GABAergic modulation of DC stimulation-induced motor cortex excitability shifts in humans

Weak transcranial DC stimulation (tDCS) of the human motor cortex results in excitability shifts during and after the end of stimulation, which are most probably localized intracortically. Anodal stimulation enhances excitability, whereas cathodal stimulation reduces it. Although the after-effects of tDCS are NMDA receptor-dependent, nothing is known about the involvement of additional receptors. Here we show that pharmacological strengthening of GABAergic inhibition modulates selectively the after-effects elicited by anodal tDCS. Administration of the GABA(A) receptor agonist lorazepam resulted in a delayed, but then enhanced and prolonged anodal tDCS-induced excitability elevation. The initial absence of an excitability enhancement under lorazepam is most probably caused by a loss of the anodal tDCS-generated intracortical diminution of inhibition and enhancement of facilitation, which occurs without pharmacological intervention. The reasons for the late-occurring excitability enhancement remain unclear. Because intracortical inhibition and facilitation are not changed in this phase compared with pre-tDCS values, excitability changes originating from remote cortical or subcortical areas could be involved.     

Impaired modulation of motor cortex excitability by homonymous and heteronymous muscle afferents in focal hand dystonia.

A decrease of heteronymous median nerve-evoked inhibition of corticospinal projections to forearm extensor muscles was reported in a group of 10 dystonic patients by Bertolasi and colleagues in 2003. Here we tested the excitability of corticomotoneuronal connections to both wrist extensor (ECR) and flexor (FCR) muscles after conditioning stimulation of median and also radial nerve at rest in a group of 25 patients with focal hand dystonia compared to 20 healthy subjects. We also investigated the effect of the wrist dystonic posture, either in flexion or in extension, on the afferent modulation of ECR and FCR motor evolved potentials (MEPs). The heteronymous (median-induced) but also homonymous (radial-induced) inhibitions (interstimuli intervals 13-21 ms) of ECR MEP size observed in healthy subjects were decreased in patients. In addition, homonymous (median-induced) facilitation of FCR MEP size was also decreased in patients while heteronymous inhibition (radial-induced) was not. Neither the involvement of the target muscle in the dystonic posture nor the origin of the afferent volley (from a dystonic muscle) influenced the degree of impairment of afferent modulation of the MEP. These findings support the view that a global abnormal somatosensory coupling in focal hand dystonia may contribute to an inadequate motor command to wrist muscles.     

Parietal transcranial direct current stimulation modulates primary motor cortex excitability

The posterior parietal cortex is part of the cortical network involved in motor learning and is structurally and functionally connected with the primary motor cortex (M1). Neuroplastic alterations of neuronal connectivity might be an important basis for learning processes. These have however not been explored for parieto‐motor connections in humans by transcranial direct current stimulation (tDCS). Exploring tDCS effects on parieto‐motor cortical connectivity might be functionally relevant, because tDCS has been shown to improve motor learning. We aimed to explore plastic alterations of parieto‐motor cortical connections by tDCS in healthy humans. We measured neuroplastic changes of corticospinal excitability via motor evoked potentials (MEP) elicited by single‐pulse transcranial magnetic stimulation (TMS) before and after tDCS over the left posterior parietal cortex (P3), and 3 cm posterior or lateral to P3, to explore the spatial specificity of the effects. Furthermore, short‐interval intracortical inhibition/intracortical facilitation (SICI/ICF) over M1, and parieto‐motor cortical connectivity were obtained before and after P3 tDCS. The results show polarity‐dependent M1 excitability alterations primarily after P3 tDCS. Single‐pulse TMS‐elicited MEPs, M1 SICI/ICF at 5 and 7 ms and 10 and 15 ms interstimulus intervals (ISIs), and parieto‐motor connectivity at 10 and 15 ms ISIs were all enhanced by anodal stimulation. Single pulse‐TMS‐elicited MEPs, and parieto‐motor connectivity at 10 and 15 ms ISIs were reduced by cathodal tDCS. The respective corticospinal excitability alterations lasted for at least 120 min after stimulation. These results show an effect of remote stimulation of parietal areas on M1 excitability. The spatial specificity of the effects and the impact on parietal cortex–motor cortex connections suggest a relevant connectivity‐driven effect.     

