Depressed intracortical inhibition after long trains of subthreshold repetitive magnetic stimuli at low frequency

OBJECTIVE: Repetitive transcranial magnetic stimulation (rTMS) modulates cortical excitability. These effects outlast the rTMS train, and range from inhibition to facilitation according to the variables used for rTMS. Several studies have demonstrated short and long-term effects on motor evoked potential (MEP) size, whereas the effects on intracortical inhibition (ICI) and facilitation (ICF) are still unclear. We investigated short- (1-15 min), intermediate- (16-30 min), and long-term (6 h) effects on intracortical excitability. METHODS: Fourteen healthy subjects were stimulated with rTMS trains of 900 pulses (1 Hz, 90% resting motor threshold (rMTh)), delivered over the primary motor cortex and the occipital area. MTh, MEP size, silent period, intracortical inhibition at short (ICI) and long inter-stimulus intervals, and ICF were tested before and after rTMS. RESULTS: ICI was reduced 16-30 min after 1 Hz rTMS trains over the primary motor area, whereas the other response variables remained unchanged. The ICI reduction at 16-30 min was reproducible on different days in the same subjects; it was absent at 6 h and after stimulation of the occipital area. CONCLUSIONS: Subthreshold 1 Hz rTMS decreases ICI by reducing the excitability of intracortical inhibitory interneurones or by altering the electrical properties of the facilitatory chain of neurons responsible for the I waves.     

Interhemispheric effects of high and low frequency rTMS in healthy humans.

OBJECTIVE: We investigated whether repetitive transcranial magnetic stimulation (rTMS) applied to the right motor cortex modified the excitability of the unstimulated left motor cortex. METHODS: Interhemispheric effects of 0.5 and 5 Hz subthreshold rTMS over the right motor cortex were examined by single pulse and paired pulse TMS and by transcranial electrical stimulation (TES) applied to the unstimulated left motor cortex. The effects of (a) 1800 pulses real and sham rTMS with 5 Hz, (b) 180 pulses real and sham rTMS with 0.5 Hz and (c) 1800 pulses real rTMS with 0.5 Hz were studied. RESULTS: Following 5 Hz right motor rTMS motor evoked potential (MEP) amplitudes induced by single pulse TMS over the left motor cortex increased significantly. Intracortical inhibition (ICI) and facilitation (ICF) and MEP amplitudes evoked by TES were unchanged. Sham stimulation had no influence on motor cortex excitability. After 180 pulses right motor cortex rTMS with 0.5 Hz a significant decrease of left motor ICF, but no change in single pulse MEP amplitudes was found. A similar trend was observed with 1800 pulses rTMS with 0.5 Hz. CONCLUSIONS: High frequency right motor rTMS can increase left motor cortex excitability whereas low frequency right motor rTMS can decrease it. These effects outlast the rTMS by several minutes. The underlying mechanisms mediating interhemispheric excitability changes are likely to be frequency dependent.     

Therapeutic effect of repetitive transcranial magnetic stimulation on motor function in Parkinson''s disease patients

Cortical excitability of the primary motor cortex is altered in patients with Parkinson's disease (PD). Therefore, modulation of cortical excitability by high frequency repetitive transcranial magnetic stimulation (rTMS) of the motor cortex might result in beneficial effects on motor functions in PD. The present study aims to evaluate the effect of rTMS of the motor cortex on motor functions in patients with PD. Thirty-six unmedicated PD patients were included consecutively in this study. The patients were assigned in a randomized pattern to one of two groups, one group receiving real-rTMS (suprathreshold 5-Hz, 2000 pulses once a day for 10 consecutive days) and the second group receiving sham-rTMS using closed envelopes. Total motor section of Unified Parkinson's Disease Rating Scale (UPDRS), walking speed, and self-assessment scale were performed for each patient before rTMS and after the first, fifth, 10th sessions, and then after 1 month. Evaluation of these measures was performed blindly without knowing the type of rTMS. anova for repeated measurements revealed a significant time effect for the total motor UPDRS, walking speed and self-assessment scale during the course of the study in the group of patients receiving real-rTMS (P = 0.0001, 0.001, and 0.002), while no significant changes were observed in the group receiving sham-rTMS except in self-assessment scale (P = 0.019). A 10-day course of real-rTMS resulted in statistically significant long-term improvement of the motor functions in comparison with the sham-rTMS. The rTMS could have a therapeutic role of for PD patients.     

