We assessed transmurally the coronary autoregulatory response to elevated perfusion pressure in 85 anesthetized, open-chest dogs. Steady state and transient flow distributions were measured with 9 ± 1 /im radioactive microspheres. Steady state distributions of myocardial blood flow were uniform transmurally(P >0.05) at perfusion pressures of 103 ± 1 (n= 81) and 146 ± 2 (n= 34) mm Hg, whereas Endo:Epi ratios of 1.26 ± 0.05 and 1.51 ± 0.07 at perfusion pressures of 194 ± 1(n= 60) and 221 ± 3 (n= 14) mm Hg, respectively, indicated progressive redistribution(P <0.05) of flow toward subendocardium. As perfusion pressure was increased, autoregulation failed first in subendo-cardium. At high perfusion pressures, subendocardial flow exceeded subepicardial flow (P< 0.05) whether or not subepicardial flow was autoregulated. The initial, transient response to elevation of coronary perfusion pressure from 99 ± 1 to 145 ± 2 (n= 5) mm Hg was an increase (P< 0.05) in Endo: Epi ratio from 1.05 ± 0.06 to 1.30 ± 0.06. By 2 minutes this ratio had returned to near control. In contrast, the initial Endo:Epi ratio of 1.32 ± 0.05 caused by elevation of perfusion pressure to 190 ± 5 (n= 6) mm Hg did not wane (P> 0.05). A selective increase in subendocardial oxygen demand could not explain greater subendocardial flow since (1) elevated perfusion pressure had no effect on aortic and left ventricular pressures, cardiac output, and heart rate, (2) left ventricular oxygen consumption was constant in the presence of preferential subendocardial perfusion, (3) regional myocardial oxygen tension increased in parallel with blood flow to subepicardium and subendocardium. Also, elevated perfusion pressure caused a greater steady state increase in subendocardial flow in four empty, nonworking hearts. The results demonstrate transmural variation in coronary autoregulatory poten-tial; the subepicardial vasculature appears better adapted to autoregulate blood flow at elevated perfusion pressures.Circ Res 47: 599-609, 1980