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Pulmonary Inflammatory and Immunological Responses to Airborne Pathogens: A Review

  • L. Bruce Weekley
  • Gerald C. Llewellyn
Part of the Biodeterioration Research book series (BIOR, volume 3)

Abstract

Influenza and the associated pneumonia is the sixth leading cause of death in the United States. The economic cost in terms of medical dollars and work loss is about $5 billion a year. Deterioration of air quality in the workplace may be caused by microbiological or particulate pollution and such pollution may impair pulmonary defenses sufficiently to enhance the susceptibility to airborne infections such as influenza. Tobacco smoke has been implicated as a disease causing agent even in individuals exposed to second-hand smoke. Ventilation systems in buildings have been implicated in transmission of infectious disease including tuberculosis, measles, smallpox and staphylococcus infections. Carpeting, humidifiers, and flush toilets can harbor bacteria, pollen, fungi, and other allergens. A number of viruses with varying degrees of epidemiologic and pathologic significance may be aerosolized, contribute to air quality deterioration, and cause respiratory disease (Table 1). Influenza viruses are prone to antigenic drift and consequently humoral immunity from previous infections is often only partially effective at preventing disease. The rationale behind vaccinating with a killed or modified live virus vaccine (or prior clinical or subclinical disease) is to stimulate the production of antibodies to certain epitopes on the viral surface. These epitopes are in constant contact with the host blood antibodies and hence are subject to a great deal of selective pressure. This selective pressure tends to favor the emergence of new viral epitopes and hence loss of disease resistance.

Keywords

Functional Residual Capacity Mucociliary Clearance Respiratory Bronchiole Live Virus Vaccine Malignant Catarrhal Fever 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

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Copyright information

© Springer Science+Business Media New York 1990

Authors and Affiliations

  • L. Bruce Weekley
    • 1
  • Gerald C. Llewellyn
    • 1
  1. 1.Bureau of Toxic SubstancesVirginia Department of HealthRichmondUSA

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