Respiratory-tract infection, specifically pneumonia, contributes substantially to the increased morbidity and mortality among elderly individuals exposed to airborne particulate matter of <10 microm diameter (PM(10)). These epidemiological findings suggest that PM(10) may act as an immunosuppressive factor that can undermine normal pulmonary antimicrobial defense mechanisms. To investigate whether, and how, compromised pulmonary immunocompetence might contribute to increased mortality, two sets of laboratory studies were performed. The first examined the effects of a single inhalation exposure to concentrated ambient PM(2.5) (CAPS) from New York City air on pulmonary/systemic immunity and on the susceptibility of exposed aged rats to subsequent infection with Streptococcus pneumoniae. The second set of studies determined whether CAPS exposure, at a concentration approximating or somewhat greater than the promulgated 24-h NAAQS of 65 microg/m(3), could exacerbate an ongoing infection. Taken together, results demonstrated that a single exposure of healthy animals to CAPS had little effect on pulmonary immune function or bacterial clearance during subsequent challenge with S. pneumoniae. Alternatively, CAPS exposure of previously infected rats significantly increased bacterial burdens and decreased percentages of lavageable neutrophils and proinflammatory cytokine levels compared to those in infected filtered-air-exposed controls. These studies demonstrate that a single exposure to ambient PM(2.5) compromises a host's ability to handle ongoing pneumococcal infections and support the epidemiological findings of increased pneumonia-related deaths in ambient PM-exposed elderly individuals.
Epidemiologic studies demonstrate that infection, specifically pneumonia, contributes substantially to the increased morbidity and mortality among elderly individuals following exposure to ambient particulate matter (PM). This laboratory has previously demonstrated that a single inhalation exposure of Streptococcus pneumoniae-infected rats to concentrated ambient PM 2.5 (particulate matter with aerodynamic diameter ≤ 2.5 µm) from New York City (NYC) air exacerbates the infection process and alters pulmonary and systemic immunity. Although these results provide some basis for explaining the epidemiologic findings, the identity of specific PM constituents that might have been responsible for the worsening pneumonia in exposed hosts remains unclear. Thus, studies were performed to correlate the physicochemical attributes of ambient PM 2.5 with its in vivo immunotoxicity to identify and characterize the role of constitutive transition metals in exacerbating an ongoing streptococcal infection. Uninfected or previously infected rats were exposed in the laboratory to soluble divalent Fe, Mn, or Ni chloride salts. After exposure, uninfected rats were sacrificed and their lungs were lavaged. Lungs from infected hosts were used to evaluate changes in bacterial clearance and effects of exposure on the extent/severity of infection. Results demonstrated that inhalation of Fe altered innate and adaptive immunity in uninfected hosts, and both Fe and Ni reduced pulmonary bacterial clearance in previously infected rats. The effects on clearance produced in infected Fe-exposed rats were similar to those seen in infected rats exposed to ambient NYC PM. Taken together, these studies demonstrate that inhaled ambient PM can worsen the outcome of an ongoing pulmonary infection and that associated Fe may play some role in the immunotoxicity.
Epidemiology studies suggest that exposure to air pollution increases the frequency of cardiac arrhythmias. A limitation of these studies is that it is difficult to link an increased risk of arrhythmias to a specific air pollutant. Animal exposure studies offer the opportunity to examine the effects of concentrated ambient fine particulate matter (PM), ultrafine PM, and copollutant gases separately. Male Fischer 344 rats, aged 18 mo, with implanted electrocardiograph (ECG) transmitters were used to determine the effects of PM on the frequency of arrhythmias. We found that old F344 rats had many spontaneous arrhythmias. An arrhythmia classification system was developed to quantify arrhythmia frequency. Arrhythmias were broadly grouped into two categories: premature beats and delayed beats. The rats were exposed to concentrated ambient PM (CAPS) or air for 4 h. The rats were exposed twice with a crossover design so each rat could serve as its own control. The CAPS concentrations were 160 microg/m(3) and 200 microg/m(3) for the first and second exposures, respectively. There was a significant increase in the frequency of irregular and delayed beats after exposure to CAPS. The same rats were subsequently exposed to laboratory-generated ultrafine carbon particles, to SO(2), or to air with a repeated crossover design. In these experiments there was no significant change in the frequency of any category of spontaneous arrhythmia following exposure to ultrafine carbon or SO(2). Thus, this study adds supporting evidence that acute exposure to elevated levels of ambient PM increases the frequency of cardiac arrhythmias.
Time-series studies have shown that the lag time between elevated particulate air pollution (PM) and increases in cardiovascular-related hospital admissions and death is very short 1 d or less. If PM does cause serious cardiovascular effects shortly after exposure, one would expect to see some physiological change during exposure. In this study, spontaneously hypertensive rats (SHRs) with surgically implanted blood pressure transmitters were exposed to concentrated ambient PM (CAPS) for 4 h to determine whether CAPS inhalation causes immediate effects. The rats were also exposed to sulfuric acid aerosols because acid is one of the components of PM that could potentially activate irritant receptors and cause effects during exposure. Exposure to CAPS caused a striking decrease in respiratory rate that was apparent soon after the start of exposure and stopped when exposure to CAPS ceased. The decrease in respiratory rate was accompanied by a decrease in heart rate. Exposure of the same rats to fine-particle-size sulfuric acid aerosol also caused a significant decrease in respiratory rate similar to the effects of CAPS. Ultrafine acid had the opposite effect on respiratory rate compared to CAPS. Because acids have been shown to evoke sensory irritant responses in rodents, the similarity between the effects of fine acid aerosol and CAPS suggests that CAPS activates airway-irritant receptors during exposure.
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