从神经可塑性的视角看压力与疾病的关系

压力致病是一个复杂的过程,涉及到与多种致病因素的相互作用、多个器官系统的激活和反馈、不同发育阶段对疾病的易感性等.这个过程中,神经可塑性起着重要的调节作用.本文以神经可塑性为切入点,阐述了压力、发育阶段、个人发展、疾病发生之间的关系.     

应对方式与认知训练对青少年情绪障碍易感性的影响

以往研究指出青少年阶段是情绪障碍的高发时期, 各种情绪问题深刻影响青少年的身心健康。通过文献分析得出青春期压力所采取的应对方式(即个体对压力事件做出反应的稳定方式)可能是决定青少年情绪障碍易感程度的核心因素; 而认知训练可降低该易感性, 从而提高青少年的心理健康水平。为了验证上述观点, 综合采用行为调查与生理测量, EEG/ERP与fMRI手段, 拟开展如下4个方面的研究工作：1)青春期发育阶段影响个体负性情绪易感性的大脑机制; 2)认知应对方式与青春期发育阶段的交互作用对负性情绪易感性的影响及大脑机制; 3)认知训练(包括注意训练、解释训练与接受训练)对健康青少年负面情绪易感性的调节作用及大脑可塑性机制; 4)认知训练对青少年抑郁/焦虑症患者情绪应对方式与临床症状的影响及大脑可塑性机制。通过上述系列研究, 揭示青少年更高情绪障碍易感性的认知神经机制, 找出并培养有利于青少年身心健康的情绪应对方法, 从而为情绪障碍的临床治疗奠定理论与实践基础。     

情绪神经回路的可塑性

从两个方面介绍了近年来关于情绪神经回路可塑性的研究进展：（1）情绪神经回路中各主要脑区（包括前额叶、杏仁核等）的可塑性及其相互影响;（2）情绪神经回路可塑性的影响因素,包括情绪学习、早期环境和经历以及抚养者的情绪状态等。文章最后还对情绪神经回路可塑性的研究方法及未来的研究方向进行了探讨     

抑郁症的心理神经免疫学研究：细胞因子的作用

免疫系统在一些心理精神障碍中具有重要作用,抑郁症可看作是一种心理神经免疫紊乱性疾病。生理应激和心理应激能激活免疫系统,导致细胞因子的产生,从而影响中枢神经系统的多个方面,包括神经递质代谢、神经内分泌功能、神经可塑性以及与行为改变有关的信息过程。细胞因子不仅由免疫活性细胞分泌,也能被神经胶质细胞和神经细胞合成和分泌,它在抑郁症中的作用可能会在揭示抑郁障碍机制上有新突破,并可能作为今后药物治疗的靶点进入临床领域     

非面孔物体倒置效应形成过程的认知神经机制

物体识别, 尤其是人造新异物体专家识别形成过程的神经机制是了解大脑可塑性的一个重要窗口。当前, 从行为学上或神经机制上探讨物体特定角度体验程度与物体专家识别形成关系的研究较少, 本项目采用事件相关电位与行为训练相结合的方法, 分别选择在社会生活中自然形成的某类物体识别专家和经人为训练形成的人造新异物体识别专家作为被试, 研究非面孔物体识别倒置效应从无到有、从小到大整个过程的脑机制。通过对倒置效应大小的操纵, 分离出专家识别状态下的ERP成分, 并分析专家识别形成过程的脑电动态变化过程, 探讨非面孔物体识别大脑可塑性变化的神经机制。在上述研究的基础上, 研究者试图提出物体特定角度体验程度与物体识别加工方式选择关系模型并完善当前物体识别整体布局加工连续量假设(configural processing continuum)理论。     

智能发育与退化的神经网络基础

智能是人类最有特色的行为,正是通过智能活动,人类对自然环境进行了杰出的控制。智能与大脑皮层中大量的神经回路有关。本文讨论了智能赖以存在的基础-神经系统的发育,形成构筑和退化的过程,及其与智能的关系。神经生长锥的延长,分支,迁移到射靶运动,导致突触的形成和可塑性到神经联系的建立,关注局部神经回路到功能神经网络的形态构筑和功能特点,以及神经网络损伤对智能的影响。     

评述早期儿童认知发展的神经科学研究

神经科学的迅猛发展,尤其是神经科学新的研究手段的广泛运用,使得神经科学在儿童早期认知发展的神经机制研究中取得了长足的进展。本文主要涉及神经发育中神经系统的可塑性、关键期,以及知觉、注意、记忆和空间认知等认知发展诸多方面的神经机制。     

