nitrogen-dioxide and Hyperventilation

Previous studies in asthmatic subjects and guinea pigs have demonstrated attenuation of bronchoconstriction in repeated exposures to clean cold dry air. In the present animal study, we have simulated short-lasting human exposures to subfreezing urban air containing sulfur dioxide (SO(2)) and nitrogen dioxide (NO(2)). The anesthetized, paralyzed, and mechanically ventilated guinea pigs had 4 consecutive 10-min exposures either to clean cold dry air or to cold air with graded concentrations of SO(2) (0-5 ppm) or NO(2) (0-4 ppm). Peak expiratory flow (PEF) and tidal volume (V(T)) were continuously measured both during and after highly controlled exposures. Bronchoalveolar lavage fluid (BALF) and histological samples were obtained after finishing the consecutive exposures. Cold air + SO(2) at 1 and 2.5 ppm (n = 12) produced immediate concentration-dependent increases in the lung function responses compared to the preceding single exposure to clean cold dry air in the same animals (DeltaPEF = -32.7 +/- 6.1% and -35.6 +/- 6.5% vs. -27.0 +/- 3.1%; DeltaV(T) = -22.4 +/- 4.4% and -28.3 +/- 4.7% vs. -18.1 +/- 2.9%). In a multivariate analysis, these responses were significantly larger than the attenuated lung function responses to the corresponding second and third clean cold dry air exposures (p <. 05). The fourth exposure to cold air + SO(2) at 5 ppm produced a smaller response (DeltaPEF = -25.3 +/- 4.8% and DeltaV(T) = -17.8 +/- 3.7%) than cold air with the lower SO(2) concentrations. Cold air + NO(2) at 1 and 2.5 ppm (n = 12) produced roughly similar lung function responses to the preceding single exposure to clean cold dry air in the same animals, and there was no significant attenuation of bronchoconstriction as with the consecutive exposures to clean cold dry air. The largest decreases in lung functions (DeltaPEF = -33.8 +/- 6.7% and DeltaV(T) = -26.2 +/- 6.8%) were recorded during the fourth exposure, which was to cold air + NO(2) at 4 ppm. In the cold air + SO(2) group, there was a significantly lower proportion of macrophages in the differential count of BALF white cells compared to the clean cold dry air group. In addition, there was eosinophilic infiltration within and below the tracheal epithelium in all guinea pigs exposed to either clean cold dry air, cold air + SO(2), or cold air + NO(2). In conclusion, the addition of moderate concentrations of SO(2) or NO(2) to clean cold dry air counteracted the attenuation of bronchoconstriction induced by repea

Topics: Air Pollutants; Animals; Bronchoalveolar Lavage Fluid; Bronchoconstriction; Cell Count; Cold Temperature; Dose-Response Relationship, Drug; Eosinophilia; Guinea Pigs; Hemodynamics; Hyperventilation; Inhalation Exposure; Macrophages; Male; Models, Animal; Nitrogen Dioxide; Propranolol; Pulmonary Ventilation; Respiration, Artificial; Sulfur Dioxide; Tidal Volume; Trachea

