Hypoxemia lowers cerebrovascular resistance without changing brain and blood [H+]

Abstract

We designed the present study to see whether during acute moderate isocapnic hypoxemia, changes in cerebral vascular resistance (CVR) and brain extracellular fluid (ECF) [H+] can or cannot be dissociated from each other. In seven anesthetized and paralyzed dogs we measured brain ECF pH with surface electrodes (n = 4) or double-barreled microelectrodes (n = 3) with tip diameters of < 30 .mu.m inserted 5 mm below the surface. Cerebral blood flow (CBF) was measured by radioactive microspheres during normoxemia and moderate hypoxemia, whereas brain ECF pH was measured continuously. In six of the seven dogs brain pH did not change during moderate hypoxemia of 4-20 min duration. In these six animals the mean arterial O2 partial pressure decreased from 84.8 .+-. 12.9 (SD) to 46.7 .+-. 10.2 Torr during hypoxic gas breathing, resulting in a significant drop in CVR from 3.88 .+-. 1.88 to 3.27 .+-. 1.97 Torr .cntdot. ml-1 .cntdot. 100 g and a rise in CBF from 31.7 .+-. 12.7 to 47.8 .+-. 31.5 ml .cntdot. min-1 .cntdot. 100 g-1. The mean brain ECF [H+] was 57.4 .+-. 8.2 nmol/l (pH = 7.24) during normoxemia and did not change significantly during hypoxic gas breathing [56.6 .+-. 7.7 nmol/l (pH = 7.25)]. Furthermore, arterial and sagittal venous blood and cisternal cerebrospinal fluid (CSF) pH did not change significantly during hypoxic gas breathing. We conclude that during acute moderate hypoxemia reduction in CVR can occur independently from increases in brain ECF, cisternal CSF, and arterial and sagittal venous blood [H+] and PCO2.