Mapping human brain activity in vivo.

A wide range of structural and functional techniques now exists to map the human brain in health and disease. These approaches span the gamut from external tomographic imaging devices (positron-emission tomography, single photon-emission computed tomography, magnetic resonance imaging, computed tomography), to surface detectors (electroencephalography, magnetoencephalography, transcranial magnetic stimulation), to measurements made directly on the brain''s surface or beneath it (intrinsic signal imaging, electrocorticography). The noninvasive methods have been combined to provide unique and previously unavailable insights into the macroscopic organization of the functional neuroanatomy of human vision, sensation, hearing, movement, language, learning, and memory. All methods have been applied to patients with neurologic, neurosurgical, and psychiatric disease and have provided a rapidly expanding knowledge of the pathophysiology of diseases such as epilepsy, cerebrovascular disease, neoplasms, neurodegenerative diseases, mental illness, and addiction states. In addition, these new methods have become a mainstay of preoperative surgical planning and the monitoring of pharmacologic or surgical (transplantation) interventions. Most recently, the ability to observe the reorganization of the human nervous system after acute injury, such as occurs with cerebral infarction or head trauma, or in the course of a progressive degenerative process such as Alzheimer''s or Parkinson''s disease, may provide new insights and methods in the rapidly expanding field of neurorehabilitation. Our newfound ability to generate maps and databases of human brain development, maturation, skill acquisition, aging, and disease states is both an exciting and formidable task.     

Noninvasive brain stimulation with transcranial magnetic or direct current stimulation (TMS/tDCS)-From insights into human memory to therapy of its dysfunction

Noninvasive stimulation of the brain by means of transcranial magnetic stimulation (TMS) or transcranial direct current stimulation (tDCS) has driven important discoveries in the field of human memory functions. Stand-alone or in combination with other brain mapping techniques noninvasive brain stimulation can assess issues such as location and timing of brain activity, connectivity and plasticity of neural circuits and functional relevance of a circumscribed brain area to a given cognitive task. In this emerging field, major advances in technology have been made in a relatively short period. New stimulation protocols and, especially, the progress in the application of tDCS have made it possible to obtain longer and much clearer inhibitory or facilitatory effects even after the stimulation has ceased. In this introductory review, we outline the basic principles, discuss technical limitations and describe how noninvasive brain stimulation can be used to study human memory functions in vivo. Though improvement of cognitive functions through noninvasive brain stimulation is promising, it still remains an exciting challenge to extend the use of TMS and tDCS from research tools in neuroscience to the treatment of neurological and psychiatric patients.     

Noninvasive brain stimulation with transcranial magnetic or direct current stimulation (TMS/tDCS)—From insights into human memory to therapy of its dysfunction

Noninvasive stimulation of the brain by means of transcranial magnetic stimulation (TMS) or transcranial direct current stimulation (tDCS) has driven important discoveries in the field of human memory functions. Stand-alone or in combination with other brain mapping techniques noninvasive brain stimulation can assess issues such as location and timing of brain activity, connectivity and plasticity of neural circuits and functional relevance of a circumscribed brain area to a given cognitive task. In this emerging field, major advances in technology have been made in a relatively short period. New stimulation protocols and, especially, the progress in the application of tDCS have made it possible to obtain longer and much clearer inhibitory or facilitatory effects even after the stimulation has ceased. In this introductory review, we outline the basic principles, discuss technical limitations and describe how noninvasive brain stimulation can be used to study human memory functions in vivo. Though improvement of cognitive functions through noninvasive brain stimulation is promising, it still remains an exciting challenge to extend the use of TMS and tDCS from research tools in neuroscience to the treatment of neurological and psychiatric patients.     

Current status of stem cell research: An editorial

The purpose of this editorial is to highlight recent developments in molecular biology tools and techniques in stem cell research and their applications to human diseases. Recent advancements in stem cell research and regenerative medicine are offering immense hope to cure human diseases and injuries, such as cancer, diabetes, Alzheimer's disease, Parkinson's disease, and traumatic brain injuries. In the last three decades, especially in the last decade, major breakthroughs have been seen in the conversion of adult stem cells into induced pluripotent stem cells, which in turn has led the way to developing stem cell therapies for human diseases. This article summarizes contributions of research into stem cell therapies.     

