Hemolysate Inhibits Cerebral Artery Relaxation

Abstract

In helical strips of dog middle cerebral arteries partially contracted with prostaglandin (PG) F_2α, relaxations induced by angiotensin-II, possibly mediated by PGI₂, and those induced by PGH₂were reversed to a contraction or markedly reduced by treatment with hemolysate, which, however, attenuated the PGI₂-induced relaxation only slightly. The relaxant response of human middle cerebral arterial strips to PGH₂was also suppressed by hemolysate. Dog and monkey middle cerebral arteries responded to transmural electrical stimulation and nicotine with transient relaxations, which were quite susceptible to tetrodotoxin and hexamethonium, respectively; the relaxations were abolished almost completely by hemolysate and methylene blue. On the other hand, the relaxant response of dog cerebral arteries to a low concentration of K⁺was not influenced by hemolysate or by methylene blue, but was reversed to a contraction by treatment with ouabain. Relaxations induced by substance-P and nitroglycerin were markedly inhibited by hemolysate; removal of endothelium abolished the relaxation by substance-P, but did not influence the nitroglycerin-induced relaxation. Hemolysate may interfere with the biosynthesis of PGI₂in the vascular wall, thereby reversing the relaxation induced by angiotensin-II and PGH₂to a contraction. Relaxations induced by electrical and chemical stimulation of vasodilator nerves innervating cerebral arteries appear to be elicited by a mechanism dependent on cellular cyclic guanosine monophosphate (GMP), like that underlying the substance-P-induced and nitroglycerin-induced relaxation. These actions of hemolysate may be involved in the genesis of cerebral vasospasm after subarachnoid hemorrhage.