镜像神经元系统的研究回顾及展望

镜像神经元系统的发现使得研究者从一个较为统一的神经机制层面了解人类多个层次的社会认知活动。在猕猴大脑F5区发现的镜像神经元可以在抽象的层面上帮助猕猴理解他人行为的意图。利用脑成像技术,研究发现人类的镜像神经元系统能够匹配外界的知觉表征和内在的动作表征从而通过“居身模仿”这一过程来进行模仿、语言理解、理解他人的意图及情绪这些重要的社会认知活动。另外,镜像神经元系统在社会交往中也起着重要作用,最后,就镜像神经元系统在心理理论中的作用、了解自我-他人问题和镜像神经元系统的关系、动机、经验等因素对镜像神经元系统活动的调控等问题对未来的研究方向进行了展望     

The psychology of the neuron: Freud, Cajal and Golgi

The interdisciplinary relations between neuroanatomy, philosophy and psychology are discussed in a historical framework-the period 1880–1900. It is shown that philosophical associationism is an integrated part of the neuroanatomical exploration of the minimal unit in the nervous system, and how these points have significance in some of Freuds earliest works     

孤独症与镜像神经元

孤独症是起始于婴幼儿时期的由脑功能障碍引起的长期发展性障碍,有3种典型的症状:社会交往与言语沟通障碍及出现刻板僵化行为.孤独症的病因复杂,镜像神经元的发现和研究,使得研究者有望揭开孤独症症状背后的神经机制,并为孤独症的诊断和治疗予以新的启发.     

The mirror neuron system and action recognition

Mirror neurons, first described in the rostral part of monkey ventral premotor cortex (area F5), discharge both when the animal performs a goal-directed hand action and when it observes another individual performing the same or a similar action. More recently, in the same area mirror neurons responding to the observation of mouth actions have been also found. In humans, through an fMRI study, it has been shown that the observation of actions performed with the hand, the mouth and the foot leads to the activation of different sectors of Broca's area and premotor cortex, according to the effector involved in the observed action, following a somatotopic pattern which resembles the classical motor cortex homunculus. These results strongly support the existence of an execution-observation matching system (mirror neuron system). It has been proposed that this system is involved in action recognition. Experimental evidence in favor of this hypothesis both in the monkey and humans are shortly reviewed.     

Conditioning circuits

A circuit of mutually exciting neurones capable of approaching and maintaining a state of permanent excitation has been described by Rashevsky as a possible mechanism for the production of conditioned reflexes. The mode of approach of such a circuit to the steady state is examined in some detail under slightly more general assumptions, and an estimate is made of the order of magnitude of the time required to reach this state.     

Integrative Properties of the Pe1 Neuron, a Unique Mushroom Body Output Neuron

A mushroom body extrinsic neuron, the Pe1 neuron, connects the peduncle of the mushroom body (MB) with two areas of the protocerebrum in the honeybee brain, the lateral protocerebral lobe (LPL) and the ring neuropil around the α-lobe. Each side of the bee brain contains only one Pe1 neuron. Using a combination of intracellular recording and neuroanatomical techniques we analyzed its properties of integrative processing of the different sensory modalities. The Pe1 neuron responds to visual, mechanosensory, and olfactory stimuli. The responses are broadly tuned, consisting of a sustained increase of spike frequency to the onset and offset of light flashes, to horizontal and vertical movements of extended objects, to mechanical stimuli applied to the antennae or mouth parts, and to all olfactory stimuli tested (29 chemicals). These multisensory properties are reflected in its dendritic organization. Serial reconstructions of intracellularly stained Pe1 neurons using confocal microscopy reveal that the Pe1 neuron arborizes throughout all layers of MB peduncle with finger-like, vertically oriented dendrites. The peduncle of the MB is formed by the axons of Kenyon cells, whose dendritic inputs are organized in modality-specific subcompartments of the calyx region. The peduncular arborization indicates that the Pe1 neuron receives input from Kenyon cells of all calycal subcompartments. Because the Pe1 neuron changes its odor responses transiently as a consequence of olfactory learning, we hypothesize that the multimodal response properties might have a role in memory consolidation and help to establish contextual references in the long-term trace.     