Transcranial Direct Current Stimulation of Right Dorsolateral Prefrontal Cortex Does Not Affect Model-Based or Model-Free Reinforcement Learning in Humans

There is broad consensus that the prefrontal cortex supports goal-directed, model-based decision-making. Consistent with this, we have recently shown that model-based control can be impaired through transcranial magnetic stimulation of right dorsolateral prefrontal cortex in humans. We hypothesized that an enhancement of model-based control might be achieved by anodal transcranial direct current stimulation of the same region. We tested 22 healthy adult human participants in a within-subject, double-blind design in which participants were given Active or Sham stimulation over two sessions. We show Active stimulation had no effect on model-based control or on model-free (‘habitual’) control compared to Sham stimulation. These null effects are substantiated by a power analysis, which suggests that our study had at least 60% power to detect a true effect, and by a Bayesian model comparison, which favors a model of the data that assumes stimulation had no effect over models that assume stimulation had an effect on behavioral control. Although we cannot entirely exclude more trivial explanations for our null effect, for example related to (faults in) our experimental setup, these data suggest that anodal transcranial direct current stimulation over right dorsolateral prefrontal cortex does not improve model-based control, despite existing evidence that transcranial magnetic stimulation can disrupt such control in the same brain region.     

太赫兹刺激听神经的测试平台搭建

目的 近年来，用于脑功能调控的神经调控技术蓬勃发展，很多方法已在临床上被推广应用，主要包括电极深部脑刺激、经颅磁刺激、光遗传技术、超声深脑刺激等。但是这些调控技术存在刺激靶点改变灵活性差、空间分辨率不足、需要注射病毒转染等问题。与这些技术相比，太赫兹波调控则能以较高的时空分辨率、无需引入外源基因的方式对神经活动进行干预。激光神经刺激是一种具有较明确靶向性的刺激方法，可以通过调整不同激光参数（激光波长、脉冲能量等）控制引起神经兴奋或者抑制。但是由于该研究方向的实验手段和实验平台的缺乏，相关研究开展较少。方法 针对这个问题，从听觉神经入手，在分子、细胞和在体不同层面为相关领域的研究搭建了不同的测试平台。结果 实验结果表明，这些系统在时间和空间上具有良好的耦合性和靶向性，测得的信号受噪音干扰小。结论 这些系统可以有效测试神经系统对太赫兹刺激的响应并精确控制刺激时间和位置。     

Studies on magnetism and bioelectromagnetics for 45 years: from magnetic analog memory to human brain stimulation and imaging

Forty-five years of studies on magnetism and bioelectromagnetics, in our laboratory, are presented. This article is prepared for the d'Arsonval Award Lecture. After a short introduction of our early work on magnetic analog memory, we review and discuss the following topics: (1) Magnetic nerve stimulation and localized transcranial magnetic stimulation (TMS) of the human brain by figure-eight coils; (2) Measurements of weak magnetic fields generated from the brain by superconducting quantum interference device (SQUID) systems, called magnetoencephalography (MEG), and its application in functional brain studies; (3) New methods of magnetic resonance imaging (MRI) for the imaging of impedance of the brain, called impedance MRI, and the imaging of neuronal current activities in the brain, called current MRI; (4) Cancer therapy and other medical treatments by pulsed magnetic fields; (5) Effects of static magnetic fields and magnetic control of cell orientation and cell growth; and (6) Effects of radio frequency magnetic fields and control of iron ion release and uptake from and into ferritins, iron cage proteins. These bioelectromagnetic studies have opened new horizons in magnetism and medicine, in particular for brain research and treatment of ailments such as depression, Parkinson's, and Alzheimer's diseases.     

Influence of Anodal Transcranial Direct Current Stimulation (tDCS) over the Right Angular Gyrus on Brain Activity during Rest

Although numerous studies examined resting-state networks (RSN) in the human brain, so far little is known about how activity within RSN might be modulated by non-invasive brain stimulation applied over parietal cortex. Investigating changes in RSN in response to parietal cortex stimulation might tell us more about how non-invasive techniques such as transcranial direct current stimulation (tDCS) modulate intrinsic brain activity, and further elaborate our understanding of how the resting brain responds to external stimulation. Here we examined how activity within the canonical RSN changed in response to anodal tDCS applied over the right angular gyrus (AG). We hypothesized that changes in resting-state activity can be induced by a single tDCS session and detected with functional magnetic resonance imaging (fMRI). Significant differences between two fMRI sessions (pre-tDCS and post-tDCS) were found in several RSN, including the cerebellar, medial visual, sensorimotor, right frontoparietal, and executive control RSN as well as the default mode and the task positive network. The present results revealed decreased and increased RSN activity following tDCS. Decreased RSN activity following tDCS was found in bilateral primary and secondary visual areas, and in the right putamen. Increased RSN activity following tDCS was widely distributed across the brain, covering thalamic, frontal, parietal and occipital regions. From these exploratory results we conclude that a single session of anodal tDCS over the right AG is sufficient to induce large-scale changes in resting-state activity. These changes were localized in sensory and cognitive areas, covering regions close to and distant from the stimulation site.     

