Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UMLS:C0034069 (
pulmonary fibrosis
)
7,050
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Multiple reactive oxygen species-induced epithelial injury by glucose,
glucose oxidase
, and lactoperoxidase instillation in the lung results in a progressive interstitial fibrosis. To test the hypothesis that multiple pulmonary inflammatory responses alone would not result in fibrosis, three sequential inflammatory reactions were produced at weekly intervals in hamster lungs via intratracheal instillation of human recombinant C5a. Numbers of neutrophils and total inflammatory cells in bronchoalveolar lavage (BALF) increased significantly at 24 h after each C5a treatment compared with saline controls. Neutrophils increased by 3-, 33-, and 34-fold compared with the corresponding controls at 24 h after the first, second, and third doses, respectively, but returned to control levels by six days postinstillation. LTB4 levels increased by 24% and 20% compared with the corresponding controls at 24 h after the first and second doses but were not different from controls at other times. Hydroxyproline levels in treated animals did not differ significantly from control levels throughout the study. Protein levels were significantly increased at 24 h after the second and third doses and six days after the third dose compared with the corresponding controls. Occasional foci of neutrophils in alveolar spaces were observed at 24 h after each dose, but they decreased in frequency after six days. No foci of neutrophils were observed six days after the final dose, although some epithelial degeneration was observed by transmission electron microscopy. Our results indicate that pulmonary inflammation resulting from repeated influx of neutrophils in response to multiple instillations of C5a in the lung does not cause sufficient injury to result in
pulmonary fibrosis
.
...
PMID:Repeated episodes of C5a-induced neutrophil influx do not result in pulmonary fibrosis. 165 81
Oxidant-mediated epithelial injury and repair processes may promote the development of
pulmonary fibrosis
. The authors examined this hypothesis by inducing oxidant injury in hamsters with intratracheally instilled mixtures of glucose,
glucose oxidase
(GO) and lactoperoxidase at weekly intervals. Solutions containing denatured GO (DE) served as a control treatment. One and six days after each treatment, anesthetized animals were sacrificed and lavaged, and their lungs and plasma were preserved for further study. Although DE-treatment consistently evoked a transient, neutrophil-rich inflammatory response, no significant biochemical or morphologic changes were detected at the ensuing 6-day time points. In contrast, repeated GO treatments prolonged inflammation and injured the alveolar epithelium, evidenced by significantly greater levels of neutrophils and macrophages in bronchoalveolar lavage fluid (BALF) and increased BALF levels of protein, beta-glucuronidase and lactic dehydrogenase activities. Active GO also altered BALF lymphocytes and monocytes, but no discernable pattern emerged. Fibrotic, consolidated parenchyma appeared after the second and third GO exposures, coinciding with increased levels of total collagen, prolyl hydroxylase activity, and anti-oxidant enzyme activities. Although alveolitis and type II cell hyperplasia were observed after the initial treatment, polyplike nodules covered by hyperplastic, undifferentiated epithelium were evident after the third treatment. After each exposure, GO-treated animals had larger volumes of parenchymal lesion than DE-treated hamsters. These data indicate that normal alveolar epithelial repair processes were greatly disrupted by repeated oxidant injury and suggest that repeated and/or continued epithelial injury may contribute to the development of
pulmonary fibrosis
.
...
PMID:Repeated exposures to enzyme-generated oxidants cause alveolitis, epithelial hyperplasia, and fibrosis in hamsters. 175 May 14
Reactive oxygen species (ROS) have been closely associated with a number of pathological disorders, including interstitial
pulmonary fibrosis
. While models of ROS-induced fibrosis offer advantages over chemically-induced fibrosis, the biochemical and morphological features of ROS-induced fibrosis have yet to be extensively documented. In this study, we evaluated the effect of initial ROS dose on lung injury and repair. Male hamsters received a single dose of glucose,
glucose oxidase
and lactoperoxidase via the intratracheal route. From 3 to 14 days post-treatment, a significant dose-related body weight loss was observed. There was a trend towards greater mortality with increasing dose. After 2 weeks, we noted significant, dose-related increases in lung levels of collagen, lipid peroxidation products, nucleic acids, and protein. Similarly, total lung catalase, lactic dehydrogenase and glutathione reductase activities were also elevated significantly above control values in a dose-related fashion. A concurrent, dose-dependent thickening of alveolar septa in ROS-treated lungs was composed of epithelial hyperplasia, hyperemia, edema and accumulations of interstitial fibers and macrophages. Interstitial and alveolar macrophages in ROS-induced lesions were enlarged and contained numerous primary and secondary lysosomes. These results demonstrate that, in the hamster lung, injury induced by enzyme-generated ROS can initiate dose-dependent fibroproliferative changes which eventuate into interstitial fibrosis.
...
PMID:Dose-related effects of enzyme-generated oxidants on the biochemistry and morphology of the hamster lung. 267 4
The intrapulmonary instillation into rat lung of enzymes that generate oxygen metabolites results in acute lung injury. The injection of xanthine oxidase and xanthine produces acute lung injury that, in the presence of superoxide dismutase, but not in the presence of catalase, can be significantly diminished, suggesting that O2- has the capacity to injure the lung. Instillation of a generator of H2O2, namely
glucose oxidase
, will, in sufficient quantities, produce acute injury that is not neutrophil-dependent. When either a low dose of
glucose oxidase
alone or lactoperoxidase alone is employed, little lung injury occurs. However, instilling the combination of the two enzymes produces severe, acute injury that can be blocked in a dose-dependent manner by catalase, but not by superoxide dismutase. Purified human leukocytic myeloperoxidase, but not horseradish peroxidase, will substitute for lactoperoxidase in the model of lung injury. The lung damaging effects of these enzymes cannot be attributed to the presence of contaminating proteases. Acute lung injury produced by the instillation of
glucose oxidase
and lactoperioxidase progresses to interstitial fibrosis. These studies represent a direct application of generators of oxygen metabolites to the in vivo induction of lung injury. The data suggest that rat lung is susceptible to injury by a variety of oxygen metabolites, including O2-, H2O2 and its lactoperoxidase or myeloperoxidase-produced derivatives. The studies also indicate that lung injury produced by oxygen metabolites can result in interstitial
pulmonary fibrosis
.
...
PMID:In vivo damage of rat lungs by oxygen metabolites. 689 54