The photoneuromime: An artificial visual neuron for dynamic testing of computer-controlled experiments

The photoneuromime is a simple electronic device that produces frequency-modulated pulses resembling neural spike trains in response to light modulation. It simulates the linear behavior of cat retinal ganglion X-cell receptive field centers and was designed for testing computer programs that track sensitivity to patterns generated on a raster-scan CRT. Besides providing a convenient means for testing computer programs and recording apparatus, which previously required the use of a live preparation, the neuromime is also a valuable teaching tool in sensory psychology and neuroscience.     

奖赏环路与阿片成瘾:喙内侧被盖核的调节作用

喙内侧被盖核(RMTg)位于腹侧被盖区(VTA)的尾部, 富含抑制性的γ-氨基丁酸(GABA)能神经元.RMTg是中脑边缘多巴胺系统的一个综合调节器.它的GABA能神经元接受外侧缰核(LHb)的输入, 然后投射到VTA多巴胺能神经元, 进而抑制多巴胺的释放.这三个脑区是奖赏环路的重要组成部分, 其中RMTg在阿片类物质激活的奖赏环路中尤为重要.阿片类物质主要通过抑制RMTg GABA能神经元使VTA多巴胺能神经元去抑制, 进而激活奖赏系统.因此, RMTg有望成为治疗药物成瘾(尤其是阿片成瘾)的一个重要靶点.此外, 胆碱类物质作用于RMTg的毒蕈碱受体能够抑制阿片类物质诱导的奖赏效应.未来研究应深入探讨RMTg调控的负性奖赏环路, 这对弱化觅药动机,促进消退和戒断具有重要意义.     

The origins of vocal learning: New sounds, new circuits, new cells

We do not know how vocal learning came to be, but it is such a salient trait in human evolution that many have tried to imagine it. In primates this is difficult because we are the only species known to possess this skill. Songbirds provide a richer and independent set of data. I use comparative data and ask broad questions: How does vocal learning emerge during ontogeny? In what contexts? What are its benefits? How did it evolve from unlearned vocal signals? How was brain anatomy altered to enable vocal learning? What is the relation of vocal learning to adult neurogenesis? No one has described yet a circuit or set of circuits that can master vocal learning, but this knowledge may soon be within reach. Moreover, as we uncover how birds encode their learned song, we may also come closer to understanding how we encode our thoughts.     

The chronometry of single neuron activity: testing discrete and continuous models of information processing

The authors propose to study information transmission by comparing the effects of experimental factors on reaction time (RT) with the latency of the changes in activity of single-neurons. An experiment was conducted in which a monkey (Macaca mulatta) performed a tactilo-manual 2-choice RT task and the compatibility of the stimulus-response mapping was manipulated. Task-related neurons were recorded in the monkey's primary somesthetic and motor cortices. The changes in activity of 105 of these neurons were classified either as sensory-like or as motor-like. The sensory-like changes occurred before the motor-like ones. The stimulus-response mapping exerted its entire effect on the RT after the sensory-like changes and before the motor-like ones. These findings suggest that the information was transmitted discretely from the processes affected by the mapping to the processes implemented by the motor-like changes.     

Cortico-amygdala circuits: role in the conditioned stress response

The amygdala plays a crucial role in the orchestration and modulation of the organism response to aversive, stressful events. This response could be conceived as the result of two interdependent components. The first is represented by sets of visceral and motor responses aimed at helping the organism to cope with the present event. The second is the acquisition and modulation of memories relative to the stressful stimulus and its context. This latter component contributes to the instatement of conditioned stress responses that are essential to the capability of the organism to predict future exposures to similar stimuli in order to avoid them or counteract them effectively. In the amygdala, these two components become fully integrated. Massive networks link the amygdala to the hypothalamus, midbrain and brainstem. These networks convey visceral, humoral and nociceptive information to the amygdala and mediate its effects on the hypothalamic-pituitary-adrenal axis as well on autonomic and motor centers. On the other hand, interactions between the amygdala and interconnected cortical networks play a crucial role in acquisition, consolidation and extinction of learning relative to the stressful stimulus. Within the scope of this review, current evidence relative to the interaction between the amygdala and cortical networks will be considered in relationship to the integration of the conditioned response to stress.     

脑神经系统的非线性动力学特征及方法论

脑神经系统的非线性动力学特征是:它具有非线性、混沌性、突变性、自组织性及不可逆性等.脑神经系统是人类生命的中枢系统,这个系统是一个非线性动力学的复杂系统,由一个远离平衡态的耗散结构,综合构成了脑神经系统的整体性、复杂性.从方法论的角度对脑神经系统的整体性、复杂性进行了思考,并提供了一个方法论的理论框架,及具体的技术方法.     

