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Pulmonary Inflammatory Response (pulmonary + inflammatory_response)

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Medical Sciences75%

Selected Abstracts

Acute and Chronic Alcohol Exposure Impair the Phagocytosis of Apoptotic Cells and Enhance the Pulmonary Inflammatory Response

ALCOHOLISM, Issue 10 2010
Darren M. Boé
Background:, Alcohol abuse increases the risk for acute respiratory distress syndrome (ARDS). Efferocytosis, the clearance of apoptotic cells, is important in the resolution of inflammation and is regulated by RhoA and rho kinase (ROCK) activation. The effects of alcohol on pulmonary Rho pathway activation and efferocytosis have not been determined. We hypothesize that acute and chronic alcohol exposure impair pulmonary efferocytosis, leading to heightened inflammation during ARDS. Methods:, For in vivo experiments, C57BL/6 mice received either a single intraperitoneal injection of alcohol or chronic ethanol-in-water for 8 weeks prior to intratracheal instillation of apoptotic cells or lipopolysaccharide (LPS). Bronchoalveolar lavage (BAL) was performed for cells counts, calculation of the phagocytic index (PI), and Rho activity measurements. For in vitro studies, primary alveolar macrophages were cultured in alcohol (25,100 mM) and then co-cultured with apoptotic cells. RhoA activity was determined following alcohol exposure, and the PI was determined before and after treatment with the ROCK inhibitor, Y27632. Results:, Acute alcohol exposure was associated with impaired efferocytosis. Following LPS exposure, acute alcohol exposure was also associated with increased BAL neutrophils. Chronic alcohol exposure alone did not alter efferocytosis. However, following exposure to LPS, chronic alcohol exposure was associated with both impaired efferocytosis and increased BAL neutrophils. In vitro alcohol exposure caused a dose-dependent decrease in efferocytosis. Despite the fact that RhoA activity was decreased by alcohol exposure and RhoA inhibition did not alter the effects of alcohol on efferocytosis, treatment with the Rho kinase inhibitor, Y27632, reversed the effects of alcohol on efferocytosis. Conclusions:, Acute alcohol exposure impairs pulmonary efferocytosis, whereas exposure to chronic alcohol is only associated with impaired efferocytosis following LPS-induced lung injury. Both forms of alcohol exposure are associated with increased alveolar neutrophil numbers in response to LPS. The acute effects of alcohol on efferocytosis appear to be mediated, at least in part, by RhoA-independent activation of ROCK. Further studies are needed to dissect the differences between the effects of acute and chronic alcohol exposure on efferocytosis and to determine the effects of alcohol on alternative activators of ROCK. [source]

Meconium aspiration syndrome: a role for phospholipase A2 in the pathogenesis?

ACTA PAEDIATRICA, Issue 4 2001
P KääpäArticle first published online: 2 JAN 200
The pathophysiology of neonatal meconium aspiration syndrome (MAS), often resulting in severe respiratory failure, is complex and still largely unclear. Factors involved in the propagation of acute lung injury after perinatal aspiration of meconium include obstruction of the airways, ventilation/perfusion mismatch, increase of the pulmonary vascular resistance and a rapidly developing parenchymal and alveolar inflammatory reaction with associated surfactant dysfunction. Conclusion: Although the early pulmonary inflammatory response is believed to play a central pathogenetic role in the meconium-induced acute lung damage, its initiating mechanisms are still poorly defined. However, increasing evidence indicates a direct toxic effect of meconium. [source]

Respiratory hypersensitivity to trimellitic anhydride in Brown Norway Rats: a comparison of endpoints