Kick with the finger: symbolic actions shape motor cortex excitability

A large body of research indicates that observing actions made by others is associated with corresponding motor facilitation of the observer's corticospinal system. However, it is still controversial whether this matching mechanism strictly reflects the kinematics of the observed action or its meaning. To test this issue, motor evoked potentials induced by single‐pulse transcranial magnetic stimulation were recorded from hand and leg muscles while participants observed a symbolic action carried out with the index finger, but classically performed with the leg (i.e., a soccer penalty kick). A control condition in which participants observed a similar (but not symbolic) hand movement was also included. Results showed that motor facilitation occurs both in the observer's hand (first dorsal interosseous) and leg (quadriceps femoris) muscles. The present study provides evidence that both the kinematics and the symbolic value of an observed action are able to modulate motor cortex excitability. The human motor system is thus not only involved in mirroring observed actions but is also finely tuned to their symbolic value.     

Task‐dependent changes in late inhibitory and disinhibitory actions within the primary motor cortex in humans

The objective of the present study was to investigate the time course of long‐interval intracortical inhibition (LICI) and late cortical disinhibition (LCD) as a function of the motor task (index abduction, thumb–index precision grip). Motor‐evoked potentials were recorded from the first dorsal interosseus (FDI) muscle of the dominant limb in 13 healthy subjects. We used paired‐pulse transcranial magnetic stimulation (TMS) paradigms in which a test pulse was preceded by a suprathreshold priming pulse (130% of the resting motor threshold) with varying interstimulus intervals (ISIs). In each task, double pulses were delivered with ISIs ranging from 30% of the corresponding silent period (SP; ~ 45 ms) to 220% of the SP (~ 330 ms). In both tasks, we found that LICI was followed by LCD (namely a period of increased cortical excitability lasting until ~ 200% of the SP). The time‐dependent modulation of LICI and LCD differed in the two tasks; LICI was shorter (i.e. disinhibition occurred earlier) and LCD was more intense during precision grip than during index abduction. Long‐interval intracortical inhibition disappeared well before the end of the SP in the precision grip task, suggesting that the mechanisms underlying these two inhibitory phenomena are distinct. Our data suggest that disinhibition might reflect adaptation of neural circuit excitability to the functional requirements of the motor task.     

Intracortical excitability in the hand motor representation in hand dystonia and blepharospasm.

We sought to determine the activity of inhibiting and facilitating cortical circuits in areas surrounding a hand muscle motor representation in focal dystonia and in controls. In 15 patients with hand dystonia, 16 patients with blepharospasm, and age-matched controls, we applied suprathreshold transcranial magnetic stimuli with a figure-eight coil over the optimal representation of the relaxed abductor digiti minimi muscle of the dominant hand. Additional conditioning stimuli were given through a second figure-eight coil that was held either above the test coil or 2 cm or 4 cm apart in the anterior, posterior, lateral, or medial direction. We measured intracortical excitability in each of the nine positions of the conditioning coil. Intracortical inhibition was reduced in both patient groups at all conditioning coil positions. With both coils centered, the intracortical facilitation did not differ between patients and controls. After shifting the conditioning coil, the intracortical facilitation tended to be less diminished in patients than in controls, this difference between patients and controls was significant for the anterior, posterior, and medial 4-cm conditioning coil shift. Our results demonstrate decreased intracortical inhibition in the cortical hand muscle representation not only in patients with hand dystonia, but also in patients with blepharospasm. In addition, our findings in both patient groups show a trend toward a relatively increased intracortical facilitation in surrounding motor areas.     

