MJ Hazucha, LJ Folinsbee, E Seal and PA Bromberg
Department of Medicine, School of Medicine, University of North Carolina, Chapel Hill 27599-7310.

Since NOx emissions bear a precursor-product relation with ambient ozone (O3) levels, the sequence of peak ambient concentrations is first nitrogen dioxide (NO2) followed later in the day by ozone (O3). We ascertained whether preliminary exposure to 0.6 parts per million (ppm) NO2 would affect the lung function response to subsequent exposure to 0.3 ppm O3. Twenty-one healthy young nonsmoking women (18 to 35 yr of age) underwent two sets of exposures on two different days separated by a minimum of 2 wk. On one day, subjects were exposed to air for 2 h followed 3 h later by a 2-h exposure to O3. On the other day, the first exposure was to NO2; order of the days was randomized. During each exposure subjects intermittently exercised, alternating 15 min of rest with 15 min of exercise (Ve approximately 40 L/min). Spirometry was performed before the first exposure and at 1-h intervals until the end of the 2-h (O3) exposure. Plethysmography measurements were made before and after NO2 and O3 exposures. Nonspecific airway reactivity (AR) was determined at least 1 wk prior to the first exposure and following each O3 exposure. AR to methacholine (MCh) was expressed as dose required to decrease FEV1 by 10% (PD10FEV1). Nitrogen dioxide exposure alone did not reduce FEV1 but did significantly enhance O3-induced spirometric changes. No significant effects were observed in plethysmography. On both exposure days, the median PD10FEV1 was significantly reduced (p < 0.05) from control PD10FEV1 (14.3 mg/ml).(ABSTRACT TRUNCATED AT 250 WORDS)