JOURNAL OF APPLIED TOXICOLOGY, Issue 2 2002
Jürgen Pauluhn
Abstract A rat bioassay has been developed to provide an objective approach for the identification and classification of respiratory allergy using trimellitic anhydride (TMA), which is a known respiratory tract irritant and asthmagen. Particular emphasis was placed on the study of route-of-induction-dependent effects and their progression upon inhalation challenge with TMA (,23 mg m,3 for a duration of 30 min), which included analysis of specific and non-specific airway hyperreactivity and pulmonary inflammation initiated and sustained by immunological processes. Refinement of the bioassay focused on procedures to probe changes occurring upon challenge with TMA or methacholine aerosols using physiological, biochemical and immunological procedures. Following challenge with TMA, the rats sensitized to TMA showed marked changes in peak inspiratory and expiratory air flows and respiratory minute volume. In these animals, a sustained pulmonary inflammation occurred, characterized by specific endpoints determined in bronchoalveolar lavage (lactate dehydrogenase, protein, nitrite, eosinophil peroxidase, myeloperoxidase). When compared with the naive controls, lung weights were increased significantly, as were the weights of lung-associated lymph nodes following inhalation induction and auricular lymph nodes following topical induction. The extent of changes observed was equal or more pronounced in animals sensitized epicutaneously (day 0 : 150 µl vehicle/50% TMA on each flank, day 7; booster administration to the skin of the dorsum of both ears using half the concentration and volume used on day 0) when compared with rats sensitized by 5 × 3 h day,1 inhalation exposures (low dose: 25 mg TMA m,3, high dose: 120 mg TMA m,3). In summary, the findings support the conclusion that the Brown Norway rat model is suitable for identifying TMA as an agent that causes both an immediate-type change of breathing patterns and a delayed-type sustained pulmonary inflammatory response. However, it remains unresolved whether the marked effects observed in the topically sensitized rats are more related to a route-of-induction or dose-dependent phenomenon. Copyright © 2002 John Wiley & Sons, Ltd. [source]

Effects of meconium aspiration in isolated perfused rat lungs

PEDIATRIC PULMONOLOGY, Issue 4 2005
Wlodzimierz M. Wisniewski MD
Abstract Our objective was to study meconium-induced lung injury in isolated perfused rat lungs exposed to anoxia. Our working hypothesis was that meconium-induced lung injury is independent of preexisting hypoxia, and that hypoxia will increase severity of lung injury observed after meconium aspiration. We comparde five different groups of animals (n,=,5) for pulmonary arterial pressure (PAP), weight lung changes, and TNF, expression. Group I had lungs instilled with 4 ml of normal saline. Group II had lungs exposed to 5 min of anoxia. Group III had lungs instilled with 4 ml of 30% filtered human meconium. Group IV had lungs exposed to 5 min of anoxia and then instilled with 4 ml of 30% filtered human meconium. Group V had lungs instilled with 4 ml of 30% unfiltered human meconium. Our subjects were adult Sprague-Dawley rats. The isolated rat lung model was prepared according to Levey and Gast (J Appl Physiol 1966;21:313,316). Lungs were ventilated with room air. Anoxia was caused by the use of N2. The pulmonary artery was cannulated, and pulmonary arterial pressure and lung weight were measured. Lung weight and pulmonary arterial pressure were monitored for 120 min, and TNF, levels were measured in effluent at 15, 30, 60, and 120 min. Experiments were done at the Michael Reese Hospital (Chicago, IL). At the end of the experiment, PAP reached its highest values in group V (10.0,±,1.7 mmHg). Final PAPs in groups I,IV were: 4.85,±,0.3, 4.99,±,0.4, 5.93,±,0.3, and 7.25,±,0.51 mmHg, respectively). Lung wet weight increased significantly only in groups IV and V vs. group I; at 120 min, they were: 0.96,±,0.3 g, P,<,0.01, and 1.5 g,±,0.2 g, P,<,0.01, respectively. TNF, levels did not change significantly over time in group I. TNF, is a marker as well as proprietor of pulmonary inflammatory response. TNF, reached its highest levels in groups IV and V: 595 and 753 pg/ml at 120 min, respectively. In conclusion, a short episode of anoxia prior to meconium aspiration may increase lung sensitivity to meconium-induced lung injury. This effect may be moderated by the TNF, present in the pulmonary circulation. Pediatr Pulmonol. 2005; 39:368,373. © 2005 Wiley-Liss, Inc. [source]