药物成瘾中不同环境线索诱发觅药行为的机制

接触药物相关环境线索可激发成瘾者对药物的渴求感及复吸行为。实验动物研究中药物相关环境线索分为三类:伴药线索、辨别线索和情境线索。在长期停药及用药行为消退后三种环境线索均能诱发觅药行为恢复,而行为机制各具特点:伴药线索条件性强化觅药行为,辨别线索直接激发觅药行为发生,情境线索设定场景诱发觅药行为恢复。三种线索行为效应的神经基础局部相同而又各具特点,其机制的研究有助于对成瘾药物复吸机制的理解及临床戒毒治疗。     

药物成瘾记忆的神经生物机制及临床干预方法

药物成瘾者戒断后的持久复吸是治疗药物成瘾的难点.成瘾者出现持续复吸的重要原因是由于成瘾记忆的长期存在.成瘾物质的长期反复使用导致前额叶-边缘多巴胺系统结构和功能的适应性改变,这种改变是成瘾记忆形成的神经基础.本文从学习记忆的角度来理解成瘾形成,介绍了成瘾记忆的初始形成阶段、习惯化阶段和成瘾行为维持阶段及其相应的神经基础.回顾了近年来成瘾记忆的临床干预方法,包括消退干预方法、增强消退干预的多情境干预方法,以及直接干预消除成瘾记忆的记忆再巩固干预方法,并总结了虚拟现实、神经调控技术在成瘾记忆干预中的应用.对记忆再巩固干预方法与虚拟现实、神经调控技术相结合干预成瘾记忆进行展望,为药物成瘾的临床干预和治疗提供了新方法、新思路.     

药物复吸的神经生物学机制

复吸是指药物依赖者在戒药一段时间后,由于某些因素的激发,重现觅药和用药的行为。是药物成瘾的重要特征,与多种因素有关,其神经生物学机理十分复杂。杏仁核复合体、前额叶皮层、海马以及伏隔核等结构在复吸的过程中起重要的作用,多巴胺和谷氨酸等神经递质及其受体与复吸有关。该文介绍了复吸的神经生物学机制。     

心得安对ICR小鼠吗啡诱导的条件化位置偏爱记忆获得和提取的影响

利用心得安阻断β-肾上腺素受体(β-受体),从而干扰药物成瘾患者对药物环境线索记忆的某些环节(如再巩固等),进而降低或抑制其对成瘾药物的渴求,已成为未来治疗复吸的潜在途径.但目前,心得安对吗啡相关环境线索记忆的获得及提取的影响尚不清楚.因此,该实验检测了心得安对小鼠吗啡诱导的条件化位置偏爱(conditioned place preference,CPP)环境线索记忆的获得和提取的影响.该研究首次发现在吗啡CPP记忆的获得期,心得安不影响CPP的表达和消退,提示β-受体不参与吗啡诱导CPP学习记忆的获得;而在吗啡CPP记忆的提取期,心得安可延缓CPP的消退,提示β-受体与吗啡诱导CPP学习记忆的提取相关.该结果表明,药物成瘾过程与β-受体相关,为成瘾等精神疾病的治疗提供了新的理论依据.     

终纹床核神经元AMPA／NMDA的受体比例与可卡因复吸

研究成瘾药物复吸的神经机制是此类研究的核心问题。最近,美国俄勒冈健康与科学大学学者John TWilliams等人发现:被动接受成瘾药物和主动复吸有不同的神经机制。此研究从兴奋性突触强度变化和AMPA/NMDA受体比例变化入手,观察到大鼠腹侧终纹床核(ventral lateral bed nucleus of     

GABA受体与药物依赖性的研究进展

药物成瘾是一种全球性的公共卫生问题,其发生机制十分复杂。γ-氨基丁酸(γ-aminobutyric acid,GABA)是中枢神经系统中主要的抑制性神经递质,其通过调节GABA受体(如:GABA_A,GABA_B)的活性参与多种药物成瘾和依赖性的发生与发展过程。吗啡、可卡因、甲基苯丙胺等药物引起的奖赏、戒断和复吸作用与GABA受体的激活或抑制密切相关。本文将对GABA受体在药物依赖中的作用及机制进行综述,从而为治疗药物成瘾提供新的策略。     

