Effects of ambient ozone on respiratory function in healthy adults exercising outdoors

The effect of exposure to ozone (O3) in ambient air on respiratory function was studied in 30 healthy adult nonsmokers engaged in a regular daily program of outdoor exercise in Tuxedo, NY during the summer of 1985. Each subject did the same exercise each day, but exercise intensity and duration varied widely between subjects, with minute ventilation ranging from 20 to 153 L and duration ranging from 15 to 55 min. Spirometry was performed immediately before and after each exercise period. O3 concentrations during exercise ranged from 21 to 124 parts per billion (ppb). All measured functional indexes showed significant (p less than 0.01) O3-associated mean decrements with FVC at -2.1 ml/ppb, FEV1 at -1.4 ml/ppb, PEFR at -9.2 ml/s/ppb, FEF25-75 at -6.0 ml/s/ppb, and FEV1/FVC at -0.038%/ppb. Mean decrements were smaller for 10 subjects with minute ventilations greater than 100 L than for 10 other subjects with minute ventilations between 60 and 100 L or for the 10 subjects with minute ventilations below 60 L. Overall, the functional decrements were similar in magnitude to those we have seen in children engaged in supervised recreational programs in summer camps. For 10 subjects with minute ventilations comparable to those used in controlled 1- and 2-h exposures to O3 in purified air in chambers (50 to 80 L), the effects were about twice as large as those reported for the chamber studies.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acute ozone exposure increases plasma prostaglandin F2 alpha in ozone-sensitive human subjects

Twenty O3-sensitive and 2O O3-nonsensitive subjects participated in a study to investigate the effects of disparate O3 sensitivity on plasma prostaglandin F2 alpha) responses consequent to exposure to ambient O3 concentrations. Subjects were selected from a pool of 75 normal healthy college-aged males who had been previously exposed to 0.35 ppm O3 for 1 h at an exercising VE of 60 L/min. The selection criterion used was the observed decrement in FEV1 after the O3 exposure: O3-sensitive, FEV1 decrement greater than 24%; O3-nonsensitive, FEV1 decrement less than 11%. Each subject was exposed to filtered air and to 0.20 and 0.35 ppm O3 for 80 min while exercising at a VE of 50 L/min. These experimental protocols were divided into two 40-min sessions separated by a period of 4 to 10 min. PGF2 alpha, FVC, FEV1, and FEF25-75 were evaluated before, during, and after each protocol. SGaw and Vtg were measured before and after each protocol. Plasma PGF2 alpha was significantly increased in the O3-sensitive group during and after the 0.35-ppm O3 exposure.     

Relationship between bronchial response to respiratory heat exchange and nonspecific airways reactivity in asthmatic patients

In this study we have examined the relationship between the bronchial response to inhaled histamine and the bronchial response to breathing cold air at rest in nine control subjects and nine patients with asthma. Dried warm air (mean temp: +/- 1SD: 25.4 +/- 1.6 degrees C) and cold air (-19.7 +/- 2.6 degrees C) were breathed for 10 minutes each during quiet breathing at rest prior to as well as during both measurements of forced expired spirograms and the phase 3 slope of the single-breath oxygen test (delta N2/L). Subjects were also challenged with inhaled aerosolized histamine to determine the concentration required to reduce the forced expired volume in one second (FEV1) by 20 percent (PC20). Both asthmatic and control subjects had significantly greater respiratory heat exchange breathing cold as compared to warm air (p less than 0.01 in both cases). Control subjects did not change FEV1 or delta N2/L breathing cold air. Asthmatic patients increased delta N2/L from a mean warm air value of 2.41 +/- 1.31% N2/L to a mean cold air value of 5.39 +/- 4.55% N2/L (p less than 0.05). There was a significant linear correlation between the percent increase in delta N2/L from warm to cold air and 1/log10PC20 (r = -0.97, p less than 0.001) and also the percent decrease in FEV1 and log PC20 (r = -0.76, p less than 0.03) in the asthmatic patients. We conclude that cold air-induced alterations in ventilation/distribution and expired flow rates in asthmatic patients are related to pre-existing nonspecific airways reactivity.     