音乐表演训练对神经可塑性的影响:元分析研究

音乐表演是人类最复杂和精细的技能之一。通过激活似然性评估元分析,对音乐表演训练所诱发的神经可塑性进行探究。结果发现,音乐表演者与非音乐家在左侧小脑、双侧中央前回、双侧颞上回、左侧额下回、双侧顶下小叶以及右侧脑岛等脑区存在差异。这些脑区与听觉、运动以及多通道信息整合等加工有关。未来研究应从不同音乐表演训练诱发的神经适应性出发,进一步探究音乐表演训练与大脑可塑性之间的关联。     

NMDA受体的结构与药理学特性

NMDA受体是一类离子型谷氨酸受体,其功能主要参与发育过程中神经回路的细化及触发多种形式的突触可塑性。近年来的证据表明,组成NMDA受体的亚单位有着复杂的生理学和药理学特性;NMDA受体的数量、分布和亚单位组成并非一成不变,而是在发育过程中、神经元活动时,以一种细胞特异性和突触特异性的方式变化着。这种NMDA受体的双向变化是突触可塑性重塑的基础,而其调节的异常又可导致神经-精神疾病的发生,如可卡因成瘾、精神分裂症等     

非安全依恋可塑性的神经机制

非安全依恋可塑性是借助认知启动技术(例如安全依恋启动)使非安全依恋个体长期处于敏感和支持性的环境中, 从而唤醒个体积极的依恋经历, 使其对依恋关系形成新的认知图式, 最终实现非安全依恋个体内部工作模型的重构。本项目针对非安全依恋个体的认知加工缺陷, 采用安全依恋启动的方法探索非安全依恋可塑性的发生机制及相应的神经生理基础。项目拟从单次安全依恋启动对非安全依恋个体认知加工缺陷的改善效应、多任务条件下对重复安全启动效应的检验以及重复安全依恋启动效应的追踪研究三方面开展非安全依恋可塑性研究; 研究手段采用行为-生理-脑成像的技术, 从安全依恋启动的性质、方式和时间三个维度上系统地探究非安全依恋可塑性的发生机制与神经基础。非安全依恋可塑性研究为安全依恋研究提供了新视角, 研究提出的依恋图式重构理论是对安全基地图式理论的印证与发展, 对重复安全启动效应的检验及追踪研究试图为非安全依恋可塑性研究构建一套科学有效的评估标准。研究成果对于非安全依恋人群的干预训练、提升依恋安全感、维护心理健康具有重要价值。     

The cerebral,extra-cerebral bodily,and socio-cultural dimensions of enculturated arithmetical cognition

Arithmetical cognition is the result of enculturation. On a personal level of analysis, enculturation is a process of structured cultural learning that leads to the acquisition of evolutionarily recent, socio-culturally shaped arithmetical practices. On a sub-personal level, enculturation is realized by learning driven plasticity and learning driven bodily adaptability, which leads to the emergence of new neural circuitry and bodily action patterns. While learning driven plasticity in the case of arithmetical practices is not consistent with modularist theories of mental architecture, it can be enriched by the theory of neural reuse. According to neural reuse, cerebral regions are reused to contribute to multiple neural circuits in functionally constrained ways throughout ontogeny. By hypothesis, learning driven plasticity is complemented by learning driven bodily adaptability, which suggests that there is an interesting functional relationship between finger gnosis, finger counting, and arithmetical practices. The emerging perspective on enculturated arithmetical cognition will be complemented by considerations on associated developmental and acquired disorders, namely developmental dyscalculia and acquired acalculia. The upshot is that we need to take the cerebral, extra-cerebral bodily, and socio-cultural dimensions of enculturation into account in order to arrive at a better understanding of the phylogenetic and ontogenetic conditions of arithmetical cognition.