药物成瘾及成瘾记忆的研究现状

本文在介绍药物成瘾与学习和记忆密切相关的神经回路及共同分子机制的基础上,围绕学习和记忆在药物成瘾中的作用,综述了关联性学习与复吸,关联性学习与敏化,异常关联性学习与强迫性用药行为,关联性学习及成瘾记忆与成瘾,多重记忆系统与成瘾的发生发展等方面的研究进展,并强调了突触可塑性及成瘾记忆在药物成瘾中的重要性。在此基础上提出：作为慢性脑病的药物成瘾的形成过程的重要特征是它包含着信息的特殊学习类型。药物成瘾与依赖于多巴胺的关联性学习紊乱有密切关系。海马可能在成瘾中扮演重要角色。     

纹状体在药物成瘾有关的联想性学习中的作用

多种学习和记忆系统参与成瘾行为,其中联想性学习发挥着重要作用。药物相关的条件性刺激通过经典条件作用和操作性条件作用的异常结合,引起觅药行为的产生、巩固、加强,并参与习惯行为的获得和复吸的发生。这些影响是通过腹侧纹状体对皮层边缘系统的整合以及背侧纹状体的习惯化来调节的,而多巴胺在其中发挥重要作用。另外,基于鸟类纹状体发达的解剖特点,脑内多巴胺系统及与哺乳动物成瘾行为的相似性,相信可为以后的研究提供新的思路。     

药物依赖临床治疗的研究新进展

随着吸毒人员的剧增,药物依赖极大的危害着人类健康和社会稳定,已经成为目前严重的社会性问题。心瘾是患者复吸的重要原因,心瘾的戒断是治疗成瘾的关键。供临床医生选择的治疗方法有很多,但是根据成瘾者的病情合理的选择治疗措施是目前临床工作中面临的巨大挑战。本文综述了目前物质依赖的药物治疗的作用机制以及临床疗效、各种手术戒毒的效果以及不良反应、心理行为治疗的原因以及具体措施,药物治疗、手术治疗以及中西医联合治疗的最新进展。     

脑内多巴胺信号动态变化的检测方法及在成瘾研究中的应用

多巴胺是脑内重要的神经递质,中脑多巴胺系统在控制奖赏、动机、运动和情绪调节过程中起重要作用。脑内多巴胺功能紊乱与药物依赖、精神分裂症、抑郁症和帕金森氏病等神经精神障碍有关,动态测定脑内多巴胺变化对于了解多巴胺功能和揭示相关疾病病理机制具有重要意义。本文主要介绍了微透析、快速扫描循环伏安法和光纤光度法的基本原理和方法,并对比分析了这些技术在多巴胺动态检测应用中的优缺点。以药物成瘾研究为应用实例,利用微透析法发现伏隔核壳部是成瘾性药物产生奖赏效应的关键部位,快速扫描循环伏安法检测到与可卡因自身给药行为相关的三种多巴胺信号模式,而光纤光度法则揭示了酒精成瘾和复吸过程中伏隔核和中脑复侧被盖区多巴胺活动特征存在空间和时间上的多样性。这些发现为揭示药物成瘾的机制做出了重要贡献。     

Experimental genetic approaches to addiction

Drugs of abuse are able to elicit compulsive drug-seeking behaviors upon repeated administration, which ultimately leads to the phenomenon of addiction. Evidence indicates that the susceptibility to develop addiction is influenced by sources of reinforcement, variable neuroadaptive mechanisms, and neurochemical changes that together lead to altered homeostasis of the brain reward system. Addiction is hypothesized to be a cycle of progressive dysregulation of the brain reward system that results in the compulsive use and loss of control over drug taking and the initiation of behaviors associated with drug seeking. The view that addiction represents a pathological state of reward provides an approach to identifying the factors that contribute to vulnerability, addiction, and relapse in genetic animal models.     

A cannabinoid mechanism in relapse to cocaine seeking

Treatment of cocaine addiction is hampered by high rates of relapse even after prolonged drug abstinence. This relapse to compulsive cocaine use can be triggered by re-exposure to cocaine, by re-exposure to stimuli previously associated with cocaine or by exposure to stress. In laboratory rats, similar events reinstate cocaine seeking after prolonged withdrawal periods, thus providing a model to study neuronal mechanisms underlying the relapse to cocaine. The endocannabinoid system has been implicated in a number of neuropsychiatric conditions, including drug addiction. The active ingredient of marijuana, Delta9-tetrahydrocannabinol, activates the mesolimbic dopamine (DA) reward system and has rewarding effects in preclinical models of drug abuse. We report here that the synthetic cannabinoid agonist, HU210 (ref. 13), provokes relapse to cocaine seeking after prolonged withdrawal periods. Furthermore, the selective CB1 receptor antagonist, SR141716A (ref. 14), attenuates relapse induced by re-exposure to cocaine-associated cues or cocaine itself, but not relapse induced by exposure to stress. These data reveal an important role of the cannabinoid system in the neuronal processes underlying relapse to cocaine seeking, and provide a rationale for the use of cannabinoid receptor antagonists for the prevention of relapse to cocaine use.     