Placebo-controlled study of rTMS for the treatment of Parkinson's disease.

The objective of this study is to assess the safety and efficacy of repetitive transcranial magnetic stimulation (rTMS) for gait and bradykinesia in patients with Parkinson's disease (PD). In a double-blind placebo-controlled study, we evaluated the effects of 25 Hz rTMS in 18 PD patients. Eight rTMS sessions were performed over a 4-week period. Four cortical targets (left and right motor and dorsolateral prefrontal cortex) were stimulated in each session, with 300 pulses each, 100% of motor threshold intensity. Left motor cortex (MC) excitability was assessed using motor evoked potentials (MEPs) from the abductor pollicis brevis. During the 4 weeks, times for executing walking and complex hand movements tests gradually decreased. The therapeutic rTMS effect lasted for at least 1 month after treatment ended. Right-hand bradykinesia improvement correlated with increased MEP amplitude evoked by left MC rTMS after individual sessions, but improvement overall did not correlate with MC excitability. rTMS sessions appear to have a cumulative benefit for improving gait, as well as reducing upper limb bradykinesia in PD patients. Although short-term benefit may be due to MC excitability enhancement, the mechanism of cumulative benefit must have another explanation.     

Effects of low frequency and low intensity repetitive paired pulse stimulation of the primary motor cortex.

OBJECTIVE: Following a previous report [Bestmann et al. Clin Neurophysiol 2004;115:755-64] that pairs of subthreshold pulses of transcranial magnetic stimulation (TMS) can show temporal summation, we explored whether repeated application of pairs of stimulation could produce long-lasting after effects on the excitability of the human motor cortex. METHODS: Twelve healthy subjects received 25 min repetitive paired pulse magnetic stimulation (paired rTMS) given at a frequency of about 0.6 Hz over the left primary motor cortex (500 paired stimuli in total). The interval between the paired stimuli was 3 ms and the intensity of both stimuli was 80% of active motor threshold. The resting and active motor threshold, MEP recruitment curve, short interval intracortical inhibition (SICI) and facilitation, and the duration of the cortical silent period (SP) were tested for the right first interosseous muscle (FDI) before and two times after the end of 25 min paired rTMS. RESULTS: Prolonged subthreshold paired rTMS produced a significant decrease in excitability in the corticospinal projection to FDI: resting motor threshold was significantly increased and MEP recruitment was significantly decreased, SICI was significantly increased at 2 and 4 ms and the SP was significantly increased in duration. CONCLUSIONS: Prolonged low frequency paired rTMS at subthreshold intensity can modulate cortical excitability by producing inhibitory effects that outlast the period of stimulation.     

Repetitive transcranial magnetic stimulation to improve mood and motor function in Parkinson's disease

Repetitive transcranial magnetic stimulation (rTMS) is a non-invasive brain stimulation technique that can produce lasting changes in excitability and activity in cortical regions underneath the stimulation coil (local effect), but also within functionally connected cortical or subcortical regions (remote effects). Since the clinical presentation of Parkinson's disease (PD) is related to abnormal neuronal activity within the basal ganglia and cortical regions, including the primary motor cortex, the premotor cortex and the prefrontal cortex, several studies have used rTMS to improve brain function in PD. Here, we review the studies that have investigated the possible therapeutic effects of rTMS on mood and motor function in PD patients. We highlight some methodological inconsistencies and problems, including the difficulty to define the most effective protocol for rTMS or to establish an appropriate placebo condition. We finally propose future directions of research that may help to improve the therapeutic efficacy of rTMS in PD.     

