灵长类镜像神经系统研究的最新进展

近年来,镜像神经系统成为认知神经科学的研究热点.神经生理学和脑成像的相关研究表明,镜像神经系统以运动为基础,统一了动作观察和动作执行的神经机制,为理解他人动作提供了来自"内部"的支持.镜像神经系统为个体间的自然交流提供了神经基础,具有深远的进化意义.它不仅存在于灵长类,甚至在进化距离较远的物种(如沼雀和斑雀)中也有发现...     

情绪模仿的神经生理机制：从镜像神经系统到神经网络

情绪模仿是指观察者对表达者传递出的非言语情绪信号进行模仿,进而表现出一致的表情与行为.以往关于情绪模仿的神经机制着重强调镜像神经系统的作用,然而随着研究成果越来越丰富,研究者们发现仅仅是镜像神经系统不足以解释情绪模仿的发生过程.梳理以往实证研究可以发现,情绪模仿是包括镜像神经系统、情绪系统、运动系统以及与社会认知相关脑区在内的脑网络共同作用的结果,该网络同时受到内分泌系统的调节.本文首先基于过往研究对情绪模仿的神经生理基础进行总结,然后介绍新近的神经网络概念模型,试图解释情绪信息从表达者传递至观察者完成模仿的神经路径,为情绪模仿的神经生理机制提供较为完整的框架,并在此基础上指出未来可能的研究方向.     

被子植物镜像花柱及其进化意义

镜像花柱是指花柱在花水平面上向左(左花柱型)或向右(右花柱型)偏离花中轴线,是一种花柱多态现象,可根据左、右花柱花在植株上的排列式样划分为单型镜像花柱和二型镜像花柱两类,或根据镜像花柱和雄蕊的排列方式划分为雌雄互补镜像花柱和非雌雄互补镜像花柱两类。镜像花柱现象已在被子植物11个科的部分种类中进行了报道,它在保护功能型雄蕊和雌蕊、通过自交产生繁殖保障效应以及通过减小雌雄功能间干扰、提高异交率和雄性适合度等方面具有重要的进化意义,目前已成为植物繁殖生物学领域的研究热点。本文总结分析了国际上有关镜像花柱的研究工作,重点介绍:(1)镜像花柱的类型、镜像花的形态分化及花部特征,(2)镜像花柱植物在被子植物中的分布及其遗传演化,(3)镜像花的交配式样和交配频率、传粉特点及其进化生物学意义,并对今后的研究方向进行了展望,以期为进一步研究镜像花柱植物的进化生物学特性,推动我国在该领域的发展提供科学依据。     

灵长类镜像神经元系统起源及其争议研究进展

在灵长类镜像神经元系统的研究中,关于镜像神经元系统的产生主要存在两种观点,基因假说认为镜像神经元系统的出现基于一定的演化压力,服务于动作理解这一社会性功能;而联想学习假说则认为镜像神经元系统是感觉运动学习的产物,并不服务于动作理解。在联想学习的阵营中,联想序列学习主张一种极端的后天论立场,并通过刺激-反应范式提供大量的实证证据。但是,联想序列学习虽然能够解释大部分镜像神经元的研究,却无法否定其发生机制中的基因成分。比较镜像神经元系统在多个物种中的演化历史,探索个体早期发展对社会性信息的偏好均显示出联想序列学习存在局限,而联想序列学习提供的证据也不具有生态学效度。因此,对镜像神经元的基因基础如何影响其产生、发展与演化的探讨仍将是一个极具意义和生命力的主题。     