Comparison of peak expiratory flow rate and FEV1 in assessing bronchomotor tone after challenges with occupational sensitizers

Bronchial responses to occupational sensitizers measured by peak expiratory flow rate (PEFR) and forced expiratory volume in 1 s (FEV1) during late reactions (between 90 minutes and 8 hours after exposure) were compared in two groups of 88 subjects who had undergone specific inhalation challenges in the laboratory. The first group had what was considered a positive reaction (a fall of at least 15 percent in FEV1) whereas the second group's reaction was interpreted as negative (fall in FEV1 less than 15 percent). Although the correlation in terms of percentage of change from baseline values was statistically significant, the correspondence was poor. PEFR proved far less sensitive than FEV1 in detecting a reaction. Whereas the mean maximum change in FEV1 overall was 27 percent, the mean maximum change in PEFR at the same time interval was only 16 percent. Moreover, individual correlations between the percentage of change in FEV1 and PEFR were satisfactory (r2 greater than 0.80) in only 32/88 subjects (36 percent). No subject who was considered to have a negative challenge according to FEV1 had a change in PEFR greater than 20 percent. We therefore conclude that changes in PEFR are far less sensitive than changes in FEV1 in detecting responses during late reactions to occupational sensitizers.     

Influence of short-term passive smoking on symptoms, lung mechanics and airway responsiveness in asthmatic subjects and healthy controls.

We studied the acute effect of passive smoking on symptoms, lung mechanics and airway responsiveness. Twenty four patients with mild to moderate bronchial asthma (11 male and 13 female; mean(SD) age 34(15) yrs; forced expiratory volume in one second (FEV1) 91(17) % pred) were investigated. Sixteen of them had a history of passive smoke-induced respiratory symptoms. For comparison we studied 16 controls (7 male and 9 female; mean(SD) age 31(9) yrs; FEV1 106(13) % pred). On two different days, the subjects were exposed in an exposure chamber for one hour to either ambient air (Sham) or environmental tobacco smoke (ETS). During exposure to ETS, the mean concentrations of particles and CO were 3,095 micrograms.m-3 and 20.3 ppm, respectively. Before and immediately after exposure, symptoms and lung mechanics were assessed, followed by an inhalation challenge to determine the provocative concentrations of methacholine necessary to increase specific airway resistance (sRaw) by 100%, (PC100sRaw), and to decrease FEV1 by 20% (PC20FEV1). In the asthmatic subjects, during Sham exposure, mean (SEM) decrease of sRaw and FEV1 was 0.23(0.22) cmH2O.s and 0.04(0.03) l, respectively, (NS). During ETS, mean(SEM) decrease of sRaw and FEV1 was 0.55(0.46) cmH2O.s and 0.13(0.06) l, respectively. The significance of this decrease, however, disappeared when taking into account the individual variability of FEV1. Geometric mean(SEM) PC100sRaw and PC20FEV1 were 0.35(1.32) and 0.23(1.34) mg.ml-1 after Sham, and 0.34(1.37) and 0.28(1.36) mg.ml-1 after ETS, respectively, with no difference between the two study days. In the controls, the two exposure conditions did not exert any significant effects on sRaw, FEV1 and airway responsiveness.(ABSTRACT TRUNCATED AT 250 WORDS)     