Interhemispheric differences of hand muscle representation in human motor cortex

Focal magnetic transcranial stimulation (TCS) is employed for mapping of the motor cortical output to abductor digiti minimi (ADM) muscle. The aim of this study was to evaluate the interhemispheric asymmetries in normals. Motor maps were obtained through motor evoked potentials (MEPs) recordings from ADM muscle in 20 healthy subjects in right and left hemispheres TCS. Measurement of several indexes such as excitability threshold, MEPs amplitude, MEPs latency, and silent period duration did not show differences between the hemispheres. Moreover, no interhemispheric asymmetries were found when the amplitude ratio values were analyzed. The hand motor cortical area, as represented by the number of responsive sites (3.6 vs. 3.5) and the “hot spot” site localization presented a fairly symmetrical organization. Absolute values displayed a relatively wide intersubject variability, while their interhemispheric differences were extremely restricted. This observation can offer a new tool in diagnosing and following up neurological disorders affecting the central motor system, mainly for those concerning monohemispheric lesions. © 1997 John Wiley & Sons, Inc. Muscle Nerve, 20, 535–542, 1997.     

The human dorsal premotor cortex facilitates the excitability of ipsilateral primary motor cortex via a short latency cortico-cortical route

In non-human primates, invasive tracing and electrostimulation studies have identified strong ipsilateral cortico-cortical connections between dorsal premotor- (PMd) and the primary motor cortex (M1(HAND) ). Here, we applied dual-site transcranial magnetic stimulation (dsTMS) to left PMd and M1(HAND) through specifically designed minicoils to selectively probe ipsilateral PMd-to-M1(HAND) connectivity in humans. A suprathreshold test stimulus (TS) was applied to M1(HAND) producing a motor evoked potential (MEP) of about 0.5 mV in the relaxed right first dorsal interosseus muscle (FDI). A subthreshold conditioning stimulus (CS) was given to PMd 2.0-5.2 ms after the TS at intensities of 50-, 70-, or 90% of TS. The CS to PMd facilitated the MEP evoked by TS over M1(HAND) at interstimulus intervals (ISI) of 2.4 or 2.8 ms. There was a second facilitatory peak at ISI of 4.4 ms. PMd-to-M1(HAND) facilitation did not change as a function of CS intensity. Even at higher intensities, the CS alone failed to elicit a MEP or a cortical silent period in the pre-activated FDI, excluding a direct spread of excitation from PMd to M1(HAND). No MEP facilitation was present while CS was applied rostrally over lateral prefrontal cortex. Together our results indicate that our dsTMS paradigm probes a short-latency facilitatory PMd-to-M1(HAND) pathway. The temporal pattern of MEP facilitation suggests a PMd-to-M1(HAND) route that targets intracortical M1(HAND) circuits involved in the generation of indirect corticospinal volleys. This paradigm opens up new possibilities to study context-dependent intrahemispheric PMd-to-M1(HAND) interactions in the intact human brain.     

Focal enhancement of motor cortex excitability during motor imagery: a transcranial magnetic stimulation study

OBJECTIVES: In order to learn more about the physiology of the motor cortex during motor imagery, we evaluated the changes in excitability of two different hand muscle representations in the primary motor cortex (M1) of both hemispheres during two imagery conditions. MATERIALS AND METHODS: We applied focal transcranial magnetic stimulation (TMS) over each M1, recording motor evoked potentials (MEPs) from the contralateral abductor pollicis brevis (APB) and first dorsal interosseus (FDI) muscles during rest, imagery of contralateral thumb abduction (C-APB), and imagery of ipsilateral thumb abduction (I-APB). We obtained measures of motor threshold (MT), MEP recruitment curve (MEP-rc) and F waves. RESULTS: Motor imagery compared with rest significantly decreased the MT and increased MEPs amplitude at stimulation intensities clearly above MT in condition C-APB, but not in condition I-APB. These effects were not significantly different between right and left hemisphere. MEPs simultaneously recorded from the FDI, which was not involved in the task, did not show facilitatory effects. There were no significant changes in F wave amplitude during motor imagery compared with rest. CONCLUSIONS: Imagery of unilateral simple movements is associated with increased excitability only of a highly specific representation in the contralateral M1 and does not differ between hemispheres.     

