation between NO increase and provocative dose causing a 20% fall in the forced expiratory volume in one second decrease.
In conclusion, bronchial responsiveness and exhaled nitric oxide increased after exposure to a swine confinement facility. Half-mask abolished the increase in exhaled nitric oxide levels, but influenced the increase in bronchial responsiveness to a minor extent. These results indicate that these two outcome measures reflect different aspects of airway inflammation induced by exposure to a farming environment.
This study was supported by The Swedish Heart-Lung Foundation.
Endogenously produced nitric oxide (NO) in exhaled air of animals and humans was first measured by Gustafsson et al. 1, and it was suggested early that the concentration of exhaled NO may reflect airway inflammation, thus offering a noninvasive method to assess inflammatory airway diseases 2–4. Following a bronchial allergen challenge there is an elevation of exhaled NO levels in allergic patients and increased levels of exhaled NO are also observed in acute exacerbations of asthma 5–7. Endotoxin and several inflammatory cytokines, such as tumour necrosis factor-;α (TNF-;α), interferon-;γ and interleukin (IL)-;1 induce transcription of NO by inducible NO synthase (iNOS) 3, 8, which is generated as a response to inflammation or tissue injury.
Exposure to a swine confinement building for 3 h causes airway inflammation in healthy nonatopic subjects. Symptoms like fever and malaise are common. The exposure also increases bronchial responsiveness to methacholine and induces release of cytokines (e.g. TNF-;α and IL-;6, IL-;1, IL-;8) into the airways 9–13.
The aims of the present study were to investigate whether exhaled NO is a marker of the inflammation caused by exposure to the environment in swine confinement buildings and if there is a relationship between two inflammatory indices, the increase in bronchial responsiveness to methacholine and the level of exhaled NO. Furthermore, the aim was to find out whether wearing a half-mask influences the respiratory response to dust exposure.
Material and methods
Study subjects
Thirty-three healthy, nonatopic, nonsmoking subjects (14 males) with a mean age of 26 yrs (range 20–47) were exposed for 3 h, while weighing pigs, in a swine confinement building.
None of the subjects had a history of asthma, as assessed by a questionnaire, and all denied ongoing respiratory infections. All subjects gave their informed consent and the study was approved by the ethics committee at the Karolinska Institute, Stockholm, Sweden.
Study design
One week prior to the exposure, lung function, bronchial responsiveness and exhaled NO were measured. The subjects were randomised to wear a half-mask (n=11), with a class P2 filter (9322; 3MTm, Upplands Vasby, Sweden), or not to wear a mask (n=22) during exposure. The characteristics of the subjects were similar in the two groups.
Exposure took place in a swine confinement building with approximately 300 pigs, and five or six subjects were exposed on each occasion. Exposure was measured with personal samplers.
Exhaled NO was measured 5 h after the beginning of the exposure, and lung function and bronchial responsiveness to methacholine 2 h later. In eleven of the subjects without mask, exhaled NO measurements were repeated after the methacholine challenge and after inhalation of salbutamol (0.8 mg, Diskhaler; Ventoline®).
Symptoms such as shivering, headache, malaise, muscle pain and nausea were assessed before and after the visit to the swine confinement building. Oral temperature was measured before and every other hour following exposure.
Spirometry
Vital capacity (VC), forced expiratory volume in one second (FEV1) and airway resistance (Raw) were measured using a body plethysmograph (Eric Jaeger GmbH & Co, Würzburg, Germany). Spirometry was performed according to the American Thoracic Society recommendations and the best of at least three measurements was recorded 14. FEV1 was measured before and following inhalation of methacholine with a wedge spirometer (Vitalograph®, Buckingham, UK).
Methacholine provocation test
Bronchial challenge with methacholine was performed with a Sidestream jet nebuliser (Medic-Aid, Pagham, UK). In order to increase the methacholine deposition in the lower airways, the nebulisate was led through a drying device, where the aerosol was dried for about 8 s before inhalation 15, 16. Inhalation time (2 s, i.e. a volume of 0.8 L), and number of breaths (15 min−1) were controlled using a metronome. The inhalation flow was controlled by the use of a back valve at the outlet of the tube.
Methacholine inhalations were performed during 1 min, i.e. 30 s of inhalation and 30 s of exhalation, at each concentration and FEV1 was measured 4 min after the start of the inhalation. There were 6 min between the start of the inhalations of two successive concentrations. The subjects inhaled diluent followed by methacholine (0.5, l, 2, 4, 8, 16, 32 mg·mL−1). Only one FEV1, i.e. one forced expiration, was allowed at each dose step. The provocation concentration causing a 20% fall in FEV1 (PC20) and the provocation dose causing a 20% fall in FEV1 (PD20) were calculated. The PC/PD calculations were performed by interpolation on a logarithmic scale of concentration or cumulated dose of methacholine, respectively. The dose/response slope (DRS) of change in FEV1 was calculated by linear regression including all data points, using the per cent change of FEV1 (initial value as the average of pre and postdiluent value) as a function of the cumulated methacholine dose 17.
