Gonzalez Lorie A, Gatch Michael B, Taylor Cynthia M, Bell-Horner Cathy L, Forster Michael J, Dillon Glenn H
Department of Pharmacology and Neuroscience, University of North Texas Health Science Center, Fort Worth, TX 76107, USA.
J Pharmacol Exp Ther. 2009 May;329(2):827-37. doi: 10.1124/jpet.109.151142. Epub 2009 Feb 24.
Carisoprodol is a frequently prescribed muscle relaxant. In recent years, this drug has been increasingly abused. The effects of carisoprodol have been attributed to its metabolite, meprobamate, a controlled substance that produces sedation via GABA(A) receptors (GABA(A)Rs). Given the structural similarities between carisoprodol and meprobamate, we used electrophysiological and behavioral approaches to investigate whether carisoprodol directly affects GABA(A)R function. In whole-cell patch-clamp studies, carisoprodol allosterically modulated and directly activated human alpha1beta2gamma2 GABA(A)R function in a barbiturate-like manner. At millimolar concentrations, inhibitory effects were apparent. Similar allosteric effects were not observed for homomeric rho1 GABA or glycine alpha1 receptors. In the absence of GABA, carisoprodol produced picrotoxin-sensitive, inward currents that were significantly larger than those produced by meprobamate, suggesting carisoprodol may directly produce GABAergic effects in vivo. When administered to mice via intraperitoneal or oral routes, carisoprodol elicited locomotor depression within 8 to 12 min after injection. Intraperitoneal administration of meprobamate depressed locomotor activity in the same time frame. In drug discrimination studies with carisoprodol-trained rats, the GABAergic ligands pentobarbital, chlordiazepoxide, and meprobamate each substituted for carisoprodol in a dose-dependent manner. In accordance with findings in vitro, the discriminative stimulus effects of carisoprodol were antagonized by a barbiturate antagonist, bemegride, but not by the benzodiazepine site antagonist, flumazenil. The results of our studies in vivo and in vitro collectively suggest the barbiturate-like effects of carisoprodol may not be due solely to its metabolite, meprobamate. Furthermore, the functional traits we have identified probably contribute to the abuse potential of carisoprodol.
卡立普多是一种常用的肌肉松弛剂。近年来,这种药物的滥用现象日益增多。卡立普多的作用归因于其代谢产物甲丙氨酯,甲丙氨酯是一种通过GABA(A)受体(GABA(A)Rs)产生镇静作用的管制药物。鉴于卡立普多与甲丙氨酯在结构上的相似性,我们采用电生理和行为学方法来研究卡立普多是否直接影响GABA(A)R功能。在全细胞膜片钳研究中,卡立普多以类似巴比妥酸盐的方式变构调节并直接激活人α1β2γ2 GABA(A)R功能。在毫摩尔浓度下,抑制作用明显。对于同聚体rho1 GABA或甘氨酸α1受体,未观察到类似的变构效应。在无GABA的情况下,卡立普多产生了对苦味毒敏感的内向电流,该电流明显大于甲丙氨酯产生的电流,这表明卡立普多可能在体内直接产生GABA能效应。当通过腹腔内或口服途径给小鼠给药时,卡立普多在注射后8至12分钟内引起运动抑制。腹腔内注射甲丙氨酯在同一时间范围内抑制运动活性。在用卡立普多训练的大鼠进行的药物辨别研究中,GABA能配体戊巴比妥、氯氮卓和甲丙氨酯均以剂量依赖性方式替代卡立普多。与体外研究结果一致,卡立普多的辨别刺激效应被巴比妥酸盐拮抗剂美解眠拮抗,但未被苯二氮卓位点拮抗剂氟马西尼拮抗。我们体内和体外研究的结果共同表明,卡立普多的类似巴比妥酸盐的效应可能不仅仅归因于其代谢产物甲丙氨酯。此外,我们所确定的功能特性可能导致了卡立普多的滥用潜力。