时域相干刺激研究进展

脑深部电刺激已成为许多神经和精神疾病的有效治疗方法。然而,侵入性的电极植入会带来手术并发症的风险,并且刺激靶区在植入后很难改变。经颅磁刺激和经颅电刺激等非侵入性刺激方法为调节大脑功能提供了新的途径。但是,尚未证明这些非侵入性脑刺激方法可以直接调节脑深部神经元活动而不影响皮层神经元。因此,这些方法主要用于调节大脑表层脑区的神经活动。时域相干（temporal interference,TI）刺激是通过两个高频电场相互作用,产生低频包络调节神经活动的一种非侵入式脑深部电刺激的新方法,该方法有望解决无创脑深部刺激的需求。本文首先介绍TI刺激的概念以及安全性,然后阐述TI刺激现有研究中的电场分析方法,并讨论电场分析相关的生理模型建模方法和仿真平台以及TI刺激诱发场分布的研究进展与在动物和人体中的应用进展。最后,本文展望了TI刺激技术未来发展方向,以期为无创脑深部刺激研究提供新的研究思路。     

精准定位脑刺激对运动功能调控研究进展

脑刺激是神经科学研究的重要手段,传统的经颅磁刺激和经颅电刺激等脑刺激方法尽管能调控运动功能(包括减轻运动性障碍疾病的运动障碍、提高运动能力等),但存在空间分辨率低且无法刺激深部脑组织的局限性.近年来迅速发展的深部脑刺激(deep brain stimulation,DBS)、光遗传学、经颅超声刺激(transcranial ultrasound stimulation,TUS)、时间干涉(temporal interference,TI)等精准定位脑刺激方法,具有空间分辨率高、可聚焦深部脑组织等优点.本文综述了上述几种脑刺激方法的原理、特点,对运动功能调控的研究进展,以及面临的挑战和发展前景,从而为神经科学研究提供更好的研究工具,为临床实践提供更多的干预治疗手段.     

Modulation of Cortical Oscillations by Low-Frequency Direct Cortical Stimulation Is State-Dependent

Cortical oscillations play a fundamental role in organizing large-scale functional brain networks. Noninvasive brain stimulation with temporally patterned waveforms such as repetitive transcranial magnetic stimulation (rTMS) and transcranial alternating current stimulation (tACS) have been proposed to modulate these oscillations. Thus, these stimulation modalities represent promising new approaches for the treatment of psychiatric illnesses in which these oscillations are impaired. However, the mechanism by which periodic brain stimulation alters endogenous oscillation dynamics is debated and appears to depend on brain state. Here, we demonstrate with a static model and a neural oscillator model that recurrent excitation in the thalamo-cortical circuit, together with recruitment of cortico-cortical connections, can explain the enhancement of oscillations by brain stimulation as a function of brain state. We then performed concurrent invasive recording and stimulation of the human cortical surface to elucidate the response of cortical oscillations to periodic stimulation and support the findings from the computational models. We found that (1) stimulation enhanced the targeted oscillation power, (2) this enhancement outlasted stimulation, and (3) the effect of stimulation depended on behavioral state. Together, our results show successful target engagement of oscillations by periodic brain stimulation and highlight the role of nonlinear interaction between endogenous network oscillations and stimulation. These mechanistic insights will contribute to the design of adaptive, more targeted stimulation paradigms.     