Exhaled nitric oxide
Exhaled NO was determined during single-breath exhalations 2, 18, 19. The subject inhaled NO-free air via a mouthpiece to total lung capacity, followed immediately by full exhalation, with a flow rate of about 100 mL·s−1, through the mouthpiece into the the apparatus. During exhalation, an excess pressure was created in the oral cavity, which ensures closure of the velum and prevents contamination of the sample with nasal air. Nitric oxide was measured with chemiluminescence after reaction with ozone in the Aerocrine NO-system (type EBA:I; Aerocrine AB, Stockholm, Sweden). The mean of three measurements was considered for evaluation. To reduce contamination from the oral cavity, subjects used a mouthwash with sodium bicarbonate (10%) for 1 min before the measurement 20.
Symptoms
Symptoms were evaluated on a visual analogue scale (VAS, 0–100 mm) where zero represented no symptoms and 100 mm unbearable or very strong symptoms. The subject was requested to put a cross on the scale. The length, between the zero point and the cross, was measured and the difference before and after exposure was calculated.
Exposure measurement
IOM samplers equipped with filter cassettes (25 mm; Institute of Occupational Medicine, SKC Ltd, Dorset, UK) and portable pumps (SKC Ltd) were used to monitor inhalable dust levels, and the cassettes were equipped with polycarbonate filters (pore size 0.4 µL) (Millipore, Sundbyberg, Sweden). Each subject carried the samplers in the breathing zone. The airflow was measured with a rotameter before and after sampling and adjusted to 2 L·min−1. Inhalable dust was measured by a normal weighing procedure, after 24 h of conditioning, using a Mettler® ME22 balance (Mettler, Greisensee, Switzerland) and reference filter.
Statistical analysis
Results are presented as mean (sd or 95% confidence interval (CI)) or median values (25th–75th percentiles). Statistical comparisons were assessed by t-;test for paired observations (lung function) and the Wilcoxon's signed rank-sum test (symptoms, bronchial responsiveness and NO values) within groups. Analysis of variance (ANOVA) and Mann-Whitney U-;tests were used when groups were compared. A p-;value <0.05 was considered significant.
Results
Body temperature increased in all but four subjects after exposure to organic dust (0.4 (0.29–0.55)°C (95% CI), p<0.001). Symptoms like shivering, headache and malaise increased significantly (p<0.005), and one subject also reported muscle pain. There was no significant difference in reported symptoms or temperature between subjects with and without mask. The median (25th–75th percentiles) inhalable dust level was 9.9 mg·m−3 (8.6–14.6).
Lung function was normal in both groups: VC 94 (10) and 95 (6) % predicted; total lung capacity 95 (9) and 96 (8) % pred; and FEV1 98 (11) and 100 (9) % pred, in subjects without and with the half-mask, respectively. Following exposure to organic dust VC decreased by ∼2% in both groups and there was a decrease in FEV1 of 2.7% in the protected group (p=0.002) and 6% in the group without mask (p<0.001). There was no significant change in airway resistance in either group.
Exposure induced an increase in bronchial responsiveness to methacholine; PD20 fell from 3.3 (2.6–14.1) to 1.0 (0.39–2.8) mg in subjects wearing the mask (p=0.005) and from 1.8 (0.77–9.0) to 0.2 (0.10–0.45) mg in subjects without mask (p=0.0001). The slope increased from 5.7 (1.4–8.2) to 18.6 (9.9–54.6) %·mg−1 (p=0.003) with mask and from 13.7 (2.1–27.0) to 91.8 (38.8–209.6) %·mg−1 (p=0.0002) without mask (fig. 1⇓).
There was no significant difference between the two groups with regard to the change of concentration steps (p=0.07).
Exhaled NO increased from 7.5 ( 5.7–13.7) ppb before exposure to 13.4 (10.5–17.5) ppb 5 h after exposure (p=0.0001) in the group without the mask. In the group with mask exhaled NO did not change significantly, 8.3 (6.1–14.1) ppb before and 8.6 (6.6–14.6) after exposure, (p=0.48, fig. 2⇓). There was a significant difference between the two groups with regard to the NO response (p=0.006).
In 11 subjects without mask, exhaled NO was measured repeatedly. Exhaled NO level was 6.6 (5.5–7.4) ppb at baseline, 14.1 (11.8–17.8) ppb 5 h after exposure and 14.0 (11.8–19.2) ppb 7 h after exposure. The methacholine challenge induced a small decrease in NO before (p=0.06) and after (p=0.01) exposure. Inhalation of salbutamol did not significantly further alter the levels of exhaled NO. Exhaled NO measured after inhalation of the β2 agonist on the exposure day was still significantly increased compared to baseline pre-exposure values (p=0.003) (fig. 3⇓).
