Hypoxic vasoconstriction in pulmonary arterioles and venules.

Pulmonary microvessels (<70 microm) lack a complete muscular media. We tested the hypothesis that these thin-walled vessels do not participate in the hypoxic pressor response. Isolated canine lobes were pump perfused at precisely known microvascular pressures. A videomicroscope, coupled to a computerized image-enhancement system, permitted accurate diameter measurements of subpleural arterioles and venules, with each vessel serving as its own control. While vascular pressure was maintained constant throughout the protocol, hypoxia caused an average reduction of 25% of microvessel diameters. The constriction was reversed when nitric oxide was added to the hypoxic gas mixture. The nitric oxide reversal, combined with a lack of lobar blood flow redistribution as measured by fluorescent microspheres, shows that the constriction was active. This response suggests the unexpected potential for active intra-acinar ventilation-perfusion matching.

Effect of capillary pressure and lung distension on capillary recruitment.

To investigate the effect of capillary pressure and alveolar distension on capillary recruitment, we used video-microscopy to quantify capillary recruitment in individual subpleural alveolar walls. Canine lobes were perfused with autologous blood either while inflated by positive airway pressure or while inflated by negative intrapleural pressure in the intact thorax with airway pressure remaining atmospheric. Low flow rates minimized the arteriovenous pressure gradient (< 5 mmHg), permitting capillary pressure estimation by averaging these pressures. Capillary pressure was varied stepwise from airway pressure to 30 mmHg above airway pressure. Capillary recruitment always began as capillary pressure exceeded airway pressure. At low positive airway pressures, the capillaries of the excised lobes opened suddenly over a narrow pressure range. AT higher airway pressures and in the intact thorax, recruitment occurred over a wide range of capillary pressures. We conclude that capillary perfusion begins when intracapillary pressure just exceeds alveolar pressure but that further increases in capillary pressure recruit capillaries depending on tension in the alveolar wall, whether imposed by positive airway pressure or by gravity when the lung is suspended in an intact thorax.

Distribution of pulmonary capillary red blood cell transit times.

In theory, red blood cells can pass through the pulmonary capillaries too rapidly to be completely saturated with oxygen during exercise. This idea has not been directly tested because the transit times of the fastest red blood cells are unknown. We report the first measurements of the entire transit time distribution for red blood cells crossing single subpleural capillary networks of canine lung using in vivo fluorescence videomicroscopy and compare those times with the distribution of plasma transit times in the same capillary networks. On average, plasma took 1.4 times longer than red blood cells to pass through the capillary bed. Decreased transit times with increased cardiac output were mitigated by both capillary recruitment and a narrowing of the transit time distribution. This design feature of the pulmonary capillary bed kept the shortest times from falling below the theoretical minimum time for complete oxygenation.

Sites of leukocyte sequestration in the pulmonary microcirculation.

The location and mechanisms of leukocyte sequestration in the pulmonary circulation have been investigated by using high-magnification in vivo videomicroscopy to record the passage of unlabeled native leukocytes through canine pulmonary capillaries. Of 650 leukocytes traversing capillary networks, 46 +/- 6% (SE) of the leukocytes passed through without stopping, 42 +/- 9% stopped in segments between junctions, and 12 +/- 4% stopped in junctions. Leukocytes rolling along arteriolar walls were nearly spherical, as 94% had aspect ratios (major axis divided by minor axis) < or = 1.25. To pass through the capillary bed, the leukocytes deformed into elongated shapes. Many leukocytes remained elongated after entering the venules (53% had aspect ratios > or = 1.25). Venular rolling was blocked by fucoidin (blocking both L- and P-selectin) but not by anti-P-selectin antibodies alone, indicating that rolling leukocytes adhered to the venular endothelium by L-selectin. These observations demonstrate that leukocytes deform to transit the capillary bed, that they stop more frequently in segments than in junctions, and that rolling leukocytes in the venular marginated pool adhere via L-selectin.

Stability of alveolar capillary opening pressures.