Differential modulation of motor cortex excitability in BDNF Met allele carriers following experimentally induced and use-dependent plasticity

The purpose of this study was to investigate how healthy young subjects with one of three variants of the brain‐derived neurotrophic factor (BDNF) gene modulate motor cortex excitability following experimentally induced and use‐dependent plasticity interventions. Electromyographic recordings were obtained from the right first dorsal interosseous (FDI) muscle of 12 Val/Val, ten Val/Met and seven Met/Met genotypes (aged 18–39 years). Transcranial magnetic stimulation of the left hemisphere was used to assess changes in FDI motor‐evoked potentials (MEPs) following three separate interventions involving paired associative stimulation, a simple ballistic task and complex visuomotor tracking task using the index finger. Val/Val subjects increased FDI MEPs following all interventions (≥ 25%, P < 0.01), whereas the Met allele carriers only showed increased MEPs after the simple motor task (≥ 26%, P < 0.01). In contrast to the simple motor task, there was no significant change in MEPs for the Val/Met subjects (7%, P = 0.50) and a reduction in MEPs for the Met/Met group (?38%, P < 0.01) following the complex motor task. Despite these differences in use‐dependent plasticity, the performance of both motor tasks was not different between BDNF genotypes. We conclude that modulation of motor cortex excitability is strongly influenced by the BDNF polymorphism, with the greatest differences observed for the complex motor task. We also found unique motor cortex plasticity in the rarest form of the BDNF polymorphism (Met/Met subjects), which may have implications for functional recovery after disease or injury to the nervous system in these individuals.     

帕金森病患者运动皮质兴奋性的经颅磁刺激研究

目的:本研究拟应用低频重复性经颅磁刺激(rTMS)分别刺激帕金森病(PD)患者M1手代表区(M1Hand)及运动前区(PMC),探讨不同干预手段对运动皮质兴奋性的影响,以及M1与PMC间的联系。方法:对18名确诊PD患者先后进行4种不同干预,即口服美多芭、低频rTMS刺激M1Hand(0.5Hz,100%静息阈值,共1600次脉冲)、低频rTMS刺激PMC(0.5Hz,100%静息阈值,共1600次脉冲)以及假刺激。于每次干预前后各进行临床评价并测定运动诱发电位(MEP)相关指标。结果:①口服美多芭后UPDRSⅢ(P=0.001)以及其中有关僵直(P=0.001)、运动迟缓(P<0.001)的评分均较服药前显著改善。三种不同磁刺激干预产生结果不同,M1Hand组UPDRSⅢ减低(P=0.015),僵直(P=0.010)、运动迟缓(P=0.004)亦有所改善;PMC组UPDRSⅢ较干预前减低(P=0.046),僵直评分亦减低,但无显著性意义(P=0.163);②口服美多芭1h后MEP120减低(P=0.002),CSP延长(P=0.006);M1Hand组MEP120无著变,而CSP延长(P=0.015);PMC组MEP120减低(P=0.004),而CSP无著变;假刺激组则均无显著性改变。结论:低频rTMS对不同脑区产生的效应不同:刺激M1可使CSP延长;而刺激PMC可使MEP波幅减低。     

Long‐term progressive motor skill training enhances corticospinal excitability for the ipsilateral hemisphere and motor performance of the untrained hand