Glutamate and Brain Glutaminases in Drug Addiction

Glutamate is the principal excitatory neurotransmitter in the central nervous system and its actions are related to the behavioral effects of psychostimulant drugs. In the last two decades, basic neuroscience research and preclinical studies with animal models are suggesting a critical role for glutamate transmission in drug reward, reinforcement, and relapse. Although most of the interest has been centered in post-synaptic glutamate receptors, the presynaptic synthesis of glutamate through brain glutaminases may also contribute to imbalances in glutamate homeostasis, a key feature of the glutamatergic hypothesis of addiction. Glutaminases are the main glutamate-producing enzymes in brain and dysregulation of their function have been associated with neurodegenerative diseases and neurological disorders; however, the possible implication of these enzymes in drug addiction remains largely unknown. This mini-review focuses on brain glutaminase isozymes and their alterations by in vivo exposure to drugs of abuse, which are discussed in the context of the glutamate homeostasis theory of addiction. Recent findings from mouse models have shown that drugs induce changes in the expression profiles of key glutamatergic transmission genes, although the molecular mechanisms that regulate drug-induced neuronal sensitization and behavioral plasticity are not clear.     

miRNAs与药物成瘾

药物成瘾是一种慢性复发性脑病,主要表现为不可控制的对药物持续渴求和戒断后的高复吸。目前观点认为,成瘾是中脑腹侧被盖（ventral tegmental area,VTA）到伏隔核（nucleus accumbens,NAc）脑区多巴胺能奖赏通路中神经可塑性发生改变而导致的一种神经精神疾病。基因表达变化在神经可塑性中发挥着重要作用,但成瘾药物导致相关脑区结构和功能改变的机制还不甚清楚。微小RNAs（microRNAs,miRNAs）是一类非编码RNA,主要通过结合靶基因mRNA 3′非翻译区（3′untranslated region,3′UTR）,在转录后水平阻断其翻译成蛋白质或触发其不稳定而降解。越来越多的研究证实,miRNAs参与调节成瘾相关神经可塑性的变化。本文较系统地阐述miRNAs在药物成瘾中的作用研究进展,将为深入阐明药物成瘾的机制以及药物成瘾临床有效干预和诊治提供新思路。     

Sex differences and ovarian hormones in animal models of drug dependence

Increasing evidence indicates the presence of sex differences in many aspects of drug abuse. Most studies reveal that females exceed males during the initiation, escalation, extinction, and reinstatement (relapse) of drug-seeking behavior, but males are more sensitive than females to the aversive effects of drugs such as drug withdrawal. Findings from human and animal research indicate that circulating levels of ovarian steroid hormones account for these sex differences. Estrogen (E) facilitates drug-seeking behavior, while progesterone (P) and its metabolite, allopregnanalone (ALLO), counteract the effects of E and reduce drug seeking. Estrogen and P influence other behaviors that are affiliated with drug abuse such as drug-induced locomotor sensitization and conditioned place preference. The enhanced vulnerability to drug seeking in females vs. males is also additive with the other risk factors for drug abuse (e.g., adolescence, sweet preference, novelty reactivity, and impulsivity). Finally, treatment studies using behavioral or pharmacological interventions, including P and ALLO, also indicate that females show greater treatment effectiveness during several phases of the addiction process. The neurobiological basis of sex differences in drug abuse appears to be genetic and involves the influence of ovarian hormones and their metabolites, the hypothalamic pituitary adrenal (HPA) axis, dopamine (DA), and gamma-hydroxy-butyric acid (GABA). Overall, sex and hormonal status along with other biological risk factors account for a continuum of addiction-prone and -resistant animal models that are valuable for studying drug abuse prevention and treatment strategies.     