苦苣苔科镜像花的多样性及演化

泛热带分布的苦苣苔科(Gesneriaceae)在我国南方具有极高的物种丰富度与特有率,花部特征变化丰富,是研究物种形成与适应演化的代表类群。镜像花(mirror-image flowers)是极为特化的传粉系统,在苦苣苔科中出现了较多的不同类型,可能与苦苣苔科物种多样性形成与维持有关。该研究总结与分析了苦苣苔科镜像花的类型多样性以及系统分布与适应演化等,讨论了镜像花对苦苣苔科物种形成与维持的积极意义。结果表明:镜像花仅分布在亚洲和非洲的苦苣苔亚科(Didymocarpoideae)的7个属,在历史上就至少发生了5次独立起源。长冠苣苔属(Rhabdothamnopsis)、南洋苣苔属(Henckelia)及长蒴苣苔属(Didymocarpus)镜像花的花柱与可育雄蕊分别向左、右两侧偏转,形成互补镜像花;蛛毛苣苔属(Paraboea)、喜鹊苣苔属(Ornithoboea)、非洲堇属(Saintpaulia)镜像花缺乏与花柱对应侧偏的可育雄蕊(非互补镜像花);而海角苣苔属(Streptocarpus)直立堇兰亚属(subg.Streptocarpella Engler)则同时出现了互补、非互补镜像花。不同于其他被子植物(离瓣花、缺乏花冠筒),苦苣苔科中的镜像花大多伴随着明显的花冠筒、内藏的雄蕊、合生的花药,以非互补镜像花为主;传粉者以小型的无垫蜂(Amegilla spp.)和熊蜂(Bombus spp.)为主。这些特殊的花部综合征与特化的传粉机制,提高了传粉精确性,可能促进了传粉隔离与物种适应辐射。今后的一个研究重点应通过分子系统发育方法,进一步揭示苦苣苔亚科互补与非互补镜像花的进化顺序及其在物种分化与长距离扩散过程中的可能作用。     

实体、镜像及影像对ICR小鼠取食行为的影响

镜像、影像等虚拟条件可能影响动物的觅食行为和活动时间分配。利用控制性围栏实验观察了同种个体实体、镜像及影像对ICR小鼠(Mus musculus)的觅食行为和活动时间分配的影响。发现实验鼠与实体接触时间显著高于与镜像、影像的接触时间;实体存在时,实验鼠显著增加了在低竞争风险区域贮藏食物量和巢外活动时间;影像存在时,实验鼠显著减少了巢外活动时间。结果提示ICR小鼠在实体、镜像、影像条件下表现出不同的觅食策略和活动时间分配,其觅食行为具有一定的可塑性。该结果可能为进一步研究ICR小鼠的行为及饲养管理提供一定参考。     

家蚕神经系统研究进展

家蚕Bombyx mori神经系统属于腹神经索型, 构造简单, 却能产生丰富的行为, 是研究神经生物学的理想实验材料。研究表明： 家蚕神经系统由中枢神经系统、 外周神经系统和交感神经系统构成, 通过信号传递在调节家蚕视觉、 嗅觉、 取食、 结茧、 交配、 排泄等生命活动中发挥作用。家蚕具有编码乙酰胆碱、 γ-氨基丁酸、 多巴胺等多种神经递质及其受体和促前胸腺激素（prothoracicotropic hormone, PTTH）、 滞育激素（diapause hormone, DH）等神经肽的基因。家蚕神经系统发育受到许多基因和bmo-miR-92等小分子RNA的调控。目前研究家蚕神经的方法主要有触角电位技术、 免疫细胞化学法、 转基因方法、 神经信息学及计算机三维重建等。对家蚕神经系统的研究有助于阐明神经系统的信号传递机制和生物神经网络的形成机制。     

鸢尾素在神经系统生理及病理状态下的研究进展

随着研究的深入,肌肉因子纤连蛋白Ⅲ型结构域蛋白5(FNDC5)的分泌蛋白鸢尾素(Irisin)在神经系统中的作用逐渐被阐明。鸢尾素不仅在神经分化及神经内分泌等生理功能中发挥重要作用,还参与神经系统疾病的病理变化过程并具有广阔的临床应用前景。本文对鸢尾素在神经系统发育、神经系统功能、阿尔茨海默病及脑卒中等方面中的研究进展进行综述,为鸢尾素的研究提供新思路。     

小胶质细胞发育和功能的性别差异

小胶质细胞是神经系统的免疫细胞,参与调节神经系统的发育以及维持神经系统稳态。小胶质细胞的发育和功能存在显著的性别差异,可能是脑性分化的关键介质。该文总结了小胶质细胞在发育、免疫应答以及神经系统疾病中的性别特征,为研究脑性分化和神经系统疾病的性别差异提供理论参考。     