There was no significant correlation between the increase in bronchial responsiveness and exhaled NO following exposure to organic dust (r=0.08, p=0.44).
Discussion
In this study it has been demonstrated that exposure to swine dust is associated with increased levels of exhaled NO and increased bronchial responsiveness to methacholine and that there is no relationship between these two findings. Protection with half-mask inhibits the increase of exhaled NO whereas the increase in bronchial responsiveness is influenced only to a minor extent.
In the present study, it has been demonstrated that NO levels are approximately doubled in subjects exposed to a swine confinement facility. Increased levels of NO may indicate an induction of bronchoalveolar iNOS induced by exposure, which in turn induces production of pro-inflammatory cytokines in a variety of cells. The inflammatory reaction after acute exposure to organic dust, with increased number of neutrophils, macrophages and activated lymphocytes, in healthy subjects is similar to the inflammation observed in patients with chronic bronchitis 21, 22. This is in accordance with the finding that repeated exposure to the farming environment leads to the development of airway disease, especially chronic bronchitis, in pig farmers 23, 24.
Kölbeck et al. 25 were not able to show increased levels of exhaled NO following exposure to dust in a swine confinement building. Different techniques and a more standardised procedure to determine exhaled NO in the present study could possibly explain the discrepancies. Furthermore, in another study where subjects performed a nasal challenge with swine confinement dust, slightly elevated levels of exhaled NO were demonstrated 26. In that study exhaled NO increased within the first hour after exposure, indicating a rapid induction of NO. In the present study, for practical reasons, exhaled NO was measured 5 h after the beginning of exposure in the confinement building. The NO levels at that time point were almost identical to the NO values, measured 2 h later.
Methacholine challenge decreased exhaled NO both before and 7 h after the exposure. Bronchial challenge with methacholine has not been shown previously to alter the levels of exhaled NO in asthmatic subjects 27, 28. However, Kolbeck et al. 25 demonstrated decreased levels of exhaled NO after histamine provocation in healthy subjects exposed to dust. Deykin et al. 29 showed a fall in exhaled NO levels after repeated spirometries in subjects with atopic asthma and also showed that hyperventilation and physical exercise increased the NO production but decreased the concentration of exhaled NO in healthy nonasthmatic subjects 30, 31. A possible explanation for the decrease in exhaled NO levels after methacholine challenge in the present study could thus be deep breaths performed prior to the FEV1 measurements during the methacholine provocation challenge.
Inhalation of salbutamol after the methacholine provocation test did not influence the level of exhaled NO in subjects with ongoing inflammatory airway reaction due to exposure to organic dust. This is in accordance with findings in asthmatic subjects where regular use of short and long-acting β2 agonists did not alter the levels of exhaled NO 32.
Wearing a half-mask attenuated the increase of exhaled NO and bronchial responsiveness due to exposure. In subjects using half-mask, the bronchial responsiveness increased significantly by approximately 1.5 doubling concentration steps, whereas exhaled NO remained unchanged after exposure. Particles and microbial agents stimulate NO production, and NO contributes to the chemical defence mechanisms that keep the airways free from microorganisms 33. The half-mask filters particles and bacterial components and it completely abolished the increase of exhaled NO-levels following exposure whereas, the influence of the mask on the increase of bronchial responsiveness was minor. This suggests that other components than particles may be responsible for the increased bronchial responsiveness. In accordance with the present findings Dosman et al. 34 recently demonstrated a minor, but significant, increase in bronchial responsiveness in subjects protected with mask and a greater increase in subjects without mask when exposed to swine dust.
A high correlation between exhaled NO and airway hyperresponsiveness have been demonstrated in both mild and severe asthma 35–37. In the present study, no relationship between increases of exhaled NO and bronchial responsiveness in healthy subjects, following exposure in a swine confinement building, were found. Recently, in a population study, the current authors have demonstrated a significant correlation between exhaled NO levels and bronchial responsiveness to methacholine in subjects with asthma but not in healthy subjects 38. In that study the methodology was identical to that used in the present study. Thus, the increased response to methacholine and exhaled NO may reflect different aspects of airway inflammation in healthy subjects. In asthma, it is likely that the inflammation causes bronchial hyperresponsiveness and that NO should be regarded as a marker of airway inflammation rather than as an endogenous modulator of bronchial tone 27, 39, 40. In subjects exposed to organic dust this seems not to be the case.
In conclusion, bronchial responsiveness and exhaled nitric oxide increases after exposure to organic dust. The half-mask inhibited the increase in exhaled nitric oxide levels but had a minor effect on the increase of bronchial responsiveness to methacholine. The current findings indicate that exhaled nitric oxide and increased bronchial responsiveness to methacholine reflect different aspects of airway inflammation in this model.
Acknowledgments
The authors would like to thank S. Siljerud, F. Acevedo and C. Kallin for their excellent technical assistance.
- Received July 2, 2001.
- Accepted February 28, 2002.
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