Positron emission tomography was used to measure alveolar gas volume, pulmonary blood volume (VB), regional alveolar ventilation (VA), and the regional ventilation-to-perfusion ratio (VA/Q) in a transaxial slice at midheart level in eight supine subjects and one prone normal subject during quiet breathing. These relationships allow regional blood flow (Q) to be calculated as VA/(VA/Q). No significant differences between right and left lung were found. Within the volume studied, which excluded the peripheral 2 cm of the lung, there was an exponential increase in Q by 11%/cm from 1.2 ml.min-1.cm-3 in the upper (ventral) to 3.5 ml.min-1.cm-3 in the lower (dorsal) lung regions, explaining 61% of the total variation within groups, whereas the horizontal gradient only explained 7% (right lung; supine subjects). Similar gravitational gradients were found in the single prone subject. VA and Q were well matched except at the dorsal lung thoracic border where low values of VA/Q due to a reduction in ventilation were occasionally found even in these normal subjects. VB and Q were reasonably well matched, implying that variations in vascular transit time due to gravity are kept to a minimum. The coefficient of local variation of peripheral vascular transit times (VB/Q) (33%) was, therefore, less than would have been expected if VB and Q were uncorrelated (57%).