Respiratory dysfunction in patients with common variable hypogammaglobulinemia

Patients with common variable hypogammaglobulinemia (CVH) are susceptible to recurrent respiratory infections. We studied the prevalence and severity of respiratory dysfunction in 32 patients with CVH by measuring routine pulmonary function tests (PFT) and interpreting chest radiographs using a quantitative score system. Pulmonary symptoms were determined by patient interview and standard questionnaire. The mean age of 29 living patients was 28 +/- 2.2 yr; there were 22 males and 10 females. The mean age at diagnosis was 17.3 +/- 2.4 yr. Sinopulmonary symptoms were present in all 32 patients and included chronic sinusitis, otitis, bronchitis, recurrent pneumonia, and bronchiectasis. Complete PFT in 25 patients revealed restrictive, obstructive, and normal patterns in 10, 6, and 9 patients, respectively. Nine patients had dyspnea on exertion. Recent chest radiographs in 32 patients showed evidence of recurrent pulmonary infection, including air trapping, linear markings, and pleural abnormalities. Panlobular emphysema, documented in one case at autopsy, was suggested in 5 other patients by the presence of lower lobe bullous lesions and marked lower lobe hyperlucency on chest radiographs. The forced vital capacity (FVC) and forced expiratory volume in 1 second (FEV1) had remained stable in 19 adults (18 receiving adequate immunoglobulin replacement therapy) for 6.9 +/- 0.7 yr. The expected increase of the FEV1 and FVC with growth was normal in 6 of 8 children (all 8 receiving adequate therapy). Chest radiograph scores deteriorated only slightly from 20.3 +/- 0.6 to 18.4 +/- 0.8 (25 = normal) during the 6.9 +/- 0.7 yr in 30 patients (p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of steady-state and variable ozone concentration profiles on pulmonary function.

Measurements of ambient ozone (O2) concentration during daylight hours have shown a spectrum of concentration profiles, from a relatively stable to a variable pattern usually reaching a peak level in the early afternoon. Several recent studies have suggested that in estimating exposure dose (O3 concentration [C] x exposure time [T] x ventilation [V]), O3 concentration needs to be weighted more heavily than either ventilation or duration of exposure in the estimates. In this study we tested the hypothesis that regardless of concentration pattern and exposure rate the same exposure dose of O3 will induce the same spirometric response. We exposed 23 healthy male volunteers (20 to 35 yr of age) for 8 h to air, 0.12 ppm O3 (steady-state), and a triangular exposure pattern (concentration increased steadily from zero to 0.24 ppm over the first 4 h and decreased back to zero by 8 h). During the first 30 min of each hour, subjects exercised for 30 min at minute ventilation (VE) approximately 40 L/min. The order of the exposures was randomized, and the exposures were separated by at least 7 days. The response patterns over the 8-h periods for spirometric variables in both O3 exposures were statistically different from air exposure changes and from each other. For FEV1 the p values were 0.017 between air and steady-state profile, 0.002 between air and triangular profile, and 0.037 between steady-state and triangular profiles. Although in the triangular pattern of exposure the maximal O3 concentration was reached at 4 h, the maximum FEV1 decrement (10.2%) was observed at 6 h of exposure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ambient level of NO2 augments the inflammatory response to inhaled allergen in asthmatics

Air pollution constitutes an important factor for asthma aggravation, and there is increased concern about respiratory health effects of common air pollutants. The purpose of this study was to examine how exposure to a high ambient concentration nitrogen dioxide (NO2) prior to a bronchial allergen challenge modulated the inflammatory response in the bronchi. Thirteen subjects with mild asthma and allergy were exposed at rest to either purified air or 500 microg x m 3 NO2 for 30 min, followed 4 h later by an allergen inhalation challenge. The exposures (NO2 or air) were performed in random order and at least 4 weeks apart. Lung function during NO2/air exposure and allergen challenge was measured by plethysmography, and then hourly by portable spirometry after exposures. Subjective symptoms were recorded during and after exposure. Bronchoscopy with bronchial wash (BW) and bronchoalveolar lavage (BAL) was performed 19 h after allergen challenge. NO2+allergen enhanced the percentage of neutrophils in both BW and BAL compared to air+allergen (BW 19 vs. 11, P=0.05; BAL 3 vs. 1, P=0.02 median values).The levels of eosinophil cationic protein (ECP) in BW was higher after NO2+allergen compared to air+allergen (90 vs. 3.6 microg/l; P=0.02, median values). There was no NO2-associated effect on symptoms or pulmonary function. These data suggest that ambient NO2 can enhance allergic inflammatory reaction in the airways without causing symptoms or pulmonary dysfunction.     

