DISPERSION OF AEROSOL BOLUSES IN THE HUMAN LUNG - DEPENDENCE ON LUNG-VOLUME, BOLUS VOLUME, AND GENDER

The dispersion of aerosol boluses in the human lungs has been studied in health and disease, usually as a means of investigating convective mixing. However, there are limited data on the roles of critical facto rs, such as the volume of inhaled boluses, lung inflation, and gender on dispersion. To examine these factors, we measured the difference in volume variance between exhaled and inhaled boluses (sigma(V)(2)) of a 0.5-mu m aerosol in 11 healthy male and 12 healthy female subjects a s a function of tidal volume (V-T = 1,000 and 1,500 ml in females and 1,000 and 2,000 ml in males), bolus penetration volume ((V) over bar(i ) at 250-ml increments over each V-T), and bolus volume (target V-Bol = 75, 150, and 300 ml). Analysis of variance showed marginally signifi cant gender effects (P = 0.073) on sigma(V)(2), with sigma(V)(2) great er in males than in females. There was also a significant effect of V- Bol,1 on sigma(V)(2) (P < 0.001). A (V) over bar(i)-dependent mean vol ume shift between inhaled and exhaled boluses (Delta (V) over bar) was observed at all (V) over bar i except 500 ml. The observation of gend er and V-Bol effects and the existence of a nonzero Delta (V) over bar suggest that convective mixing mechanisms other than longitudinal dis persion alone occur in the healthy lung. The lack of V-T dependence su ggests a minimal role of lung inflation above functional residual capa city on dispersion. The dependence of sigma(V)(2) on (V) over bar(i)(2 ) up to 1,750 ml and minimal V-Bol effects demonstrates that convectiv e mixing processes continue far into the gas exchange regions of the l ung and support a significant role for axial streaming.