MicroRNA与神经系统重大疾病

目前有研究证实microRNA参与了神经系统生长发育和生理功能的调控,它也与可塑性障碍性疾病、神经系统退行性疾病、神经系统肿瘤、脑血管疾病等重大疾病的发生发展相关．随着microRNA研究领域的发展,一些重大神经系统疾病的相关发病机制将有可能被阐释．     

The mirror neuron system and the consequences of its dysfunction

The discovery of premotor and parietal cells known as mirror neurons in the macaque brain that fire not only when the animal is in action, but also when it observes others carrying out the same actions provides a plausible neurophysiological mechanism for a variety of important social behaviours, from imitation to empathy. Recent data also show that dysfunction of the mirror neuron system in humans might be a core deficit in autism, a socially isolating condition. Here, we review the neurophysiology of the mirror neuron system and its role in social cognition and discuss the clinical implications of mirror neuron dysfunction.     

Magnetoencephalography study of right parietal lobe dysfunction of the evoked mirror neuron system in antipsychotic-free schizophrenia

IntroductionPatients with schizophrenia commonly exhibit deficits of non-verbal communication in social contexts, which may be related to cognitive dysfunction that impairs recognition of biological motion. Although perception of biological motion is known to be mediated by the mirror neuron system, there have been few empirical studies of this system in patients with schizophrenia.MethodsUsing magnetoencephalography, we examined whether antipsychotic-free schizophrenia patients displayed mirror neuron system dysfunction during observation of biological motion (jaw movement of another individual).ResultsCompared with normal controls, the patients with schizophrenia had fewer components of both the waveform and equivalent current dipole, suggesting aberrant brain activity resulting from dysfunction of the right inferior parietal cortex. They also lacked the changes of alpha band and gamma band oscillation seen in normal controls, and had weaker phase-locking factors and gamma-synchronization predominantly in right parietal cortex.ConclusionsOur findings demonstrate that untreated patients with schizophrenia exhibit aberrant mirror neuron system function based on the right inferior parietal cortex, which is characterized by dysfunction of gamma-synchronization in the right parietal lobe during observation of biological motion.     

Modulation of Motor Area Activity by the Outcome for a Player during Observation of a Baseball Game

Background

Observing competitive games such as sports is a pervasive entertainment among humans. The inclination to watch others play may be based on our social-cognitive ability to understand the internal states of others. The mirror neuron system, which is activated when a subject observes the actions of others, as well as when they perform the same action themselves, seems to play a crucial role in this process. Our previous study showed that activity of the mirror neuron system was modulated by the outcome of the subject''s favored player during observation of a simple competitive game (rock-paper-scissors). However, whether the mirror neuron system responds similarly in a more complex and naturalistic sports game has not yet been fully investigated.

Methodology/Principal Findings

In the present study, we measured the activity of motor areas when the subjects, who were amateur baseball field players (non-pitchers), watched short movie clips of scenes in professional baseball games. The subjects were instructed to support either a batter or a pitcher when observing the movie clip. The results showed that activity in the motor area exhibited a strong interaction between the subject''s supported side (batter or pitcher) and the outcome (a hit or an out). When the subject supported the batter, motor area activity was significantly higher when the batter made an out than when he made a hit. However, such modulation was not apparent when the subject supported the pitcher.

Conclusions/Significance

This result indicates that mirror neuron system activity is modulated by the outcome for a particular player in a competitive game even when observing a complex and naturalistic sports game. We suggest that our inclination to watch competitive games is facilitated by this characteristic of the mirror neuron system.     

Extending the mirror neuron system model,I

The paper introduces mirror neuron system II (MNS2), a new version of the MNS model (Oztop and Arbib in Biol Cybern 87 (2):116–140, 2002) of action recognition learning by mirror neurons of the macaque brain. The new model uses a recurrent architecture that is biologically more plausible than that of the original model. Moreover, MNS2 extends the capacity of the model to address data on audio-visual mirror neurons and on the response of mirror neurons when the target object was recently visible but is currently hidden.     