     

Ontogenetic changes in the neural mechanisms of eyeblink conditioning

The rodent eyeblink conditioning paradigm is an ideal model system for examining the relationship between neural maturation and the ontogeny of associative learning. Elucidation of the neural mechanisms underlying the ontogeny of learning is tractable using eyeblink conditioning because the necessary neural circuitry (cerebellum and interconnected brainstem nuclei) underlying the acquisition and retention of the conditioned response (CR) has been identified in adult organisms. Moreover, the cerebellum exhibits substantial postnatal anatomical and physiological maturation in rats. The eyeblink CR emerges developmentally between postnatal day (PND) 17 and 24 in rats. A series of experiments found that the ontogenetic emergence of eyeblink conditioning is related to the development of associative learning and not related to changes in performance. More recent studies have examined the relationship between the development of eyeblink conditioning and the physiological maturation of the cerebellum, a brain structure that is necessary for eyeblink conditioning in adult organisms. Disrupting cerebellar development with lesions or antimitotic treatments impairs the ontogeny of eyeblink conditioning. Studies of the development of physiological processes within the cerebellum have revealed striking ontogenetic changes in stimulus-elicited and learning-related neuronal activity. Neurons in the interpositus nucleus and Purkinje cells in the cortex exhibit developmental increases in neuronal discharges following the unconditioned stimulus (US) and in neuronal discharges that model the amplitude and time-course of the eyeblink CR. The developmental changes in CR-related neuronal activity in the cerebellum suggest that the ontogeny of eyeblink conditioning depends on the development of mechanisms that estavlish cerebellar plasticity. Learning and the induction of neural plasticity depend on the magnitude of the US input to the cerebellum. The role of developmental changes in the efficacy of the US pathway has been investigated by monitoring neuronal activity in the inferior olive and with stimulation techniques. The results of these experiments indicate that the development of the conditioned eyeblink response may depend on dynamic interactions between multiple developmental processes within the eyeblink neural circuitry.     

脑信号导向蛋白Semaphorins3F与难治性癫痫

在神经发育过程中Semaphorins为轴突导向和神经细胞的迁移提供导向信息。这些导向分子通过抑制自发的或异常的轴突生长来维持己建立的神经连接,并参与突触可塑性以及中枢神经受损后抑制神经再生与神经细胞的死亡。目前,虽然对Semaphorins在神经发育、成熟及受损不同阶段中的功能己有初步的了解,但Semaphorins其受体多样,尚无法预测Sema-phorins与其受体的结合将产生的生物学效应以及Semaphorins在神经系统中起作用的分子机制。进一步研究Semaphorins对癫痫、精神分裂、老年痴呆症等神经系统性疾病的治疗具有深远意义。     

Ontogenetic Changes in the Neural Mechanisms of Eyeblink Conditioning

The rodent eyeblink conditioning paradigm is an ideal model system for examining the relationship between neural maturation and the ontogeny of associative learning. Elucidation of the neural mechanisms underlying the ontogeny of learning is tractable using eyeblink conditioning because the necessary neural circuitry (cerebellum and interconnected brainstem nuclei) underlying the acquisition and retention of the conditioned response (CR) has been identified in adult organisms. Moreover, the cerebellum exhibits substantial postnatal anatomical and physiological maturation in rats. The eyeblink CR emerges developmentally between postnatal day (PND) 17 and 24 in rats. A series of experiments found that the ontogenetic emergence of eyeblink conditioning is related to the development of associative learning and not related to changes in performance. More recent studies have examined the relationship between the development of eyeblink conditioning and the physiological maturation of the cerebellum, a brain structure that is necessary for eyeblink conditioning in adult organisms. Disrupting cerebellar development with lesions or antimitotic treatments impairs the ontogeny of eyeblink conditioning. Studies of the development of physiological processes within the cerebellum have revealed striking ontogenetic changes in stimulus-elicited and learning-related neuronal activity. Neurons in the interpositus nucleus and Purkinje cells in the cortex exhibit developmental increases in neuronal discharges following the unconditioned stimulus (US) and in neuronal discharges that model the amplitude and time-course of the eyeblink CR. The developmental changes in CR-related neuronal activity in the cerebellum suggest that the ontogeny of eyeblink conditioning depends on the development of mechanisms that establish cerebellar plasticity. Learning and the induction of neural plasticity depend on the magnitude of the US input to the cerebellum. The role of developmental changes in the efficacy of the US pathway has been investigated by monitoring neuronal activity in the inferior olive and with stimulation techniques. The results of these experiments indicate that the development of the conditioned eyeblink response may depend on dynamic interactions between multiple developmental processes within the eyeblink neural circuitry.     

