Mechanisms of Cerebrovascular O2 Sensitivity from Hyperoxia to Moderate Hypoxia in the Rat

Abstract

Cerebrovascular dilation over P_aO₂ ranging from hyperoxia to moderate hypoxia is unexplained. We hypothesize that tissue acidosis is the cause. Local cortical cerebral blood flow (LCBF), tissue hydrogen ion concentration [H⁺]_t, and tissue Po₂ (P_to₂) were measured with microelectrodes in the parietal cortex of 18 rats during a 30-min steady state on 60 to 10% inspired O₂ (P_ao₂, 300 to 40 torr) during 40% N₂O analgesia. Five rats kept on 60% O₂/40% N₂O served as controls. In 18 rats at a P_ao₂ of 275 ± 7 torr (X̄ ± SEM) and P_aco₂ of 35 ±1 torr, cerebral values were: LCBF = 129 ± 23 (X̄ ± SEM) ml · 100 g⁻¹ · min⁻¹; [H⁺], = 62 ± 6 n M; and P_to₂ = 25 ± 3 torr. As P_ao₂ was reduced from about 300 to 40 torr, changes in these variables in percentage of control with respect to P_ao₂, were described by the following equations, all at P < 0.0001: LCBF = 85.9 + 5,572/P_ao₂; [H⁺]_t = 97.15 + 1,012/P_ao₂; and = 108.8 − 3,492/P_ao₂. Simultaneous solution of the LCBF and [H⁺]_t equations at various P_ao₂ revealed a slope of 8.82%/n M. Direct correlation between LCBF in ml · 100 g⁻¹ · min⁻¹ and [H⁺]_t in n M revealed a linear relationship defined by the equation Y = − 7.472 + 1.6705 X ( r = 0.6426) for [H⁺]_t between 56 and 160 n M (pH = 7.25 and 6.80) but no correlation at [H⁺]_t values between 56 and 32 n M (pH = 7.25 to 7.50). Cerebrovascular tone is directly correlated with [H⁺]_t during progressive, 30-min steady-state reduction in P_ao₂ from 350 to 40 torr.