It is well established that unilateral motor practice can lead to increased performance in the opposite non‐trained hand. Here, we test the hypothesis that progressively increasing task difficulty during long‐term skill training with the dominant right hand increase performance and corticomotor excitability of the left non‐trained hand. Subjects practiced a visuomotor tracking task engaging right digit V for 6 weeks with either progressively increasing task difficulty (PT) or no progression (NPT). Corticospinal excitability (CSE) was evaluated from the resting motor threshold (rMT) and recruitment curve parameters following application of transcranial magnetic stimulation (TMS) to the ipsilateral primary motor cortex (iM1) hotspot of the left abductor digiti minimi muscle (ADM). PT led to significant improvements in left‐hand motor performance immediately after 6 weeks of training (63 ± 18%, P < 0.001) and 8 days later (76 ± 14%, P < 0.001). In addition, PT led to better task performance compared to NPT (19 ± 15%, P = 0.024 and 27 ± 15%, P = 0.016). Following the initial training session, CSE increased across all subjects. After 6 weeks of training and 8 days later, only PT was accompanied by increased CSE demonstrated by a left and upwards shift in the recruitment curves, e.g. indicated by increased MEP_max (P = 0.012). Eight days after training similar effects were observed, but 14 months later motor performance and CSE were similar between groups. We suggest that progressively adjusting demands for timing and accuracy to individual proficiency promotes motor skill learning and drives the iM1‐CSE resulting in enhanced performance of the non‐trained hand. The results underline the importance of increasing task difficulty progressively and individually in skill learning and rehabilitation training.     

Language perception activates the hand motor cortex: implications for motor theories of speech perception

The precise mechanisms of how speech may have developed are still unknown to a large extent. Gestures have proven a powerful concept for explaining how planning and analysing of motor acts could have evolved into verbal communication. According to this concept, development of an action-perception network allowed for coding and decoding of communicative gestures. These were manual or manual/articulatory in the beginning and then became increasingly elaborate in the articulatory mode. The theory predicts that listening to the 'gestures' that compose spoken language should activate an extended articulatory and manual action-perception network. To examine this hypothesis, we assessed the effects of language on cortical excitability of the hand muscle representation by transcranial magnetic stimulation. We found the hand motor system to be activated by linguistic tasks, most notably pure linguistic perception, but not by auditory or visuospatial processing. The amount of motor system activation was comparable in both hemispheres. Our data support the theory that language may have evolved within a general and bilateral action-perception network.     

Short-term and long-term plasticity interaction in human primary motor cortex

Repetitive transcranial magnetic stimulation (rTMS) over primary motor cortex (M1) elicits changes in motor evoked potential (MEP) size thought to reflect short‐ and long‐term forms of synaptic plasticity, resembling short‐term potentiation (STP) and long‐term potentiation/depression (LTP/LTD) observed in animal experiments. We designed this study in healthy humans to investigate whether STP as elicited by 5‐Hz rTMS interferes with LTP/LTD‐like plasticity induced by intermittent and continuous theta‐burst stimulation (iTBS and cTBS). The effects induced by 5‐Hz rTMS and iTBS/cTBS were indexed as changes in MEP size. We separately evaluated changes induced by 5‐Hz rTMS, iTBS and cTBS applied alone and those induced by iTBS and cTBS delivered after priming 5‐Hz rTMS. Interactions between 5‐Hz rTMS and iTBS/cTBS were investigated under several experimental conditions by delivering 5‐Hz rTMS at suprathreshold and subthreshold intensity, allowing 1 and 5 min intervals to elapse between 5‐Hz rTMS and TBS, and delivering one and ten 5‐Hz rTMS trains. We also investigated whether 5‐Hz rTMS induces changes in intracortical excitability tested with paired‐pulse transcranial magnetic stimulation. When given alone, 5‐Hz rTMS induced short‐lasting and iTBS/cTBS induced long‐lasting changes in MEP amplitudes. When M1 was primed with 10 suprathreshold 5‐Hz rTMS trains at 1 min before iTBS or cTBS, the iTBS/cTBS‐induced after‐effects disappeared. The 5‐Hz rTMS left intracortical excitability unchanged. We suggest that STP elicited by suprathreshold 5‐Hz rTMS abolishes iTBS/cTBS‐induced LTP/LTD‐like plasticity through non‐homeostatic metaplasticity mechanisms. Our study provides new information on interactions between short‐term and long‐term rTMS‐induced plasticity in human M1.     