Inhalation of 0.30 ppm nitrogen dioxide potentiates exercise-induced bronchospasm in asthmatics

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)     

Respiratory responses of vigorously exercising children to 0.12 ppm ozone exposure

Changes in respiratory function have been suggested for children exposed to less than 0.12 ppm ozone (O3) while engaged in normal activities. Because the results of these studies have been confounded by other variables, such as temperature or the presence of other pollutants or have been questioned as to the adequacy of exposure measurements, we determined the acute response of children exposed to 0.12 ppm O3 in a controlled chamber environment. Twenty-three white males 8 to 11 yr of age were exposed once to clean air and once to 0.12 ppm O3 in random order. Exposures were for 2.5 h and included 2 h of intermittent heavy exercise. Measures of forced expiratory volume in one second (FEV1) and the symptom cough were determined prior to and after each exposure. A significant decline in FEV1 was found after the O3 exposure compared to the air exposure, and it appeared to persist for 16 to 20 h. No significant increase in cough was found due to O3 exposure. Forced vital capacity, specific airways resistance, respiratory frequency, tidal volume, and other symptoms were measured in a secondary exploratory analysis of this study.     

Acute response to 3.0 ppm formaldehyde in exercising healthy nonsmokers and asthmatics

Formaldehyde is an ubiquitous industrial and indoor air pollutant to which millions are daily exposed. Because of the paucity of scientific data concerning the inhalation toxicity of this compound in humans, we determined the symptoms and alterations in pulmonary function resulting from inhalation for 1 h of 3 parts per million formaldehyde in a controlled environmental chamber. The protocol consisted of randomized exposure of each subject to clean air or 3.0 ppm HCHO on 2 separate days. Twenty-two healthy normal subjects engaged in intermittent heavy exercise (VE = 65 L/min) and 16 asthmatic subjects performed intermittent moderate exercise (VE = 37 L/min). Symptoms and pulmonary function were assessed during the time course of exposure; nonspecific airway reactivity was assessed after exposure. Both groups exhibited similar, significant (p less than 0.01) increases in perceived odor, nose/throat irritation, and eye irritation throughout the exposure. The normal group had the following statistically significant (p less than 0.02) lower pulmonary functions after 55 min of exposure to formaldehyde as compared to clean air: 3.8% in FEV1, 2.6% in FVC, and 2.8% in FEV3. The asthmatic group showed no statistically significant decrements in pulmonary function. Five of 38 subjects studied had decrements in FEV1 greater than 10%. In conclusion, acute exposure to 3 ppm HCHO produced: consistent irritant symptoms in both normal and asthmatic subjects, small decreases in pulmonary function in normal subjects engaging in heavy exercise, and clinically significant responses (defined here as decrements in FEU1 greater than 10) in 13% of the study population.(ABSTRACT TRUNCATED AT 250 WORDS)     

Grain dust and lung function. Dose-response relationships.

Grain dust exposure has been associated with both acute and chronic respiratory abnormalities. We sought to answer two questions with regard to this exposure: (1) is there a dose-response relationship between grain dust and respiratory abnormalities, and (2) is there evidence to suggest that the allowable exposure (currently 10 mg/m3 in Canada) be lowered? We compared respiratory symptoms and lung function among 454 grain elevator workers and 55 civic workers to estimates of lifetime average grain dust exposure. A total of 781 personal air samples representing 20 different job titles over a 15-yr period were used to construct a job title-time period matrix for average dust exposure levels. The matrix was applied to each worker's detailed job history to obtain a value for estimated cumulative and average dust exposure. Significant dose-response relationships were seen for chronic phlegm production, breathlessness on exertion, FEV1, and FVC; and dose-response trends were evident for the longitudinal change in both FEV1 and FVC. Workers with estimated average exposure between 4 and 9 mg/m3 were found to have significantly lower values for FEV1 and FVC compared to both grain workers exposed to less than 4 mg/m3 on average and civic workers, despite no difference in duration of employment among these groups. The results indicate a strong dose-response relationship between grain dust exposure and both respiratory symptoms and lung function and also suggest that the current Canadian allowable exposure level of 10 mg/m3 is too high.     

