Molecular Docking Studies on Anticonvulsant Enaminones Inhibiting Voltage-Gated Sodium Channels.

Open journal of physical chemistry Pub Date : 2019-11-01 Epub Date: 2019-11-29 DOI:10.4236/ojpc.2019.94015
Yayin Fang, Jamiya Kirkland, Isis J Amaye, Patrice Jackson-Ayotunde, Matthew George
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引用次数: 1

Abstract

Epilepsy is described as the most common chronic brain disorder. A typical symptom of epilepsy results in uncontrolled convulsions caused by temporary excessive neuronal discharges. Although, several new anticonvulsants have been introduced, some types of seizures have still not been adequately controlled with these new and current therapies. There is an urgent need to develop new anticonvulsant drugs to control the many different types of seizures. Many studies have shown that the epilepsies involve more than one mechanism and therefore may be responsible for the various types of observed seizures. Recently reported studies have shown that a group of newly synthesized 6 Hz active anticonvulsant fluorinated N-benzamide enaminones to exhibited selective inhibitions of voltage-gated sodium (Nav) channels. Nav channels are responsible for the initial inward currents during the depolarization phases of the action potential in excitable cells. The activation and opening of Nav channels result in the initial phases of action potentials. We hypothesize that there is an essential pharmacophore model for the interactions between these enaminones and the active sites of Nav channels. The research reported here is focused on molecular docking studies of the interactions that occur between the fluorinated N-benzamide enaminones and the Nav channels. These studies may open an avenue for designing anticonvulsant drugs by inhibiting Nav channels.

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抗惊厥胺酮抑制电压门控钠通道的分子对接研究。
癫痫被认为是最常见的慢性脑部疾病。癫痫的一个典型症状是由暂时的过度神经元放电引起的不受控制的抽搐。虽然已经引入了几种新的抗惊厥药,但一些类型的癫痫发作仍然不能通过这些新的和现有的治疗方法得到充分控制。迫切需要开发新的抗惊厥药物来控制许多不同类型的癫痫发作。许多研究表明,癫痫涉及不止一种机制,因此可能导致观察到的各种类型的癫痫发作。最近报道的研究表明,一组新合成的6赫兹活性抗惊厥氟化n -苯甲酰胺胺酮对电压门控钠(Nav)通道具有选择性抑制作用。在可兴奋细胞的动作电位去极化阶段,Nav通道负责初始的内向电流。Nav通道的激活和打开导致动作电位的初始阶段。我们假设这些胺酮与Nav通道活性位点之间的相互作用存在一个基本的药效团模型。本文报道的研究重点是氟化n -苯酰胺胺酮与Nav通道之间相互作用的分子对接研究。这些研究可能为通过抑制Nav通道设计抗惊厥药物开辟了一条途径。
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