脑可塑性研究综述

本文简要总结了脑可塑性实验研究的三个方面：(1)脑损伤的研究,(2)学习和训练的脑可塑研究,(3)双语习得的研究。目前研究脑可塑的一个重要方向是通过学习和训练,考察认知成分的获得与大脑皮层活动状态变化之间的关系。这些研究说明大脑的成熟是一个动态发展的过程,它的结构和功能在一定程度上具有可塑性。     

Applying cognitive training to target executive functions during early development

Developmental psychopathology is increasingly recognizing the importance of distinguishing causal processes (i.e., the mechanisms that cause a disease) from developmental outcomes (i.e., the symptoms of the disorder as it is eventually diagnosed). Targeting causal processes early in disordered development may be more effective than waiting until outcomes are established and then trying to reverse the pathogenic process. In this review, I evaluate evidence suggesting that neural and behavioral plasticity may be greatest at very early stages of development. I also describe correlational evidence suggesting that, across a number of conditions, early emerging individual differences in attentional control and working memory may play a role in mediating later-developing differences in academic and other forms of learning. I review the currently small number of studies that applied direct and indirect cognitive training targeted at young individuals and discuss methodological challenges associated with targeting this age group. I also discuss a number of ways in which early, targeted cognitive training may be used to help us understand the developmental mechanisms subserving typical and atypical cognitive development.     

发展性协调障碍的神经机制

发展性协调障碍是一种特殊的发育障碍, 它的一个显著特征是动作协调困难, 这种障碍影响着5%~8%学龄儿童的学业成绩和日常生活。发展性协调障碍常常与其他类型的学习困难并存。发展性协调障碍的病因非常复杂, 这种障碍与一定程度的视觉空间认知能力受损有关, 早期精细运动技能发育与脑神经发育进程可能存在时间的重合。近年来, 研究者们试图探索影响发展性协调障碍的神经基础, 并先后提出不同的神经关联假说。这些理论假说主要涉及到小脑、顶叶、胼胝体、基底神经节和大脑白质等脑区。本文全面回顾了该领域研究的最新进展, 并提出未来研究应该关注的方向与问题。     

Multiple realization and methodological pluralism

Multiple realization was once taken to be a challenge to reductionist visions, especially within cognitive science, and a foundation of the “antireductionist consensus.” More recently, multiple realization has come to be challenged on naturalistic grounds, as well as on more “metaphysical” grounds. Within cognitive science, one focal issue concerns the role of neural plasticity for addressing these issues. If reorganization maintains the same cognitive functions, that supports claims for multiple realization. I take up the reorganization involved in language dysfunctions to deal with questions concerned with multiple realization and neural plasticity. Beginning with Broca’s case for localization and the nineteenth century discussion of “reorganization,” and returning to more recent evidence for neural plasticity, I argue that, in the end, there is substantial support for multiple realization in cognitive systems; I further argue that this is wholly consistent with a recognition of methodological pluralism in cognitive science.     

Training the brain: practical applications of neural plasticity from the intersection of cognitive neuroscience, developmental psychology, and prevention science

Prior researchers have shown that the brain has a remarkable ability for adapting to environmental changes. The positive effects of such neural plasticity include enhanced functioning in specific cognitive domains and shifts in cortical representation following naturally occurring cases of sensory deprivation; however, maladaptive changes in brain function and development owing to early developmental adversity and stress have also been well documented. Researchers examining enriched rearing environments in animals have revealed the potential for inducing positive brain plasticity effects and have helped to popularize methods for training the brain to reverse early brain deficits or to boost normal cognitive functioning. In this article, two classes of empirically based methods of brain training in children are reviewed and critiqued: laboratory-based, mental process training paradigms and ecological interventions based upon neurocognitive conceptual models. Given the susceptibility of executive function disruption, special attention is paid to training programs that emphasize executive function enhancement. In addition, a third approach to brain training, aimed at tapping into compensatory processes, is postulated. Study results showing the effectiveness of this strategy in the field of neurorehabilitation and in terms of naturally occurring compensatory processing in human aging lend credence to the potential of this approach. (PsycINFO Database Record (c) 2012 APA, all rights reserved).     

Biocultural orchestration of developmental plasticity across levels: the interplay of biology and culture in shaping the mind and behavior across the life span

The author reviews reemerging coconstructive conceptions of development and recent empirical findings of developmental plasticity at different levels spanning several fields of developmental and life sciences. A cross-level dynamic biocultural coconstructive framework is endorsed to understand cognitive and behavioral development across the life span. This framework integrates main conceptions of earlier views into a unifying frame, viewing the dynamics of life span development as occurring simultaneously within different time scales (i.e., moment-to-moment microgenesis, life span ontogeny, and human phylogeny) and encompassing multiple levels (i.e., neurobiological, cognitive, behavioral, and sociocultural). Viewed through this metatheoretical framework, new insights of potential interfaces for reciprocal cultural and experiential influences to be integrated with behavioral genetics and cognitive neuroscience research can be more easily prescribed.