Cotton dust and endotoxin exposure-response relationships in cotton textile workers

Endotoxin exposure has been implicated in the etiology of lung disease in cotton workers. We investigated this potential relationship in 443 cotton workers from 2 factories in Shanghai and 439 control subjects from a nearby silk mill. A respiratory questionnaire was administered and pre- and postshift forced expiratory volume (FVC) and flow in one second (FEV1) were determined for each worker. Multiple area air samples were analyzed for total elutriated dust concentration (range: 0.15 to 2.5 mg/m3) and endotoxin (range: 0.002 to 0.55 microgram U.S. Reference Endotoxin/m3). The cotton worker population was stratified by current and cumulative dust or endotoxin exposure. Groups were compared for FEV1, FVC, FEV1/FVC%, % change in FEV1 over the shift (delta FEV1%), and prevalences of chronic bronchitis and byssinosis, and linear and logistic regression models were constructed. No dose-response relationships were demonstrated comparing dust concentration to any pulmonary function or symptom variable. A dose-response trend was seen with the current endotoxin level and FEV1, delta FEV1%, and the prevalence of byssinosis and chronic bronchitis, except for the highest exposure level group in which a reversal of the trend was seen. The regression coefficients for current endotoxin exposure were significant (p less than 0.05) in the models for FEV1 and chronic bronchitis but not in the models for delta FEV1% (i.e., acute change in FEV1) or byssinosis prevalence. The coefficient for dust level was never significant in the models.(ABSTRACT TRUNCATED AT 250 WORDS)     

Airway inflammation after controlled exposure to diesel exhaust particulates

Epidemiologic evidence suggests a link between morbidity and mortality and levels of particulate matter in the atmosphere. We studied the inflammatory response to inhalation of diesel exhaust particulates (DEP) in normal volunteers. DEP were collected from the exhaust of a stationary diesel engine and were resuspended in an exposure chamber. Ten nonsmoking healthy volunteers were exposed for 2 h at rest to a controlled concentration of DEP (monitored at 200 microg/m(3) particulate matter of less than 10 microm aerodynamic diameter [PM(10)]) or air in a double-blind, randomized, crossover study. Exposures were followed by serial spirometry and measurement of pulse, blood pressure, exhaled carbon monoxide (CO), and methacholine reactivity, as well as sputum induction and venesection for up to 4 h after exposure, and a repeat of all these procedures at 24 h after exposure. There were no changes in cardiovascular parameters or lung function following exposure to DEP. Levels of exhaled CO were increased ater exposure to DEP, and were maximal at 1 h (air: 2.9 +/- 0.2 ppm [mean +/- SEM]; DEP: 4.4 +/- 0.3 ppm; p < 0.001). There was an increase in sputum neutrophils and myeloperoxidase (MPO) at 4 h after DEP exposure as compared with 4 h after air exposure (neutrophils: 41 +/- 4% versus 32 +/- 4%; MPO: 151 ng/ml versus 115 ng/ml, p < 0.01), but no change in concentrations of inflammatory markers in peripheral blood. Exposure to DEPs at high ambient concentrations leads to an airway inflammatory response in normal volunteers.     

The effect of exposure to sulphuric acid on the early asthmatic response to inhaled grass pollen allergen.

Particulate sulphates, including sulphuric acid (H2SO4), are important components of the ambient aerosol in some areas and are regarded as air pollutants with potentially important human health effects. Challenge studies suggest little or no effect of H2SO4 exposure on lung function in asthmatic adults, although some epidemiological studies demonstrate an effect of acid species on symptoms in subjects with asthma. To date, the effect of H2SO4 on allergen responsiveness has not been studied. The effect of exposure to particulate H2SO4 on the early asthmatic response to grass pollen allergen has been investigated in 13 adults with mild asthma. After establishment of the provocative dose of allergen producing a 15% fall in forced expiratory volume in one second (FEVI) (PD15) for each subject, they were exposed to air, 100 microg m(-3) or 1,000 g x m(-3) H2SO4 for 1 h, double-blind in random order > or =2 weeks apart, through a head dome delivery system 14 h after each exposure subject underwent a fixed-dose allergen challenge (PD15). Ten subjects completed the study. The mean early asthmatic responses (maximum percentage change in FEV1 during the first 2 h after challenge) following air, 100 microg x m(-3) H2SO4, and 1,000 microg m(-3) H2SO4, were -14.1%, -16.7%, and -18.4%, respectively. The difference between 1,000 microg x m(-3) H2SO4 and air was significant (mean difference: -4.3%, 95% confidence interval (CI: -1.2-7.4%, p=0.013). The difference between air and 100 microg m(-3) H2SO4 approached significance (mean difference: -2.6%, 95% CI: 0.0-5.3%, p = 0.051). These results suggest that, at least at high mass concentration, sulphuric acid can potentiate the early asthmatic response of mild asthmatic subjects to grass pollen allergen, although the effect is limited.     

