Induction of acute pulmonary edema in anesthetized dogs causes a large fall in compliance. out of proportion to lung volume (1), and a sharp increase in venous admixture that can be reversed by forcible inflation of the lungs (2). This pattern of abnormal function suggested alveolar closure (1, 2).Since alveolar stability depends in large measure on the presence of normal pulmonary surface properties (3), altered surface forces were consiclered as an underlying mechanism. Cook and co-workers (1) reasoned that the decrease in alv'eolar diameter, resulting from the accumulation of intra-alveolar fluid, would account for an increase in total surface forces. We examined the possibility that pulmonary edema alters alveolar surface tension properties, in this way contributing to alveolar instability and to the failure of respiratory function. It can 1)e shown that for alveoli, as for spherical surfaces, total surface forces equal twice the surface tension divided by the radius of curvature (4).We induced pulmonary edema in anesthetized dogs by rapid intravenous infusion of dextran. Surface activity of lung extracts was measured and correlated with morphologic changes. There was a regional loss or impairment of surface activity in the edematous lung, associated with areas * Submitted for publication October 14, 1964; accepted November 27, 1964. Presented in part at the 47th Annual Meeting of the American Physiological Society, April 15, 1963, Atlantic City, N. J., and abstracted in Fed. Proc. 1963, 22, 339. Supported by U. S. Public Health Service research grant HE-04226 and by a research grant from the American Heart Association.
MethodsProccdnarc. The experiments were conducted on 24 mongrel dogs weighing 7 to 33 kg. The dogs were tracheostomized and anesthetized with 30 mg per kg pentobarbital intravenously. They were supine and breathed spontaneously or with the assistance of a Starling respirator, set to deliver ventilation in the normal tidal range. To duplicate the conditions of an earlier study of gas exchange in pulmonary edema (2), we gave the animals 100% oxygen to breathe before the induction of pulmonary edema; the total period of oxygen breathing was generally 1 to 2 hours and did not exceed 5 hours. Pulmonary edema was induced by intravenous infusion of 6%o dextran solution in saline, at the rate of approximately 4 ml per kg per minute. The infusion was maintained until foam came out of the trachea. The animals were then killed with magnesium sulfate.Post-mortem, the lungs were weighed separately and their gross morphologic features noted. In every case, one sample was taken from a dark, depressed part of the lung and another from a pink, relatively unaltered part. The samples were examined for surface activity, as detailed below. In seven instances, portions of these samples were also fixed in Bouin's solution and stained with hematoxylin and eosin, toluidine blue, and with periodic acid Schiff reagent for microscopic examination.In ten experiments, a thoracotomy was performed, and the airway t...