The present study is a continuation of our previous experiments on repeated 10-min exposures of anesthetized, mechanically ventilated guinea pigs to clean cold dry air (Hälinen et al., 2000a), and to cold air plus gaseous air pollutants (Hälinen et al., 2000b). This time we made continuous 60-min exposures to clean cold dry air, cold air + SO(2) at 1 ppm, cold air + NO(2) at 1 ppm, and warm humid air + NO(2) at 1 ppm, and focused on responses at 10-60 min. Clean cold dry air and cold air + pollutants (n = 8-9 in each group) produced similar cooling in the guinea pig lower respiratory tract. The decreases in intratracheal temperature (T(tr)) reached a plateau at 20 min with mean maximal decreases of 9.7-11.3 degrees C from the pre-exposure control values of 36.0-37.3 degrees C. In contrast, there were progressive decreases in esophageal temperature (T(oe)) during the exposures, indicating constant conductive and evaporative heat losses from the tracheobronchial tissues. The mean maximal decreases in T(oe) were 1.2-1.4 degrees C from the preexposure control values of 37.8-38.0 degrees C. Clean cold dry air induced 4. 5-10.8% mean decreases in peak expiratory flow (PEF) at 10-60 min of exposure, which were statistically nonsignificant due to a relatively large variation between animals. Cold air + SO(2) at 1 ppm induced a mean decrease of 11.4% in PEF at 10 min (p <.05), which was spontaneously abolished during the next 10 min of exposure. Cold air + NO(2) at 1 ppm caused no decrease, but in fact small, nonsignificant increases in PEF at 30-60 min of exposure. Cold air + NO(2) at 1 ppm, and to some extent also cold air + SO(2) at 1 ppm, attenuated significantly the mechanical ventilation induced gradual decrease in tidal volume (V(T)), when compared to clean cold dry air exposure. Cold air + NO(2) at 1 ppm, but not warm humid air + NO(2) at 1 ppm, increased significantly the proportion of macrophages in the differential count of bronchoalveolar lavage fluid (BALF) white cells when compared to both clean warm humid air and cold dry air. None of the exposure conditions caused morphological or inflammatory changes in the respiratory tissues. In conclusion, continuous 60-min exposures to clean cold dry air, cold air + SO(2), and cold air + NO(2) produced weaker functional effects on the lower respiratory tract of guinea pigs than our previous consecutive 10-min exposures to these air conditions. After the first 10 min, there was a strong attenuation of the bronc

Topics: Air Pollutants; Animals; Bronchoalveolar Lavage Fluid; Bronchoconstriction; Cell Count; Cold Temperature; Esophagus; Guinea Pigs; Hyperventilation; Inhalation Exposure; Lung; Male; Models, Animal; Nitrogen Dioxide; Pulmonary Ventilation; Respiration, Artificial; Respiratory Mucosa; Sulfur Dioxide; Temperature; Tidal Volume; Time Factors; Trachea

Epidemiologic studies support an association among elevated levels of nitrogen dioxide (NO2), increased respiratory symptoms, and alterations in lung function. To determine if low level NO2 inhalation potentiates exercise-induced bronchospasm, 15 asthmatic subjects, defined by airway constriction with cold air provocation, inhaled 0.30 ppm (560 micrograms/m3) NO2 for 30 min. All asthmatics inhaled either air or 0.30 ppm NO2 via a mouthpiece for 20 min at rest followed by 10 min of exercise on a bicycle ergometer at a workload of 300 kpm/min, producing a 3-fold or greater increase in minute ventilation. Our studies showed 72 +/- 2 (SE)% deposition of inhaled NO2 at rest and 87 +/- 1% deposition with exercise (p less than 0.001). Nitrogen dioxide inhalation at rest resulted in no significant change in pulmonary function. Nitrogen dioxide inhalation plus exercise compared to control (air) exposure plus exercise produced significantly greater reductions in FEV (p less than 0.01) and partial expiratory flow rates at 60% of total lung capacity (p less than 0.05). One hour after completion of NO2 exposure and exercise, pulmonary function had returned to baseline values. To determine if NO2 exposure caused increased reactivity to a known bronchoconstrictor, asthmatic subjects inhaled cold air (range: -11 +/- 2 degrees C) at 3 successive rates of isocapnic ventilation. The response to cold air was expressed as the respiratory heat exchange required to reduce the FEV by 10% (PD10RHE). Prior NO2 exposure potentiated the fall in FEV, PD10RHE, and specific airway conductance (p less than 0.05) after isocapnic cold air hyperventilation, compared to the control exposure.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Adult; Asthma; Asthma, Exercise-Induced; Bronchial Provocation Tests; Cold Temperature; Dose-Response Relationship, Drug; Humans; Hyperventilation; Lung; Nitrogen Dioxide; Respiratory Function Tests; Rest; Time Factors