Ozone exposure increases respiratory epithelial permeability in humans

Ozone is a respiratory irritant that has been shown to cause an increase in the permeability of the respiratory epithelium in animals. We used inhaled aerosolized 99mTc-labeled diethylene triamine pentacetic acid (99mTc-DTPA) to investigate whether human respiratory epithelial permeability is similarly affected by exposure to ozone. In a randomized, crossover double-blinded study, 8 healthy, nonsmoking young men were exposed for 2 h to purified air and 0.4 ppm ozone while performing intermittent high intensity treadmill exercise (minute ventilation = 66.8 L/min). SRaw and FVC were measured before and at the end of exposures. Seventy-five minutes after the exposures, the pulmonary clearance of 99mTc-DTPA was measured by sequential posterior lung imaging with a computer-assisted gamma camera. Ozone exposure caused respiratory symptoms in all 8 subjects and was associated with a 14 +/- 2.8% (mean +/- SEM) decrement in FVC (p less than 0.001) and a 71 +/- 22% increase in SRaw (p = 0.04). Compared with the air exposure day, 7 of the 8 subjects showed increased 99mTc-DTPA clearance after the ozone exposure, with the mean value increasing from 0.59 +/- 0.08 to 1.75 +/- 0.43%/min (p = 0.03). These data show that ozone exposure sufficient to produce decrements in the pulmonary function of human subjects also causes an increase in 99mTc-DTPA clearance.     

The "effective dose" concept in older adults exposed to ozone

Previous research on young adults has indicated that the magnitude of pulmonary function decrements induced by exposure to ambient ozone (O3) is related to the effective dose of O3 inhaled. The effective dose is defined as the product of O3 concentration (in ppm), mean minute ventilation (VE) and duration of exposure (min). The relative contributions of the three components of effective dose to the development of pulmonary function decrements in older adults are unknown. Twelve healthy, nonsmoking men and women (60-79 years) participated in each of four experiments: (1) a 1-h continuous exercise protocol, and (2) a 2-h intermittent exercise protocol, each performed while exposed to filtered air (FA), and to 0.45 ppm O3, resulting in different effective doses of O3. Pulmonary function (forced vital capacity, FVC, functional residual capacity, FRC, and associated calculated parameters) was measured pre- and postexposure. Ozone exposure induced significant decrements in forced expiratory volume in 0.5, 1.0 and 3.0 seconds (FEV0.5, 1.0, 3.0), regardless of the exercise protocol. There were no changes in FVC with any exposure protocol. There were significant decrements in forced expiratory flow rate at 25% and 50% of FVC (FEF25%, FEF50%) and in forced expiratory flow rate between 25% and 75% of FVC (FEF25-75%) with all four exposures, suggesting a fatigue effect. There were no differences between the decrements induced in FEV1.0 by O3 exposure under the two exercise protocols. The mean exercise VE was 25.3 l/min for the continuous exercise protocol, and was 25.2 l/min for the three exercise periods of the intermittent exercise protocol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nonspecific bronchial hyperresponsiveness to inhaled histamine and hyperventilation of cold dry air in subjects with respiratory symptoms of uncertain etiology