A general method for evaluating incubation of sucrose craving in rats

For someone on a food-restricted diet, food craving in response to food-paired cues may serve as a key behavioral transition point between abstinence and relapse to food taking. Food craving conceptualized in this way is akin to drug craving in response to drug-paired cues. A rich literature has been developed around understanding the behavioral and neurobiological determinants of drug craving; we and others have been focusing recently on translating techniques from basic addiction research to better understand addiction-like behaviors related to food. As done in previous studies of drug craving, we examine sucrose craving behavior by utilizing a rat model of relapse. In this model, rats self-administer either drug or food in sessions over several days. In a session, lever responding delivers the reward along with a tone+light stimulus. Craving behavior is then operationally defined as responding in a subsequent session where the reward is not available. Rats will reliably respond for the tone+light stimulus, likely due to its acquired conditioned reinforcing properties. This behavior is sometimes referred to as sucrose seeking or cue reactivity. In the present discussion we will use the term "sucrose craving" to subsume both of these constructs. In the past decade, we have focused on how the length of time following reward self-administration influences reward craving. Interestingly, rats increase responding for the reward-paired cue over the course of several weeks of a period of forced-abstinence. This "incubation of craving" is observed in rats that have self-administered either food or drugs of abuse. This time-dependent increase in craving we have identified in the animal model may have great potential relevance to human drug and food addiction behaviors. Here we present a protocol for assessing incubation of sucrose craving in rats. Variants of the procedure will be indicated where craving is assessed as responding for a discrete sucrose-paired cue following extinction of lever pressing within the sucrose self-administration context (Extinction without cues) or as responding for sucrose-paired cues in a general extinction context (Extinction with cues).     

Trafficking of dopamine transporters in psychostimulant actions

Brain dopamine (DA) plays a pivotal role in drug addiction. Since the plasma membrane DA transporter (DAT) is critical for terminating DA neurotransmission, it is important to understand how DATs are regulated and this regulation impacts drug addiction. The number of cell surface DATs is controlled by constitutive and regulated endocytic trafficking. Psychostimulants impact this trafficking. Amphetamines, DAT substrates, cause rapid up-regulation and slower down-regulation of DAT whereas cocaine, a DAT inhibitor, increases surface DATs. Recent reports have begun to elucidate the molecular mechanisms of these psychostimulant effects and link changes in DAT trafficking to psychostimulant-induced reward/reinforcement in animal models.     

Animal models and brain circuits in drug addiction

Animal models in the field of addiction are considered to be among the best available models of neuropsychiatric disease. These models have undergone a number of refinements that allow deeper understanding of the circuitry involved in initiating drug seeking and relapse. Notably, the demonstrable involvement of classic corticostriatal habit circuitry and the engagement of prefrontal cortical circuits in extinction training may have relevance to the therapeutic modulation of habit circuitry and drug addiction in humans.     

In search of predictive endophenotypes in addiction: insights from preclinical research

Drug addiction is widely recognized to afflict some but not all individuals by virtue of underlying risk markers and traits involving multifaceted interactions between polygenic and external factors. Remarkably, only a small proportion of individuals exposed to licit and illicit drugs develop compulsive drug‐seeking behavior, maintained in the face of adverse consequences and associated detrimental patterns of drug intake involving extended and repeated bouts of binge intoxication, withdrawal and relapse. As a consequence, research has increasingly endeavored to identify distinctive neurobehavioral mechanisms and endophenotypes that predispose individuals to compulsive drug use. However, research in active drug users is hampered by the difficulty in categorizing putatively causal behavioral traits prior to the initiation of drug use. By contrast, research in experimental animals is often hindered by the validity of approaches used to investigate the neural and psychological mechanisms of compulsive drug‐seeking habits in humans. Herein, we survey and discuss the principal findings emanating from preclinical animal research on addiction and highlight how specific behavioral endophenotypes of presumed genetic origin (e.g. trait anxiety, novelty preference and impulsivity) differentially contribute to compulsive forms of drug seeking and taking and, in particular, how these differentiate between different classes of stimulant and non‐stimulant drugs of abuse.     

Impulsivity, compulsivity, and top-down cognitive control

Impulsivity is the tendency to act prematurely without foresight. Behavioral and neurobiological analysis of this construct, with evidence from both animal and human studies, defines several dissociable forms depending on distinct cortico-striatal substrates. One form of impulsivity depends on the temporal discounting of reward, another on motor or response disinhibition. Impulsivity is commonly associated with addiction to drugs from different pharmacological classes, but its causal role in human addiction is unclear. We characterize in neurobehavioral and neurochemical terms a rodent model of impulsivity based on premature responding in an attentional task. Evidence is surveyed that high impulsivity on this task precedes the escalation subsequently of cocaine self-administration behavior, and also a tendency toward compulsive cocaine-seeking and to relapse. These results indicate that the vulnerability to stimulant addiction may depend on an impulsivity endophenotype. Implications of these findings for the etiology, development, and treatment of drug addiction are considered.