A dangerous liaison: Spreading depolarization and tissue acidification in cerebral ischemia.

Abstract

Brain pH is precisely regulated, and pH transients associated with activity are rapidly restored under physiological conditions. During ischemia, the brain's ability to buffer pH changes is rapidly depleted. Tissue oxygen deprivation causes a shift from aerobic to anaerobic metabolism and the accumulation of lactic acid and protons. Although the degree of tissue acidosis resulting from ischemia depends on the severity of the ischemia, spreading depolarization (SD) events emerge as central elements to determining ischemic tissue acidosis. A marked decrease in tissue pH during cerebral ischemia may exacerbate neuronal injury, which has become known as acidotoxicity, in analogy to excitotoxicity. The cellular pathways underlying acidotoxicity have recently been described in increasing detail. The molecular structure of acid or base carriers and acidosis-activated ion channels, the precise (dys)homeostatic conditions under which they are activated, and their possible role in severe ischemia have been addressed. The expanded understanding of acidotoxic mechanisms now provides an opportunity to reevaluate the contexts that lead to acidotoxic injury. Here, we review the specific cellular pathways of acidotoxicity and demonstrate that SD plays a central role in activating the molecular machinery leading to acid-induced damage. We propose that SD is a key contributor to acidotoxic injury in cerebral ischemia.