Little is known about the stability of the process by which pulmonary capillaries open. To investigate this process, pulmonary capillary perfusion patterns in isolated pump-perfused canine lobes were studied using video microscopy. After pump flow was set to perfuse one-half of the capillaries, the pump was turned off and all of the capillaries emptied. Turning the pump back on reopened the capillaries. The on-off cycle was repeated six times. If the same capillaries were perfused during each observation, it would demonstrate that there were stable and significant differences between individual capillary opening pressures, causing consistent recruitment of those capillaries with the lowest opening pressures. Alternatively, variable perfusion patterns would result if capillary opening pressures changed between observations, if the differences in opening pressures between capillary segments were negligible, or if experimental conditions changed between cycles. The perfusion pattern was more reproducible than expected by chance alone, which indicated the existence of stable differences among alveolar capillary opening pressures.

Effect of increasing flow on distribution of pulmonary capillary transit times.

The complex morphology of the pulmonary capillary network causes capillary transit times to be dispersed about a mean. It is known that flow-induced decreases in mean capillary transit time are partially offset by capillary recruitment and distension, but the effect of these factors on the rest of the distribution of transit times is unknown. We have studied the relationship between blood flow, capillary recruitment, and the distribution of transit times in isolated canine lungs with videomicroscopy. Doubling baseline lobar blood flow recruited capillaries. All transit times in the distribution decreased, as did relative dispersion. Doubling flow again caused a further decrease in transit times, but neither capillary recruitment nor relative dispersion changed significantly. We conclude that capillary transit times become more homogeneous as lobar flow increases from low to intermediate levels. Further increases in flow across a fully recruited network are associated with decreases in transit times but not with more homogeneous capillary perfusion.

Temporal capillary perfusion patterns in single alveolar walls of intact dogs.

Pulmonary gas exchange reserve in the form of recruitable capillaries was first described in the 1930s, when in vivo microscopy was used to demonstrate that not all capillaries were perfused during basal conditions and that perfusion of individual capillaries varied over time. These important observations have never been directly confirmed, nor have the hemodynamic causes of the variation been investigated. We used videomicroscopy to record nine consecutive pulmonary capillary perfusion patterns during a 40-min period. Confirming the original work, we found considerable perfusion variation in about one-half of the capillaries. These variations did not correlate with changes in pulmonary arterial pressures or cardiac outputs, suggesting that factors more subtle than large-vessel hemodynamics affected capillary perfusion consistency. In contrast to this variable group, one-half of the capillary segments were consistently perfused during at least eight of the nine observations and were interconnected to form preferential pathways across the alveolar wall.

Direct measurement of pulmonary microvascular distensibility.

Pulmonary vascular distensibility has an important influence on pulmonary hemodynamics. Although many measurements of distensibility have been made on large pulmonary vessels, there is less information on microvascular distensibility. We have measured the distensibility of the smallest (< 70-microns-diam) precapillary arterioles and postcapillary venules. Isolated dog lobes, at 2.5 cmH2O transpulmonary pressure, were perfused at low flows, which caused the arteriovenous pressure gradient to be very small and thereby permitted accurate estimation of microvascular pressure. As microvascular pressure was systematically varied between 0 and 30 mmHg, subpleural microvascular diameters were determined from computer-enhanced images obtained by videomicroscopy. Arteriolar and venular distensibilities were not different from each other. The microvascular pressure-diameter relationship was alinear with distensibility coefficients of 1-3% mmHg-1, values that are of the same order of magnitude as previously measured distensibilities of 100- to 1,000-microns-diam canine pulmonary vessels.

Capillary perfusion patterns in single alveolar walls.

We studied capillary perfusion patterns in single alveolar walls through a transparent thoracic window implanted in pentobarbital-anesthetized dogs. The capillaries were maximally opened by brief inflation of a balloon in the left atrium to raise pressure. After the balloon was deflated and pulmonary hemodynamics returned to zone 2 baseline conditions, the capillaries that remained perfused in the observed field were videotaped with the use of in vivo microscopy. The cycle of elevated pressure and baseline observation was repeated three times. Perfusion of different capillaries during each of the observations would imply that the capillaries had characteristics that permitted flow to switch between segments. Perfusion of a specific set of pathways through the network each time would demonstrate that flowing blood sought a unique and repeatable combination of segments, presumably with the least total pathway resistance. We found that the same capillary segments were perfused 79% of the time, a strong indication that a reproducible combination of individual segmental resistances determined the predominant pattern of pulmonary capillary perfusion.