Fifty adult subjects referred to a respiratory function laboratory of a tertiary care hospital for respiratory symptoms of uncertain etiology were investigated prospectively by means of a questionnaire, isocapnic inhalation of dry cold air (-20 degrees C), histamine inhalation tests, monitoring of peak expiratory flow rates, total eosinophil counts, and total IgE. Wheezing, tightness in the chest, dyspnea, and cough were reported by 35, 23, 41, and 30 subjects, respectively. FEV1 values less than 80% pred were found in only 2 subjects. Twenty-nine subjects had a PC20 histamine less than or equal to 16 mg/ml. Twenty, 15, and 10% falls in FEV1 were found in 10, 18, and 26 subjects, respectively, using hyperventilation of cold air. Significant eosinophilia and increased total IgE levels were seen in 5 and 18 subjects, respectively. Eight subjects had daily changes in PEFR greater than 20% on at least 1 day of monitoring. There was no significant association between specific responses to the respiratory questionnaire or the presence of rhinitis on the one hand and bronchial responsiveness to histamine and cold air on the other hand. The 10 subjects who demonstrated a greater than 20% change in FEV1 after cold air inhalation also had a PC20 less than 16 mg/ml, and 5 of them reacted at a concentration less than or equal to 2 mg/ml. Two subjects who had a PC20 less than or equal to 2 mg/ml demonstrated a less than 20% change in FEV1 after inhaling cold air. There was no association between the increase in total eosinophils or IgE and bronchial hyperresponsiveness.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acute exposure to sawdust does not alter airway calibre and responsiveness to histamine in asthmatic subjects

We investigated the effects of particles of sawdust delivered through a special device at known concentrations (close to the threshold limit value-short term exposure limit (TLV-STEL) of 10 mg.m-3) on FEV1 and PC20 in 12 asthmatic subjects free of clinical sensitization to this product. Subjects were studied over two days (day 1: exposure to sawdust; day 2: sham exposure) in random order with a maximum interval of 1 week. On each day, after the assessment of spirometry and PC20, subjects underwent exposure to sawdust or sham exposure. Sawdust was inhaled for a total of 30 min at average concentrations varying from 8.0 to 19.3 mg.m-3 (mean = 11.5 mg.m-3). Twenty-five to 39.7% (mean = 34.6%) of inhaled particles had a diameter less than 10 mu (diameter allowing deposition in the trachea and lower respiratory tract). At the end of each period of exposure, FEV1 was assessed. After recovery, the second PC20 was obtained. Serial measurements of FEV1 were carried out every hour for up to 6 h after the end of exposure. At that time, PC20 was reassessed. Only one subject showed an acute bronchoconstriction immediately after exposure to sawdust (maximum fall of 14% in FEV1) with complete recovery 10 min later. Overall, inhalation of sawdust did not modify PC20 by comparing the mean result of the first test with the second and the third assessments. Also, the mean changes in PC20 at each interval after exposure to sawdust were not significantly different from the variations in PC20 on the sham day.(ABSTRACT TRUNCATED AT 250 WORDS)     

Responses of subjects with chronic obstructive pulmonary disease after exposures to 0.3 ppm ozone

We previously reported (American Review of Respiratory Disease 1982; 125:664-669) that the respiratory mechanics of intermittently exercising persons with chronic obstructive pulmonary disease (COPD) were unaffected by a 2-h exposure to 0.2 ppm ozone. Employing a single-blind, cross-over design protocol, 13 white men with nonreversible COPD (9 current smokers; mean FEV1/FVC, 56%) were randomly exposed on 2 consecutive days for 2 h to air and 0.3 ppm ozone. During exposures, subjects exercised (minute ventilation, 26.4 +/- 3.0 L/min) for 7.5 min every 30 min; ventilation and gas exchange measured during exercise showed no difference between exposure days. Pulmonary function tests (spirometry, body plethysmography) obtained before and after exposures were unchanged on the air day. On the ozone day the mean airway resistance and specific airway resistance showed the largest (25 and 22%) changes (p = 0.086 and 0.058, respectively). Arterial oxygen saturation (SaO2) obtained in 8 subjects during the last exercise interval showed a mean decrement of 0.95% on the ozone exposure day; this change did not attain significance (p = 0.074). Nevertheless, arterial oxygen desaturation may be a true consequence of low-level ozone exposure in this compromised patient group. As normal subjects undergoing exposures to ozone with slightly higher exercise intensities show a threshold for changes in their respiratory mechanics at approximately 0.3 ppm, our data indicate that persons with COPD are not unduly sensitive to the effects of low-level ozone exposure.