Reduced Surface Tension Normalizes Static Lung Mechanics in a Rodent Chronic Heart Failure Model

Autor:	Sandra Orgeig, Carmine G. De Pasquale, Sonja Klebe, Dani-Louise Dixon, Andrew D. Bersten, Hilde Rosa De Smet
Přispěvatelé:	Dixon, Dani-Louise, De Pasquale, Carmine G, De Smet, Hilde R, Klebe, Sonja, Orgeig, Sandra, Bersten, Andrew D
Rok vydání:	2009
Předmět:	Male Pulmonary and Respiratory Medicine Pulmonary Circulation medicine.medical_specialty Pulmonary Surfactant-Associated Proteins Heart disease surfactant medicine.medical_treatment Critical Care and Intensive Care Medicine Rats Sprague-Dawley Pulmonary surfactant Internal medicine Intensive care medicine Animals Surface Tension Myocardial infarction Lung Saline Heart Failure lung morphology business.industry Airway Resistance Microcirculation Organ Size respiratory system pulmonary microvascular pressure medicine.disease Pulmonary edema Rats Surgery Disease Models Animal medicine.anatomical_structure Heart failure Chronic Disease Respiratory Mechanics alveolar type II cells Cardiology Vascular Resistance business
Zdroj:	Flinders University PURE
ISSN:	1535-4970 1073-449X
Popis:	Rationale: Chronic elevation of pulmonary microvascular pressure in chronic heart failure results in compensatory changes in the lung that reduce alveolar fluid filtration and protect against pulmonary microvascular rupture. Objectives: To determine whether these compensatory responses may have maladaptive effects on lung function. Methods: Six weeks after myocardial infarction (chronic heart failure model) rat lung composition, both gross and histologic; air and saline mechanics; surfactant production; and immunological mediators were examined. Measurements and Main Results: An increase in dry lung weight, due to increased insoluble protein, lipid and cellular infiltrate, without pulmonary edema was found. Despite this, both forced impedance and air pressure–volume mechanics were normal. However, there was increased tissue stiffness in the absence of surface tension (saline pressure–volume curve) with a concurrent increase in both surfactant content and alveolar type II cell numbers, suggesting a novel homeostatic phenomenon. Conclusions: These studies suggest a compensatory reduction in pulmonary surface tension that attenuates the effect of lung parenchymal remodeling on lung mechanics, hence work of breathing. Refereed/Peer-reviewed
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::b40758de41c2c04349df64bba50bb287 https://doi.org/10.1164/rccm.200809-1506oc Zobrazit plný text záznamu