Schema design and implementation of the grasp-related mirror neuron system

 Mirror neurons within a monkey's premotor area F5 fire not only when the monkey performs a certain class of actions but also when the monkey observes another monkey (or the experimenter) perform a similar action. It has thus been argued that these neurons are crucial for understanding of actions by others. We offer the hand-state hypothesis as a new explanation of the evolution of this capability: the basic functionality of the F5 mirror system is to elaborate the appropriate feedback – what we call the hand state– for opposition-space based control of manual grasping of an object. Given this functionality, the social role of the F5 mirror system in understanding the actions of others may be seen as an exaptation gained by generalizing from one's own hand to an other's hand. In other words, mirror neurons first evolved to augment the “canonical” F5 neurons (active during self-movement based on observation of an object) by providing visual feedback on “hand state,” relating the shape of the hand to the shape of the object. We then introduce the MNS1 (mirror neuron system 1) model of F5 and related brain regions. The existing Fagg–Arbib–Rizzolatti–Sakata model represents circuitry for visually guided grasping of objects, linking the anterior intraparietal area (AIP) with F5 canonical neurons. The MNS1 model extends the AIP visual pathway by also modeling pathways, directed toward F5 mirror neurons, which match arm–hand trajectories to the affordances and location of a potential target object. We present the basic schemas for the MNS1 model, then aggregate them into three “grand schemas”– visual analysis of hand state, reach and grasp, and the core mirror circuit – for each of which we present a useful implementation (a non-neural visual processing system, a multijoint 3-D kinematics simulator, and a learning neural network, respectively). With this implementation we show how the mirror system may learnto recognize actions already in the repertoire of the F5 canonical neurons. We show that the connectivity pattern of mirror neuron circuitry can be established through training, and that the resultant network can exhibit a range of novel, physiologically interesting behaviors during the process of action recognition. We train the system on the basis of final grasp but then observe the whole time course of mirror neuron activity, yielding predictions for neurophysiological experiments under conditions of spatial perturbation, altered kinematics, and ambiguous grasp execution which highlight the importance of the timingof mirror neuron activity. Received: 6 August 2001 / Accepted in revised form: 5 February 2002     

Action understanding: how, what and why

The mirror neuron system may help us understand how others act and what they do. A recent study has shown that consciously reflecting on their intentions additionally recruits mentalizing areas.     

Action observation: inferring intentions without mirror neurons

A recent study has shown, using fMRI, that the mirror neuron system does not mediate action understanding when the observed action is novel or when it is hard to understand.     

Síndrome del miembro fantasma: aproximación terapéutica mediante el tratamiento espejo. Experiencia de un Servicio de Geriatría

The clinical use of mirror visual feedback was initially introduced to alleviate phantom pain by restoring motor function through plastic changes in the human primary motor cortex. It is a promising novel technique that gives a new perspective to neurological rehabilitation. Using this therapy, the mirror neuron system is activated and decrease the activity of those systems that perceive protopathic pain, making somatosensory cortex reorganization possible. This paper reports the results of the mirror therapy in three patients with phantom limb pain after recent lower limb amputation, showing its analgesic effects and its benefits as a comprehensive rehabilitation instrument for lower limb amputee geriatric patients.     

Autism spectrum disorder: seeing is not understanding

Impairments in social and emotional skills are a defining feature of autism spectrum disorder. Recent research shows that structural and functional abnormalities within the neural system that matches observation and execution of actions--the mirror neuron system--may explain the social aspects of the pathophysiology of autism spectrum disorder.     

Corticospinal mirror neurons

Here, we report the properties of neurons with mirror-like characteristics that were identified as pyramidal tract neurons (PTNs) and recorded in the ventral premotor cortex (area F5) and primary motor cortex (M1) of three macaque monkeys. We analysed the neurons’ discharge while the monkeys performed active grasp of either food or an object, and also while they observed an experimenter carrying out a similar range of grasps. A considerable proportion of tested PTNs showed clear mirror-like properties (52% F5 and 58% M1). Some PTNs exhibited ‘classical’ mirror neuron properties, increasing activity for both execution and observation, while others decreased their discharge during observation (‘suppression mirror-neurons’). These experiments not only demonstrate the existence of PTNs as mirror neurons in M1, but also reveal some interesting differences between M1 and F5 mirror PTNs. Although observation-related changes in the discharge of PTNs must reach the spinal cord and will include some direct projections to motoneurons supplying grasping muscles, there was no EMG activity in these muscles during action observation. We suggest that the mirror neuron system is involved in the withholding of unwanted movement during action observation. Mirror neurons are differentially recruited in the behaviour that switches rapidly between making your own movements and observing those of others.