Plasticity of the motor cortex in Parkinson's disease patients on and off therapy.

We used the paired associative stimulation (PAS) technique to investigate associative plasticity of the sensorimotor cortex in 16 Parkinson's disease (PD) patients off and on therapy and in 10 age-matched controls. After PAS, motor evoked potential (MEP) amplitudes increased more and the cortical silent period showed a reduced prolongation in patients off therapy than in controls. These changes lasted for at least 30 minutes. In addition, MEP amplitudes increased in a less focal manner in patients off therapy than in controls. After patients received dopaminergic therapy, these abnormalities normalized. The abnormal responsiveness of sensorimotor cortex neurons to PAS in PD patients off therapy probably reflects disordered plasticity within the motor cortex.     

Towards unravelling task-related modulations of neuroplastic changes induced in the human motor cortex

Stimulation with weak electrical direct currents has been shown to be capable of inducing stimulation-polarity-dependent prolonged diminutions or elevations of cortical excitability, most probably elicited by a hyper- or depolarization of resting membrane potentials. The aim of the present study was to test if cognitive task and motor exercise practiced during the stimulation are able to modify transcranial direct current stimulation-induced plasticity in the left primary motor cortex in 12 healthy subjects. Motor evoked potentials were recorded before and after 10 min of anodal and cathodal transcranial direct current stimulation. In Experiment 1, subjects were required to sit passively during the stimulation, in Experiment 2 the subject's attention was directed towards a cognitive test and in Experiment 3 subjects were instructed to push a ball in their right hand. Both the cognitive task and motor exercise modified transcranial direct current stimulation-induced plasticity; when performing the cognitive task during stimulation the motor cortex excitability was lower after anodal stimulation and higher after cathodal stimulation, compared with the passive condition. When performing the motor exercise, the motor cortex excitability was lower after both anodal and cathodal stimulation, compared with the passive condition. Our results show that transcranial direct current stimulation-induced plasticity is highly dependent on the state of the subject during stimulation.     

Abnormal motor cortex excitability is associated with reduced cortical thickness in X monosomy

Turner syndrome (TS) is a noninherited genetic disorder caused by the absence of one or part of one X chromosome. It is characterized by physical and cognitive phenotypes that include motor deficits that may be related to neuroanatomical abnormalities of sensorimotor pathways. Here, we used transcranial magnetic stimulation (TMS) and cortical thickness analysis to assess motor cortex excitability and cortical morphology in 17 individuals with TS (45, X) and 17 healthy controls. Exploratory analysis was performed to detect the effect of parental origin of the X chromosome (X^mat, X^pat) on both measures. Results showed that long‐interval intracortical inhibition was reduced and motor threshold (MT) was increased in TS relative to controls. Areas of reduced thickness were observed in the precentral gyrus of individuals with TS that correlated with MT. A significant difference between X^mat (n = 11) and X^pat (n = 6) individuals was found on the measure of long‐interval intracortical inhibition. These findings demonstrate the presence of converging anatomical and neurophysiological abnormalities of the motor system in X monosomy. Hum Brain Mapp, 2013. © 2011 Wiley Periodicals, Inc.     

Transcranial stimulation of the leg area of the motor cortex in humans

We used transcranial magnetic stimulation on nine normal volunteers to establish an effective way to stimulate the leg area of the motor cortex. Three types of coils: a large figure-eight coil, small figure-eight coil, and a round coil were used. Surface electromyographic activities were recorded from the left tibialis anterior muscle, and the latencies and amplitudes compared with those obtained by anodal electrical stimulation. The most stable responses were obtained when the large figure-eight coil was centered over the vertex and backward current was run through it or when the round coil was centered two to three centimeters anterior to the vertex with left-flowing current in it at the posterior widening. The latencies obtained under these stimulation conditions were the same as those obtained by electrical stimulation. We conclude that direct activation of the pyramidal cells occurs in the leg area of the motor cortex in all forms of magnetic and electrical stimulation.