Single-breath diffusing capacity of the lung for carbon monoxide (DLCO) increases as lung volume increases above functional residual capacity (FRC). However, the physiological mechanism responsible for this increase remains controversial. This volume dependence of diffusing capacity could reflect changing regional distribution of inspired air as lung volume increases rather than a change in capillary blood volume or surface area for gas exchange. We measured DLCO during breath holding and during rebreathing with a technique employed to mix respired gases throughout the lung thereby minimizing regional distribution differences. Measurements were made 1,500 ml above FRC and near total lung capacity (TLC). Breath holding DLCO was 18% higher near TLC than at 1,500 ml above FRC (P less than 0.05). Rebreathing DLCO was 16% higher near TCL than at 1,500 ml above FRC (P less than 0.01). Equality of results by the two techniques indicates that changes in DLCO with lung volume are not a consequence of the changing distribution of inspired air. Our results are compatible with the hypothesis that effective surface area of the lung increases as lung volume expands.
The diffusing capacity of the lung for carbon monoxide (DLCO) varies directly with lung volume (VA) when measured during a breath-holding interval. DLCO measured during a slow exhalation from total lung capacity (TLC) to functional residual capacity (FRC) does not vary as VA changes. Since VA is reached by inhaling during breath holding and by exhaling during the slow exhalation maneuver, we hypothesized that the variability in the relation between DLCO and VA was due to hysteresis. To test this hypothesis, breath-holding measurements of DLCO were made at three lung volumes, both when VA was reached by inhaling from residual volume (RV) and when Va was reached by exhaling from TLC. At 72% TLC, DLCO was 22% higher when VA was reached by exhalation compared to inhalation (P < 0.02). At 52% TLC, DLCO was 19% higher when VA was reached by exhalation compared to exhalation (P < 0.005). DCLO measured during a slow exhalation fell on the exhalation limb of the CLCO/VA curve. these data indicate that there is hysteresis in DLCO with respect to lung volume.
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