Three-dimensional reconstruction of alveoli in the rat lung for pressure-volume relationships

Abstract

To determine alveolar pressure-volume relationships, alveolar three-dimensional reconstructions were prepared from lungs fixed by vascular perfusion at various points on the pressure-volume curve. Lungs from male Sprague-Dawley rats were fixed by perfusion through the pulmonary artery following a pressure-volume maneuver to the desired pressure point on either the inflation or deflation curve. Tissue samples from lungs were serially sectioned for determination of the volume fraction of alveoli and alveolar ducts and reconstruction of alveoli. Alveoli from lungs fixed at 5 cmH2O on the deflation curve (approximating functional residual volume) had a volume of 173 .times. 103 .mu.m3, a surface area of 11,529 .mu.m2, a mouth opening diameter of 72.7 .mu.m, and a mean caliper diameter of 91.8 .mu.m (SE). Alveolar shape changes during deflation from total lung capacity to residual volume was first (30 to 10 cmH2O) associated with little change in the diameter of the alveoli (102.7 .+-. 2.4 to 100.3 .+-. 3.3 .mu.m). In the range overlapping normal breathing (10 to 0 cmH2O) there was a substantial decrease in diameter (100.3 .+-. 3.3 to 43.3 .+-. 2.3 .mu.m). These measurements and others made on the relative changes in the dimensions of the alveolus suggest that the elastic network, particularly around the alveolar ducts, are predominant in determining lung behavior near the volume expansion limits of the lung while the elastic and surface tension properties of the alveoli are predominant in the volume range around functional residual capacity.