Characterizing the Effect of the Hypoxic Vasoconstriction Response Curve on Blood Flow Distribution and Oxygenation in the Lung

Abstract

The ability of the lung to take up oxygen can be characterized by its effective diffusing capacity, which is determined by the transport characteristics of the alveolar‐capillary membrane as well as heterogeneity of pulmonary blood flow. At rest, the healthy lung has a high degree of tolerance for pulmonary flow heterogeneity, but under conditions of physiological stress such as exercise, oxygen uptake may be inadequate to satisfy tissue demand if flow is very heterogeneous. We previously used a mathematical model of pulmonary oxygen uptake to examine the ability of hypoxic pulmonary vasoconstriction (HPV) to mitigate flow heterogeneity. In the model, flow heterogeneity is characterized by the coefficient of variation (CV) of pulmonary capillary blood flow. Assuming an initial lognormal distribution of blood flow with a normal level of heterogeneity (CV = 1.66), we simulate flow regulation over a range of oxygen consumption from rest to maximal exercise by adjusting pulmonary flow resistance in each vessel in accordance with an HPV response curve obtained from previously published experimental data. The effect of HPV on vessel flow resistance is assumed to be characterized by a sigmoidal response dependent on the capillary oxygen tension, which is approximated as the mean of the venous and arterial values in each pulmonary capillary; its maximal sensitivity occurs at a stimulus oxygen tension of approximately 30 torr. The purpose of the present study was to determine whether altering the shape of the HPV response curve would result in an improvement in CV reduction. Altering the HPV by shifting the sigmoidal curve to the right by 10 or 20 torr worsened CV, extraction and total pulmonary vascular resistance (PVR). Similar detrimental results were obtained when the range of oxygen tensions over which HPV varied was expanded by a factor of two, increasing the oxygen tension at which the sensitivity of HPV to oxygen tension was maximal. On the other hand, shrinking the range of variation of the HPV curve by a factor of two neither improved nor significantly worsened the CV or extraction, and resulted in a PVR distribution similar to the case of the normal HPV curve. These results demonstrate that the observed shape of the HPV response tends to minimize heterogeneity of pulmonary flow under conditions of exercise.Support or Funding InformationSupported by NIH U01 HL133362.