The kinetics of extracellular potassium changes during hypoxia and anoxia in the cat cerebral cortex.

Extracellular potassium activity, [K+]0, was continuously measured using potassium specific microelectrodes in the cerebral cortex of cats before and after hypoxic or anoxic insults. Two patterns of [K+]0 increase were seen. A slow, linear rise occurred during hypoxia and hypothermia and was correlated with changes in mean blood pressure (B/P). A fast, complex, exponential rise resembling spreading depression occurred during anoxia and was unassociated with B/P changes. The fall of [K+]0 after reversal of the insult was described by a single exponential function with rate constants from 0.009 to 0.0194 sec-1. It is suggested that the linear rise is primarily a result of sodium pump inhibition and that the exponential rise is due to a superimposed sudden increase in cell membrane permeability perhaps secondary to transmitter release. The kinetics of the fall of [K+[0 is consistent with the normalization of the sodium and potassium gradients across the cell membranes secondary to Na+-K+ATPase activity.