Ozone-induced decrements in FEV1 and FVC do not correlate with measures of inflammation.

Balmes, John R.; Chen, Lisa L.; Scannell, Cornelius; Tager, Ira B.; Christian, Dorothy; Hearne, Patrick Q.; Kelly, Thomas J.; Aris, Robert M.

doi:10.1164/ajrccm.153.3.8630571

Cited by 147 publications

(120 citation statements)

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“…Toxicity of O 3 to epithelial surfaces is primarily attributed to reactive oxygen species and ozonation of unsaturated fatty acids present in lung lining fluids (29). Early (3-h) and late (18-to 20-h) responses in the human after whole lung exposure to O 3 include an influx of protein, inflammatory cells, and mediators into airway and alveolar surface fluids (2,4,35). The presence of these cellular and biochemical markers of injury at the epithelial surface and the increased diffusivity of small molecules within the submucosa postexposure (14) have led to speculation that exposure to O 3 modulates bronchial smooth muscle tone and responsiveness to nonspecific challenge (24).…”

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confidence: 99%

Bronchial reactivity of healthy subjects: 18–20 h postexposure to ozone

Foster

Brown

Macri

et al. 2000

Journal of Applied Physiology

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Exposure of humans to ambient levels of ozone (O3) causes inflammatory changes within lung tissues. These changes have been reported for the “initial” (1- to 3-h) and “late” (18- to 20-h) postexposure periods. We hypothesized that at the late period, when protein and cellular markers of inflammation at the airway surface remain abnormal and the integrity of the epithelial barrier is compromised, bronchial reactivity would be increased. To test this, we measured airway responsiveness to cumulative doses of methacholine (MCh) aerosol in healthy subjects 19 ± 1 h after a single exposure to O3 (130 min at ambient levels between 120 and 240 parts/billion and alternate periods of rest and moderate exercise) or filtered air. Exposures were conducted at two temperatures: mild (22°C) and moderate (30°C). At the late period, bronchial reactivity to MCh increased, i.e., interpolated dose of MCh leading to a 50% fall in specific airway conductance (PC50) was less after O3 than after filtered air. PC50 for O3 at 22°C was 27 mg/ml (20% less than the PC50 after filtered air), and for O3 at 30°C it was 19 mg/ml (70% less than the PC50 after filtered air). The forced expiratory volume in 1 s (FEV1) at the late time point after O3 was slightly but significantly reduced (2.3%) from the preexposure level. There was no relationship found between the functional changes observed early after exposure to O3 and subsequent changes in bronchial reactivity or FEV1 at the late time point. These results suggest that bronchial reactivity is significantly altered ∼1 day after O3; this injury may contribute to the respiratory morbidity that is observed 1–2 days after an episode of ambient air pollution.

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confidence: 99%

Bronchial reactivity of healthy subjects: 18–20 h postexposure to ozone

Foster

Brown

Macri

et al. 2000

Journal of Applied Physiology

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“…Care must be taken during the procedure to avoid prolonged balloon inflation, as some subjects may experience significantly decreased arterial oxygen tension during occlusion of the airway. The technique has been used successfully in both healthy volunteers and subjects with mild asthma (35). A modification of this technique has been used to study the effects of 03 exposure in healthy and asthmatic subjects (36).…”

Section: Experimental Design and Methodsmentioning

confidence: 99%

“…For example, retention of insoluble 2 pm particles was increased 50% in subjects with COPD compared with healthy subjects, and the increased deposition correlated with the severity of obstruction (87). The (19,35). Furthermore, the mechanisms by which pollutant exposure contributes to respiratory mortality may differ from those responsible for excess cardiovascular mortality.…”

Section: Studying Susceptible Subjectsmentioning

confidence: 99%

Toxicologic methods: controlled human exposures.

Utell

Frampton

2000

Environ Health Perspect

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The assessment of risk from exposure to environmental air pollutants is complex, and involves the disciplines of epidemiology, animal toxicology, and human inhalation studies. Controlled, quantitative studies of exposed humans help determine health-related effects that result from breathing the atmosphere. The major unique feature of the clinical study is the ability to select, control, and quantify pollutant exposures of subjects of known clinical status, and determine their effects under ideal experimental conditions. The choice of outcomes to be assessed in human clinical studies can be guided by both scientific and practical considerations, but the diversity of human responses and responsiveness must be considered. Subjects considered to be among the most susceptible include those with asthma, chronic obstructive lung disease, and cardiovascular disease. New experimental approaches include exposures to concentrated ambient air particles, diesel engine exhaust, combustion products from smoking machines, and experimental model particles. Future investigations of the health effects of air pollution will benefit from collaborative efforts among the disciplines of epidemiology, animal toxicology, and human clinical studies.

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“…NO2 also has acute effects, but only at levels exceeding 2.0-4.0 ppm (1). The effects include decrements in forced expiratory volume in 1 sec (FEVI) and forced vital capacity, cough and chest discomfort, lung injury and inflammation, and changes in airway responsiveness (5)(6)(7)(8). Changes in pulmonary function have also been observed in children at summer camp and athletes exposed to ambient air pollution during outside activities (6,9).…”

mentioning

confidence: 99%

“…Airway hyperreactivity persists after 03-induced changes in FEV, resolve and the degree of reactivity is not associated with the magnitude of spirometric changes, suggesting an independent mechanism for hyperreactivity (14 respiratory diseases including asthma and chronic obstructive pulmonary disease (COPD). The inflammatory response involves increased numbers of macrophages, neutrophil infiltration, increased cellular protein permeability following the production of a broad range of inflammatory cytokines, and increased arachidonic acid metabolites (8,(15)(16)(17)(18). In addition to the inflammatory response, a large body of evidence suggests that acute NO2 exposure at environmental levels may adversely affect other aspects of immune function including macrophage function, resulting in decreased airway clearance and increased risk of infection.…”

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confidence: 99%

A theoretical basis for investigating ambient air pollution and children's respiratory health.

Gilliland

McConnell

Peters

et al. 1999

Environ Health Perspect

100

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Acute respiratory health effects in children from exposure at current ambient levels of ozone are well documented; however, evidence for acute effects from other criteria pollutants such as nitrogen dioxide and respirable particles is inconsistent. Whether chronic effects result from long-term exposure to any of these pollutants during childhood is an important unresolved question. Establishing whether acute or chronic effects result from childhood exposure and identifying sensitive subgroups may require integration of biologic mechanisms of lung defenses, injury, and response into the study design and statistical models used in analyses. This review explores the theoretical basis for explaining such adverse effects in light of our contemporary understanding of mechanisms of lung injury and response at the cellular and molecular levels. The rapidly evolving understanding of the effects of air pollution on cellular and molecular levels presents an opportunity to develop and refine innovative biologically based hypotheses about the effects of childhood exposure. We hypothesize that children with low fruit and vegetable intake, low antioxidant levels, high polyunsaturated fat intake, or who have inherited certain alleles for genes involved in lung defenses and immune response regulation may be at increased risk for adverse effects. Because responses to air pollutants of interest are complex and involve a number of pathophysiologic processes, the magnitude of main effects of dietary factors, genes, and gene-environment interactions may be modest for individuals; however, each may make an important contribution to the population burden of preventable respiratory diseases.

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Ozone-induced decrements in FEV1 and FVC do not correlate with measures of inflammation.

Cited by 147 publications

References 0 publications

Bronchial reactivity of healthy subjects: 18–20 h postexposure to ozone

Bronchial reactivity of healthy subjects: 18–20 h postexposure to ozone

Toxicologic methods: controlled human exposures.

A theoretical basis for investigating ambient air pollution and children's respiratory health.

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