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Allergy. 1997;52(38 Suppl):45-51; discussion
57-8. |
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Mechanisms of pollution-induced airway
disease: in vitro studies in the upper and lower airways
Devalia JL,
Bayram H,
Rusznak C,
Calderon M,
Sapsford RJ,
Abdelaziz MA,
Wang J,
Davies RJ.
Academic Department of Respiratory Medicine, St Bartholomew's
and the Royal-London School of Medicine and Dentistry, London
Chest Hospital, UK.
Evidence from both epidemiological and laboratory-based studies
suggests that increased exposure to liquid petroleum and
gas-derived air pollutants [nitrogen dioxide (NO2), ozone, and
respirable particulate matter] may play a role in the clinical
manifestation of both allergic and non-allergic airway disease.
The mechanisms and cell types involved in pollutant-mediated
effects in the airways, however, are not clear. In vitro studies
have suggested that human fibroblasts, B-lymphocytes, alveolar
macrophages, and epithelial cells/cell lines may be involved.
Studies of fibroblasts and macrophages have demonstrated that
exposure to ozone results in decreased cell viability and
increased release of pro-inflammatory mediators from
macrophages. Similarly, studies of B-lymphocytes have
demonstrated that exposure to diesel exhaust particles (DEP)
enhances the synthesis of immunoglobulin E by these cells. The
airway epithelial cells have received the greatest attention in
mechanistic studies of air pollution-induced airway disease and
suggest that these cells are likely to play a pivotal role in
the pathogenesis of airways disease. Various studies have
demonstrated that exposure of nasal or bronchial epithelial
cells to NO2, ozone, and DEP results in significant synthesis
and release of pro-inflammatory mediators, including eicosanoids,
cytokines, and adhesion molecules. Additionally, evidence
suggests that epithelial cells of atopic individuals release
significantly greater amounts of cytokines such as
granulocyte-macrophage colony stimulating factor (GM-CSF),
interleukin-6 (IL-6), IL-8, and regulated on activation, normal
T-cell expressed and secreted (RANTES), on exposure to NO2 and
ozone. Studies investigating the biological relevance of
epithelial cell-derived pro-inflammatory mediators have shown
that these enhance eosinophil chemotaxis and eosinophil
adherence to endothelial cells, suggesting that
pollution-induced inflammation of the airways is likely to be
influenced by modulation of epithelial synthesis and release of
these mediators.
Publication Types:
PMID: 9208059 [PubMed - indexed for MEDLINE]
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