Transepithelial sodium and water transport in the lung. Major player and novel therapeutic target in pulmonary edema.

Details

Serval ID
serval:BIB_878F016F9977
Type
Article: article from journal or magazin.
Publication sub-type
Review (review): journal as complete as possible of one specific subject, written based on exhaustive analyses from published work.
Collection
Publications
Institution
Title
Transepithelial sodium and water transport in the lung. Major player and novel therapeutic target in pulmonary edema.
Journal
Advances in Experimental Medicine and Biology
Author(s)
Sartori C., Matthay M.A., Scherrer U.
ISSN
0065-2598
Publication state
Published
Issued date
2001
Peer-reviewed
Oui
Volume
502
Pages
315-338
Language
english
Notes
Publication types: Journal Article ; Review
Abstract
Active transepithelial transport of sodium from the airspaces to the lung interstitium is a primary mechanism driving alveolar fluid clearance. This mechanism depends on sodium uptake by amiloride-sensitive sodium channels on the apical membrane of alveolar type II cells followed by extrusion of sodium on the basolateral surface by the Na-K-ATPase. Injury to the alveolar epithelium can disrupt the integrity of the alveolar barrier or downregulate ion transport pathways thus reducing net alveolar fluid reabsorption, and enhancing the extent of alveolar edema. Endogenous catecholamines upregulate alveolar fluid clearance in several experimental models of acute lung injury, but this upregulation is short-term and often not sufficient to counterbalance alveolar flooding. There is new evidence, however, that pharmacological treatment with beta-adrenergic agonists and/or epithelial growth factors may induce a more sustained stimulation of alveolar fluid reabsorption and in turn facilitate recovery from experimental pulmonary edema. Similar results have been achieved experimentally by gene transfer enhancing the abundance of sodium transporters in the alveolar epithelium. Clinical studies show that impaired alveolar fluid transport mechanisms contribute to the development, severity and outcome of pulmonary edema in humans. Very recent data suggest that mechanisms that augment transepithelial sodium transport and enhance the clearance of alveolar edema may lead to more effective prevention or treatment for pulmonary edema and acute lung injury.
Keywords
Animals, Aquaporins/physiology, Humans, Lung/metabolism, Pulmonary Alveoli/metabolism, Pulmonary Edema/metabolism, Pulmonary Edema/physiopathology, Respiratory Distress Syndrome, Adult/metabolism, Respiratory Mucosa/metabolism, Sodium/metabolism, Sodium Channels/physiology, Water/metabolism
Pubmed
Web of science
Create date
22/02/2008 15:02
Last modification date
20/08/2019 14:46
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