To help assess respiratory health risks from sulfur dioxide (SO2) air pollution, we studied 24 normal, 21 atopic, 16 minimal/mild asthmatic, and 24 moderate/severe, medication-dependent asthmatic subjects classified according to history, lung function, allergy skin tests, serum IgE level, and airway reactivity to methacholine. All were exposed in a chamber (21 degrees C, 50% humidity) to 0.0, 0.2, 0.4, and 0.6 ppm SO2 in random order at 1-wk intervals; then exposures were repeated to test consistency of response. The 1-h exposures included three 10-min exercise periods (ventilation approximately 40 L/min). Physiologic response was measured early (approximately 15 min) and late (approximately 55 min) in exposure. Symptoms were evaluated during exposure and for 1 wk afterward. Normal and most atopic subjects showed little response at these SO2 levels. A few atopic subjects and many asthmatics developed bronchoconstriction and respiratory symptoms, but most were able to maintain their exercise. Effects were not markedly different between early and late measurements, nor between the first and second round of studies; however, late and second-round responses appeared slightly more favorable. No statistically significant effect of SO2 on symptoms was found 1 day or 1 wk after exposure. Minimal/mild asthmatics showed, on the average, slight responses at 0.0 ppm (attributable to exercise) and increasing responses at increasing SO2 concentrations. Moderate/severe asthmatics reacted more at 0.0 ppm, but their increments in response with increasing SO2 concentration were roughly similar to those of minimal/mild asthmatics. Thus, responses to SO2 per se were not strongly dependent on clinical severity of asthma, nor on SO2 exposure history during previous weeks.
This study was intended to help explain individual differences in susceptibility to irritant effects of ozone (O3), by determining whether prior ambient O3 exposures and/or recent acute respiratory illness modified response to laboratory O3 exposures. Response was measured in terms of lung function changes and irritant symptoms. Initially, 59 adult volunteer Los Angeles area residents underwent screening exposures in spring, before the season of frequent high ambient O3 levels. Unusually responsive and nonresponsive individuals (N = 12 and 13 respectively) underwent followup exposures in autumn (late in the high-O3 season) and in winter (low-O3 season). All exposures were to 0.18 ppm O3 for 2 hr with intermittent heavy exercise at 31 degrees C and 35% relative humidity. Nonresponders tended to remain nonresponsive throughout. In fall, responders had lost much of their reactivity, as if they had "adapted" to summer ambient O3 exposures. They did not regain reactivity by winter. Clinical laboratory findings suggestive of acute respiratory illness did not appear to correlate with O3 response. Eight responders and 9 nonresponders underwent another followup exposure in spring, about 1 yr after screening. By that time most responders had regained their reactivity; individual function changes were significantly correlated with changes 1 yr earlier. These results suggest that response to O3 is a persistent individual characteristic, but can be modified by repeated ambient exposures.
To evaluate effects of "acid summer haze" on individuals who exercise extensively outdoors, we exposed 45 adult volunteers (15 normal or atopic, 30 asthmatic) in a chamber to a mixture of 0.12 ppm ozone (O3) and approximately 100 micrograms/m3 of respirable sulfuric acid aerosol (H2SO4). On separate occasions we exposed the same subjects to O3 alone, to H2SO4 alone, and to clean air. In exposures involving H2SO4, excess acid was generated to consume ammonia released by the subjects, and the aerosol therefore contained ammonium salts in addition to H2SO4. Subjects were exposed to each atmosphere on two successive days, for 6.5 h/d, with six 50-min exercise periods at ventilation rates averaging 29 L/min. Exposures were conducted during four successive weeks, in random order. Lung function and symptoms were measured before exposure and hourly during exposure. Bronchial reactivity to inhaled methacholine was measured just after the end of each exposure. Exposure to H2SO4 alone caused no significant changes in lung function, symptoms, or bronchial reactivity relative to clean air. Exposure to O3 alone or O3 + H2SO4 caused a progressive, statistically significant (p < 0.05) decline in forced expiratory function, smaller on the second day than the first, as previously found by others for O3 exposure. Bronchial reactivity increased significantly after exposure to O3 with or without H2SO4. Changes in mean lung function and bronchial reactivity with O3 + H2SO4 exposure were modestly larger than changes with O3 exposure, but the differences were nonsignificant or marginally significant. A minority of individual asthmatic and nonasthmatic subjects showed substantially greater declines in function with exposure to O3 + H2SO4 relative to O3 alone. Repeat exposure studies of these subjects again showed an excess response to O3 + H2SO4 on the average, but there was no significant correlation between the excess responses of individual subjects in the original and repeat studies. We conclude that for typical healthy or asthmatic adults heavily exposed to acid summer haze, O3 is more important than H2SO4 as a cause of short-term respiratory irritant effects.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.