Stroke, Vol 19, 447-454, Copyright © 1988 by American Heart Association
JC Grotta, LC Pettigrew, D Rosenbaum, C Reid, H Rhoades and D McCandless
Dihydropyridine calcium channel blockers such as nicardipine are under
evaluation for treating acute cerebral ischemia because they may increase
cerebral blood flow by causing vasodilation and because they may be
cytoprotective in part by limiting production of arachidonic acid
metabolites. We demonstrated in a previous study that nicardipine improves
postischemic neuronal function, as measured by somatosensory evoked
potentials, without reducing the extent of light-microscopic CA- 1
hippocampal histologic damage. To characterize further the effect of
nicardipine on global ischemic injury, we administered the drug beginning
24 hours before 30 minutes of four-vessel ischemia in Wistar rats. We then
measured hippocampal ATP, phosphocreatine, and glucose contents immediately
and 2 hours after ischemia, and measured learning ability (working and
reference errors) on an eight-arm radial maze beginning 30 days after
ischemia. To gain insight into the possible mechanism of action, we
measured production of arachidonic acid metabolites (eicosanoids: TXB2 and
6-keto-PGF1 alpha) and hemispheric and hippocampal cerebral blood flow by
the [14C]butanol indicator fractionation technique immediately and 2 hours
after ischemia. Nicardipine was associated with fewer working errors (p
less than 0.02) but no difference in reference errors. The drug had no
effect on energy metabolites, cerebral blood flow, or eicosanoids
immediately after ischemia, but ATP, phosphocreatine, and cerebral blood
flow all returned to normal levels significantly more rapidly during
reperfusion in treated rats. Nicardipine improves behavioral,
electrophysiologic, and mitochondrial function after ischemia without
preventing cellular damage and improves postischemic reperfusion. The
drug's positive effect appears to occur during reperfusion.
ARTICLES
Efficacy and mechanism of action of a calcium channel blocker after global cerebral ischemia in rats
Department of Neurology, University of Texas Health Science Center, Houston 77030.
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