Induction Of Pulmonary Inflammation Research Articles

Association of mononuclear cells and eosinophils with airway resistance and responsiveness in rat pulmonary inflammatory responses

To evaluate the association of various leukocytes with pulmonary resistance and methacholine responsiveness, we induced pulmonary eosinophil-rich inflammation in IgE-sensitized (ovalbumin) Sprague Dawley rats. Sensitized rats were challenged with either relevant (OA) or irrelevant antigen by tracheal insufflation a) with no other treatment, b) in conjunction with intravenous Sephadex beads pretreatment, or c) with antigen coupled covalently to Sepharose beads. About 24 h after antigen challenge, respiratory system resistance (Rrs), response to aerosolized methacholine, and pulmonary histopathology were evaluated. Challenge with OA, insufflation with Sepharose, and treatment with i.v. Sephadex all independently increased inflammatory cell infiltrates, but the combination of OA with the other agents did not significantly enhance the inflammatory response over OA alone. Interactive stepwise regression techniques were utilized to identify correlates for Rrs and methacholine responsiveness. Mononuclear cell score was a significant predictor (p < .01) for Rrs, and insufflation of Sepharose had a significant independent effect on Rrs (p = .01) above that predicted by mononuclear cell infiltrates. Conversely, eosinophil score and neutrophil score were not significant predictors for Rrs, and challenges with antigen or Sephadex had no significant independent effect on Rrs beyond that predicted from mononuclear cell infiltrates. Eosinophil score was the only significant histological predictor for methacholine responsiveness (p < .0001). Challenges with Sephadex, antigen and Sepharose did not significantly change methacholine responsiveness independently of the changes associated with eosinophil infiltrates. These findings suggest that mononuclear cells and eosinophils contribute to increases in airway resistance and responsiveness, respectively, following the induction of pulmonary inflammation by both allergic and non-allergic stimuli.

Induction of pulmonary inflammation by components of the pneumococcal cell surface.

Using a rabbit model of experimental pneumonitis, the components on the surface of the pneumococcus that incite pulmonary inflammation were identified. Rabbits were challenged intratracheally with live pneumococci, capsular polysaccharide, purified cell walls, or cell wall subcomponents. Leukocytosis and elevation of protein concentration was quantitated in bronchial lavage fluid during the first 24 h after challenge. Of the pneumococcal surface components tested, cell wall preparations had the highest specific activity in inducing inflammation; abnormalities in bronchial lavage fluid cytochemistry appeared rapidly and in a dose-dependent manner. Cell wall building blocks and the products of penicillin-induced hydrolysis of the cell wall were also highly inflammatory, indicating that inflammation can be generated by disruption of the cell wall during lysis of bacteria by beta-lactam antibiotics. Administration of inhibitors of arachidonic acid metabolism suggested that inhibition of the lipoxygenase pathway reduced inflammation associated with cell walls. We propose that pulmonary inflammation during pneumococcal pneumonia arises in large part from the interaction of the bacterial cell wall with complement and noncomplement-mediated host defenses.