Cognitive functions and corticostriatal circuits: insights from Huntington's disease

The basic mechanisms of information processing by corticostriatal circuits are currently a matter of intense debate amongst cognitive scientists. Huntington's disease, an autosomal-dominant neurogenetic disorder characterized clinically by a triad of motor, cognitive, and affective disturbance, is associated with neuronal loss within corticostriatal circuits, and as such provides a valuable model for understanding the role of these circuits in normal behaviour, and their disruption in disease. We review findings from our studies of the breakdown of cognition in Huntington's disease, with a particular emphasis on executive functions and visual recognition memory. We show that Huntington's disease patients exhibit a neuropsychological profile that shows a discernible pattern of progression with advancing disease, and appears to result from a breakdown in the mechanisms of response selection. These findings are consistent with recent computational models that suggest that corticostriatal circuits compute the patterns of sensory input and response output which are of behavioural significance within a particular environmental context.     

Predictive coding: an account of the mirror neuron system

Is it possible to understand the intentions of other people by simply observing their actions? Many believe that this ability is made possible by the brain’s mirror neuron system through its direct link between action and observation. However, precisely how intentions can be inferred through action observation has provoked much debate. Here we suggest that the function of the mirror system can be understood within a predictive coding framework that appeals to the statistical approach known as empirical Bayes. Within this scheme the most likely cause of an observed action can be inferred by minimizing the prediction error at all levels of the cortical hierarchy that are engaged during action observation. This account identifies a precise role for the mirror system in our ability to infer intentions from actions and provides the outline of the underlying computational mechanisms.     

神经细胞程序性坏死引发的哲学思考

神经细胞死亡曾被认为仅表现为坏死和凋亡。近来发现,不同的细胞死亡形式可以受相同的信号蛋白调节。对程序性坏死的新认识提示坏死与凋亡这两种传统意义上相互排斥的细胞死亡形式是可以互相转化的对立统一体。人们对复杂生命现象的认识虽存在局限性,但可随着科技的发展而不断深入。     

Visual neuroscience before the neuron

Visual neuroscience is considered to be a contemporary concern, based in large part on relating characteristics of neural functioning to visual experience. It presupposes a detailed knowledge of neural activity for which the neuron doctrine is a fundamental tenet. However, long before either the neuron doctrine had been advanced or the nerve cell had been described, attempts were made to estimate the dimensions of nerve fibres from measures of visual resolution. In the seventeenth century, the microscopes of Hooke and van Leeuwenhoek were unable to resolve structures as small as nerves adequately. However, it was not Hooke's microscope that led to an estimate of the dimensions of nerve fibres but his experiments on the limits of visual resolution. Hooke determined that a separation of one minute of arc was the minimum that could normally be seen. Descartes had earlier speculated that the retina consisted of the terminations of fibres of the optic nerve, and that their size defined the limits of what could be seen. Estimates of the diameters of nerve fibres were made on the basis of human visual acuity by Porterfield in 1738; he calculated the diameters of nerve fibres in the retina as one 7200th part of an inch (0.0035 mm), based on the resolution of one minute of arc as the minimum visible. In the same year, Jurin questioned the reliability of such estimates because of variations in visual resolution with different stimuli. The measurement of visual acuity was refined by Mayer in 1755, with dots, gratings, and grids used as stimuli. In the 1830s, Treviranus fused the microscopic and acuity approaches to determine the dimensions of nerve fibres. His indirect estimates of the dimensions of retinal fibres were close to those derived from microscopic observation. However, the suggestion that the retina consisted of terminations of nerve fibres influenced his detailed illustrations of its microscopic structure. Contrary to the situation that obtained after the microscopic structure of the retina had been established, a function of vision (acuity) was used to determine the dimensions of the structures (retinal elements) that were thought to mediate it.     

心灵如何被感知:从松果体到镜像神经元

文章从笛卡尔的身心交感论开始,探讨了松果体在身心交互中的重要地位,并分心理主义、行为主义、认知主义三个阶段,描述了心理学回答"心灵如何被感知"的两条途径:心灵内省与行为反映。最后,文章特别描述了新近发现的镜像神经元,认为它可能是当代心理学体系内的"笛卡尔式松果体",是沟通身体活动与心理状态、自我与他人心理状态的桥梁。未来,镜像神经元在心理学研究中的地位,可能与松果体在笛卡尔体系内的地位一样重要。