Molecular mechanisms of action of stimulant novel psychoactive substances that target the high-affinity transporter for dopamine.

Q4 Neuroscience
Neuronal signaling Pub Date : 2021-11-17 eCollection Date: 2021-12-01 DOI:10.1042/NS20210006
Michelle A Sahai, Jolanta Opacka-Juffry
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引用次数: 2

Abstract

Drug misuse is a significant social and public health problem worldwide. Misused substances exert their neurobehavioural effects through changing neural signalling within the brain, many of them leading to substance dependence and addiction in the longer term. Among drugs with addictive liability, there are illicit classical stimulants such as cocaine and amphetamine, and their more recently available counterparts known as novel psychoactive substances (NPS). Stimulants normally increase dopamine availability in the brain, including the pathway implicated in reward-related behaviour. This pattern is observed in both animal and human brain. The main biological target of stimulants, both classical and NPS, is the dopamine transporter (DAT) implicated in the dopamine-enhancing effects of these drugs. This article aims at reviewing research on the molecular mechanisms underpinning the interactions between stimulant NPS, such as benzofurans, cathinones or piperidine derivatives and DAT, to achieve a greater understanding of the core phenomena that decide about the addictive potential of stimulant NPS. As the methodology is essential in the process of experimental research in this area, we review the applications of in vitro, in vivo and in silico approaches. The latter, including molecular dynamics, attracts the focus of the present review as the method of choice in molecular and atomistic investigations of the mechanisms of addiction of stimulant NPS. Research of this kind is of interest to not only scientists but also health professionals as updated knowledge of NPS, their modes of action and health risks, is needed to tackle the challenges posed by NPS misuse.

Abstract Image

Abstract Image

靶向多巴胺高亲和转运体的兴奋性新型精神活性物质的分子作用机制。
药物滥用是世界范围内一个重大的社会和公共卫生问题。滥用物质通过改变大脑内的神经信号来发挥其神经行为效应,其中许多会导致长期的物质依赖和成瘾。在具有成瘾性的药物中,有可卡因和苯丙胺等非法经典兴奋剂,以及最近可获得的新型精神活性物质。兴奋剂通常会增加大脑中多巴胺的可用性,包括与奖励相关行为有关的途径。这种模式在动物和人类大脑中都可以观察到。经典和NPS兴奋剂的主要生物靶点是多巴胺转运蛋白(DAT),与这些药物的多巴胺增强作用有关。本文旨在回顾苯并呋喃、卡西酮或哌啶衍生物等兴奋剂NPS与DAT相互作用的分子机制研究,以更好地了解决定兴奋剂NPS成瘾潜力的核心现象。由于该方法在该领域的实验研究过程中至关重要,我们综述了体外、体内和计算机方法的应用。后者,包括分子动力学,作为兴奋剂NPS成瘾机制的分子和原子研究中的选择方法,吸引了本综述的焦点。这类研究不仅引起科学家的兴趣,也引起卫生专业人员的兴趣,因为需要更新关于核动力源及其行动模式和健康风险的知识,以应对核动力源滥用带来的挑战。
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
CiteScore
4.60
自引率
0.00%
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审稿时长
14 weeks
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