High-Frequency TRNS Reduces BOLD Activity during Visuomotor Learning

Transcranial direct current stimulation (tDCS) and transcranial random noise stimulation (tRNS) consist in the application of electrical current of small intensity through the scalp, able to modulate perceptual and motor learning, probably by changing brain excitability. We investigated the effects of these transcranial electrical stimulation techniques in the early and later stages of visuomotor learning, as well as associated brain activity changes using functional magnetic resonance imaging (fMRI). We applied anodal and cathodal tDCS, low-frequency and high-frequency tRNS (lf-tRNS, 0.1–100 Hz; hf-tRNS 101–640 Hz, respectively) and sham stimulation over the primary motor cortex (M1) during the first 10 minutes of a visuomotor learning paradigm and measured performance changes for 20 minutes after stimulation ceased. Functional imaging scans were acquired throughout the whole experiment. Cathodal tDCS and hf-tRNS showed a tendency to improve and lf-tRNS to hinder early learning during stimulation, an effect that remained for 20 minutes after cessation of stimulation in the late learning phase. Motor learning-related activity decreased in several regions as reported previously, however, there was no significant modulation of brain activity by tDCS. In opposition to this, hf-tRNS was associated with reduced motor task-related-activity bilaterally in the frontal cortex and precuneous, probably due to interaction with ongoing neuronal oscillations. This result highlights the potential of lf-tRNS and hf-tRNS to differentially modulate visuomotor learning and advances our knowledge on neuroplasticity induction approaches combined with functional imaging methods.     

Toward establishing a therapeutic window for rTMS by theta burst stimulation

In this issue of Neuron, Huang et al. show that a version of the classic theta burst stimulation protocol used to induce LTP/LTD in brain slices can be adapted to a transcranial magnetic stimulation (TMS) protocol to rapidly produce long lasting (up to an hour), reversible effects on motor cortex physiology and behavior. These results may have important implications for the development of clinical applications of rTMS in the treatment of depression, epilepsy, Parkinson's, and other diseases.     

Theta burst stimulation of the human motor cortex

It has been 30 years since the discovery that repeated electrical stimulation of neural pathways can lead to long-term potentiation in hippocampal slices. With its relevance to processes such as learning and memory, the technique has produced a vast literature on mechanisms of synaptic plasticity in animal models. To date, the most promising method for transferring these methods to humans is repetitive transcranial magnetic stimulation (rTMS), a noninvasive method of stimulating neural pathways in the brain of conscious subjects through the intact scalp. However, effects on synaptic plasticity reported are often weak, highly variable between individuals, and rarely last longer than 30 min. Here we describe a very rapid method of conditioning the human motor cortex using rTMS that produces a controllable, consistent, long-lasting, and powerful effect on motor cortex physiology and behavior after an application period of only 20-190 s.     

诱导神经再生治疗阿尔茨海默病的机制研究进展

阿尔茨海默病(Alzheimer’s disease,AD)是一种以进行性认知障碍和记忆减退为主要特征的中枢神经退行性疾病,已经成为老年医学中最棘手的、亟待解决的问题之一. AD的病理机制仍不清楚,尚无特效治疗药物.目前,探索AD神经再生逐渐成为研究的热点领域,通过诱导神经再生可以有效地改善AD的症状.研究表明,运用药物、物理刺激或干细胞移植方法,可以提高大脑成体神经再生,是延缓AD的病理症状和认知障碍的有效治疗策略.本文综述诱导神经再生的方法及其治疗AD的作用机制,为神经再生治疗实施提供理论依据.     

Calcium signaling in neurodegeneration

Calcium is a key signaling ion involved in many different intracellular and extracellular processes ranging from synaptic activity to cell-cell communication and adhesion. The exact definition at the molecular level of the versatility of this ion has made overwhelming progress in the past several years and has been extensively reviewed. In the brain, calcium is fundamental in the control of synaptic activity and memory formation, a process that leads to the activation of specific calcium-dependent signal transduction pathways and implicates key protein effectors, such as CaMKs, MAPK/ERKs, and CREB. Properly controlled homeostasis of calcium signaling not only supports normal brain physiology but also maintains neuronal integrity and long-term cell survival. Emerging knowledge indicates that calcium homeostasis is not only critical for cell physiology and health, but also, when deregulated, can lead to neurodegeneration via complex and diverse mechanisms involved in selective neuronal impairments and death. The identification of several modulators of calcium homeostasis, such as presenilins and CALHM1, as potential factors involved in the pathogenesis of Alzheimer's disease, provides strong support for a role of calcium in neurodegeneration. These observations represent an important step towards understanding the molecular mechanisms of calcium signaling disturbances observed in different brain diseases such as Alzheimer's, Parkinson's, and Huntington's diseases.     

