New GABA-Targeting Therapies for the Treatment of Seizures and Epilepsy: I. Role of GABA as a Modulator of Seizure Activity and Recently Approved Medications Acting on the GABA System.

IF 7.4 2区医学 Q1 CLINICAL NEUROLOGY

CNS drugs Pub Date : 2023-09-01 Epub Date: 2023-08-21 DOI:10.1007/s40263-023-01027-2

Emilio Perucca, Meir Bialer, H Steve White

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Abstract

γ-Aminobutyric acid (GABA) is the most prevalent inhibitory neurotransmitter in the mammalian brain and has been found to play an important role in the pathogenesis or the expression of many neurological diseases, including epilepsy. Although GABA can act on different receptor subtypes, the component of the GABA system that is most critical to modulation of seizure activity is the GABA_A-receptor-chloride (Cl^-) channel complex, which controls the movement of Cl^- ions across the neuronal membrane. In the mature brain, binding of GABA to GABA_A receptors evokes a hyperpolarising (anticonvulsant) response, which is mediated by influx of Cl^- into the cell driven by its concentration gradient between extracellular and intracellular fluid. However, in the immature brain and under certain pathological conditions, GABA can exert a paradoxical depolarising (proconvulsant) effect as a result of an efflux of chloride from high intracellular to lower extracellular Cl^- levels. Extensive preclinical and clinical evidence indicates that alterations in GABAergic inhibition caused by drugs, toxins, gene defects or other disease states (including seizures themselves) play a causative or contributing role in facilitating or maintaning seizure activity. Conversely, enhancement of GABAergic transmission through pharmacological modulation of the GABA system is a major mechanism by which different antiseizure medications exert their therapeutic effect. In this article, we review the pharmacology and function of the GABA system and its perturbation in seizure disorders, and highlight how improved understanding of this system offers opportunities to develop more efficacious and better tolerated antiseizure medications. We also review the available data for the two most recently approved antiseizure medications that act, at least in part, through GABAergic mechanisms, namely cenobamate and ganaxolone. Differences in the mode of drug discovery, pharmacological profile, pharmacokinetic properties, drug-drug interaction potential, and clinical efficacy and tolerability of these agents are discussed.

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用于治疗癫痫和癫痫的新的GABA靶向疗法：I.GABA作为癫痫活动调节剂的作用和最近批准的作用于GABA系统的药物。

γ-氨基丁酸（GABA）是哺乳动物大脑中最常见的抑制性神经递质，已被发现在包括癫痫在内的许多神经疾病的发病机制或表达中发挥重要作用。尽管GABA可以作用于不同的受体亚型，但GABA系统中对调节癫痫活动最关键的成分是GABAA受体氯（Cl-）通道复合物，它控制Cl-离子在神经元膜上的运动。在成熟的大脑中，GABA与GABAA受体的结合引起超极化（抗惊厥）反应，这是由细胞外液和细胞内液之间的浓度梯度驱动Cl-流入细胞介导的。然而，在未成熟的大脑中，在某些病理条件下，GABA可以发挥反常的去极化（促惊厥）作用，这是氯化物从高细胞内Cl-水平流出到低细胞外Cl-水平的结果。大量的临床前和临床证据表明，药物、毒素、基因缺陷或其他疾病状态（包括癫痫发作本身）引起的GABA能抑制的改变在促进或维持癫痫发作活动中起着致病或促进作用。相反，通过GABA系统的药理学调节来增强GABA能传递是不同抗癫痫药物发挥治疗作用的主要机制。在这篇文章中，我们回顾了GABA系统的药理学和功能及其在癫痫发作中的扰动，并强调了对该系统的理解的提高如何为开发更有效、耐受性更好的抗癫痫药物提供了机会。我们还回顾了最近批准的两种抗癫痫药物的可用数据，这两种药物至少部分通过GABA能机制发挥作用，即cenobamate和ganaxolone。讨论了这些药物在药物发现模式、药理学特征、药代动力学特性、药物相互作用潜力以及临床疗效和耐受性方面的差异。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

CNS drugs 医学-精神病学

CiteScore

12.00

自引率

3.30%

发文量

审稿时长

6-12 weeks

期刊介绍： CNS Drugs promotes rational pharmacotherapy within the disciplines of clinical psychiatry and neurology. The Journal includes: - Overviews of contentious or emerging issues. - Comprehensive narrative reviews that provide an authoritative source of information on pharmacological approaches to managing neurological and psychiatric illnesses. - Systematic reviews that collate empirical evidence to answer a specific research question, using explicit, systematic methods as outlined by the PRISMA statement. - Adis Drug Reviews of the properties and place in therapy of both newer and established drugs in neurology and psychiatry. - Original research articles reporting the results of well-designed studies with a strong link to clinical practice, such as clinical pharmacodynamic and pharmacokinetic studies, clinical trials, meta-analyses, outcomes research, and pharmacoeconomic and pharmacoepidemiological studies. Additional digital features (including animated abstracts, video abstracts, slide decks, audio slides, instructional videos, infographics, podcasts and animations) can be published with articles; these are designed to increase the visibility, readership and educational value of the journal’s content. In addition, articles published in CNS Drugs may be accompanied by plain language summaries to assist readers who have some knowledge of, but not in-depth expertise in, the area to understand important medical advances.