2-Thiazolylethylamine, a selective histamine H1 agonist, decreases seizure susceptibility in mice.

The effects of intracerebroventricular (ICV) administration of histamine and its selective agonists on electrically and pentylenetetrazole-induced convulsions in mice were studied. The ICV administration of histamine decreased seizure susceptibility on electrically and pentylenetetrazole-induced convulsions significantly and dose-dependently. The inhibitory effects of histamine were well antagonized by centrally acting histamine H1 antagonists such as pyrilamine (or mepyramine) and ketotifen, but not by a peripherally acting histamine H1 antagonist, astemizole, or a centrally acting H2 antagonist, zolantidine. The ICV administration of 2-thiazolylethylamine, a selective histamine H1 agonist, also decreased seizure susceptibility, which could be antagonized by centrally acting histamine H1 antagonists, whereas dimaprit, a selective histamine H2 agonist, did not affect seizure susceptibility. These findings strengthened the idea that the central histaminergic neuron system plays an inhibitory role in convulsions.

In vitro cardiac pharmacology of the new histamine H2-receptor agonist amthamine: comparisons with histamine and dimaprit.

The cardiac activity of the novel histamine H2-receptor agonist amthamine was investigated in a variety of isolated heart preparations from guinea pigs and humans and in the isolated rabbit aorta. Amthamine caused an increase in the sinus rate of spontaneously beating guinea-pig atria (pD2 = 6.72) and in the contractility of the electrically driven guinea-pig papillary muscle (pD2 = 6.17) and of the human atrium (pD2 = 5.38). In all these systems, amthamine behaved as a full agonist with a potency comparable to or slightly higher than that of histamine and 10 times higher than that of dimaprit. The positive effects of amthamine were competitively antagonized by ranitidine which had pA2 values (6.46 and 6.25 in the guinea-pig atria and papillary muscle, respectively) comparable with those calculated against histamine and dimaprit. In the isolated rabbit aorta amthamine was devoid of H1-mediated activities up to 3 x 10(-4) M. These results indicate that amthamine is a potent and selective histamine H2-receptor agonist which can be considered a valuable tool for investigating H2-receptor mediated effects in cardiac tissues.

Prejunctional inhibition of sympathetically evoked pupillary dilation in cats by activation of histamine H3 receptors.

Frequency-dependent pupillary dilations were evoked by electrical stimulation of the pre- or post-ganglionic cervical sympathetic nerve (sympatho-excitation) or the hypothalamus (parasympatho-inhibition) in sympathectomized anesthetized cats. Systemic administration of the selective histamine H3 receptor agonist (R)-alpha-methylhistamine (R alpha MeHA) produced a dose-dependent depression of mydriasis due to direct neural sympathetic activation but had no effect on responses elicited by parasympathetic withdrawal. The histamine H2 receptor agonist, dimaprit, was inactive. R alpha MeHA was much more effective in depressing sympathetic responses obtained at lower frequencies when compared to higher frequencies of stimulation. Responses evoked both pre- and postganglionically were inhibited by R alpha MeHA. This peripheral sympatho-inhibitory action of R alpha MeHA was antagonized by the histamine H3 receptor blocker thioperamide but not by intravenous pretreatment with the histamine H1 receptor antagonist chlorpheniramine. Histamine H2 receptor blockers cimetidine and ranitidine were also without effect. R alpha MeHA did not depress pupillary responses elicited by i.v. (-)-adrenaline. The results demonstrate that histamine H3 receptors modulate sympathetic activation of the iris at a site proximal to the iris dilator muscle. The predominant mechanism of action appears to the prejunctional inhibition of noradrenaline release from postganglionic sympathetic nerve endings. However, a concomitant ganglionic inhibitory action cannot be excluded.