Mouse models in neurological disorders: Applications of non-invasive imaging

Neuroimaging techniques represent powerful tools to assess disease-specific cellular, biochemical and molecular processes non-invasively in vivo. Besides providing precise anatomical localisation and quantification, the most exciting advantage of non-invasive imaging techniques is the opportunity to investigate the spatial and temporal dynamics of disease-specific functional and molecular events longitudinally in intact living organisms, so called molecular imaging (MI). Combining neuroimaging technologies with in vivo models of neurological disorders provides unique opportunities to understand the aetiology and pathophysiology of human neurological disorders. In this way, neuroimaging in mouse models of neurological disorders not only can be used for phenotyping specific diseases and monitoring disease progression but also plays an essential role in the development and evaluation of disease-specific treatment approaches. In this way MI is a key technology in translational research, helping to design improved disease models as well as experimental treatment protocols that may afterwards be implemented into clinical routine. The most widely used imaging modalities in animal models to assess in vivo anatomical, functional and molecular events are positron emission tomography (PET), magnetic resonance imaging (MRI) and optical imaging (OI). Here, we review the application of neuroimaging in mouse models of neurodegeneration (Parkinson's disease, PD, and Alzheimer's disease, AD) and brain cancer (glioma).     

Ultrasonic neuromodulation by brain stimulation with transcranial ultrasound

Brain stimulation methods are indispensable to the study of brain function. They have also proven effective for treating some neurological disorders. Historically used for medical imaging, ultrasound (US) has recently been shown to be capable of noninvasively stimulating brain activity. Here we provide a general protocol for the stimulation of intact mouse brain circuits using transcranial US, and, using a traditional mouse model of epilepsy, we describe how to use transcranial US to disrupt electrographic seizure activity. The advantages of US for brain stimulation are that it does not necessitate surgery or genetic alteration, but it confers spatial resolutions superior to other noninvasive methods such as transcranial magnetic stimulation. With a basic working knowledge of electrophysiology, and after an initial setup, ultrasonic neuromodulation (UNMOD) can be implemented in less than 1 h. Using the general protocol that we describe, UNMOD can be readily adapted to support a broad range of studies on brain circuit function and dysfunction.     

经颅电刺激镇痛研究的现状及展望

经颅电刺激技术是一种非侵入性神经调控方法,因其具有卓越的安全性、良好的患者依从性以及高度便携性等特点,被视为一种潜在的非药物镇痛手段。然而,目前对于经颅电刺激镇痛效果的研究结果不一致且镇痛机制尚未完全阐明。本文通过系统归纳总结3种主要的经颅电刺激技术——经颅直流电刺激、经颅交流电刺激和经颅随机噪声刺激——在镇痛领域的研究进展,评估了这些技术对短时、急性和慢性疼痛的镇痛效果,并深入剖析了其潜在的镇痛机制。同时,本文系统讨论了既往研究的局限性,并对未来研究提出了一系列切实可行的建议,如借助电场模拟技术实现个性化刺激以克服不同个体头部解剖结构差异的影响、应用多位点刺激和深部脑刺激技术来拓展刺激脑区、搭建经颅电刺激技术同步神经影像平台以制定个体特异性的刺激方案并深入揭示其镇痛机制、探索与其他治疗技术的联合应用以提高疗效等。这些建议的实施将有助于解决当前研究中存在的问题,充分发挥经颅电刺激在疼痛治疗中的临床价值,最终实现患者疼痛的缓解。     

Variability of perceptual multistability: from brain state to individual trait

Few phenomena are as suitable as perceptual multistability to demonstrate that the brain constructively interprets sensory input. Several studies have outlined the neural circuitry involved in generating perceptual inference but only more recently has the individual variability of this inferential process been appreciated. Studies of the interaction of evoked and ongoing neural activity show that inference itself is not merely a stimulus-triggered process but is related to the context of the current brain state into which the processing of external stimulation is embedded. As brain states fluctuate, so does perception of a given sensory input. In multistability, perceptual fluctuation rates are consistent for a given individual but vary considerably between individuals. There has been some evidence for a genetic basis for these individual differences and recent morphometric studies of parietal lobe regions have identified neuroanatomical substrates for individual variability in spontaneous switching behaviour. Moreover, disrupting the function of these latter regions by transcranial magnetic stimulation yields systematic interference effects on switching behaviour, further arguing for a causal role of these regions in perceptual inference. Together, these studies have advanced our understanding of the biological mechanisms by which the brain constructs the contents of consciousness from sensory input.