Low-frequency repetitive transcranial magnetic stimulation of the motor cortex in writer's cramp

OBJECTIVE: To study the short-term effects of slow repetitive transcranial magnetic stimulation (rTMS) of the motor cortex on cortical excitability and handwriting in patients with writer's cramp. BACKGROUND: Cortical excitability of the primary motor cortex is abnormally enhanced in patients with writer's cramp. Therefore, reducing cortical excitability by low-frequency rTMS of the motor cortex might result in beneficial effects on handwriting in writer's cramp. DESIGN/METHODS: We studied the effects of subthreshold 1-Hz rTMS on motor threshold and cortico-cortical excitability using the paired-pulse technique in seven patients and seven controls. In another 16 patients and 11 age-matched controls we evaluated changes in cortical excitability by measuring the stimulus-response curve and the postexcitatory silent period before and after subthreshold 1-Hz rTMS. In addition, we analyzed the handwriting before and 20 minutes after 1-Hz rTMS. RESULTS: In the first experiment, low-frequency rTMS resulted in a normalization of the deficient cortico-cortical inhibition in the patients without affecting motor threshold. In the second experiment, 1-Hz rTMS resulted in a significant prolongation of the postexcitatory silent period without affecting the stimulus-response curve in the patient group. Moreover, the dystonic patients showed a significant reduction of mean writing pressure after subthreshold 1-Hz rTMS that was associated with clear but transient improvement in six patients. CONCLUSIONS: In some patients 1-Hz rTMS can reinforce deficient intracortical inhibition and may improve handwriting temporarily. Our data support the notion that reduced intracortical inhibition plays a part in the pathophysiology of focal dystonia.     

经颅重复磁刺激对人脑皮层兴奋性的影响

目的　研究经颅重复磁刺激（rTMS）对人脑运动皮层兴奋性的影响。方法　5Hz×30次或15Hz×30次rTMS,以相当于120%静止运动阈值的强度,作用于12名青壮年志愿者,并利用成对的条件-检测刺激方法检验rTMS对皮层内抑制（ICI）及皮层内易化（ICF）的影响。结果　15HzrTMS显著抑制ICI达3.4min,兴奋ICF达1.5min,而运动阈值仅被降低约30s。5HzrTMS仅显著抑制ICI30s,而对ICF及运动阈值无影响。结论　高频阈上rTMS能一过性抑制皮层内抑制环路并提高皮层内兴奋性环路的活动。     

重复经颅磁刺激对帕金森病运动功能及运动诱发电位的影响

目的:探讨低频重复经颅磁刺激(rTMS)对PD患者运动皮质兴奋性影响的持续效应。方法:对38例PD患者,予0.5Hz rTMS刺激其主要受累肢体对侧的M1Hand(20×80,100%RMT),连续7d。于首次干预前及末次干预后20min、1周及1个月分别评价其临床运动功能和运动诱发电位。结果:低频rTMS干预后,PD患者UPDRS Ⅲ、僵直、运动迟缓评分、计时运动试验及CSP均存在显著时间效应(P<0.001)。结论:低频rTMS可改善PD患者运动迟缓症状,其对运动功能的影响可持续到刺激停止后1个月,与运动皮质兴奋性的改变一致。     

Stimulus intensity and coil characteristics influence the efficacy of rTMS to suppress cortical excitability.

OBJECTIVE: Low-frequency repetitive transcranial magnetic stimulation (rTMS) can reduce cortical excitability. Here we examined whether inhibitory after effects of low-frequency rTMS are influenced by stimulus intensity, the type of TMS coil and re-afferent sensory stimulation. METHODS: In fifteen healthy volunteers, we applied 900 biphasic pulses of 1Hz rTMS to the left primary motor cortex (M1) at an intensity that was 10% below or 15% above resting motor threshold. For rTMS, we used two different figure-of-eight shaped coils (Magstim or Medtronic coil) attached to the same stimulator. We recorded motor evoked potentials (MEPs) evoked with the same set-up used for rTMS (MEP-rTMS) before and twice after rTMS. Using a different TMS setup, we also applied monophasic pulses to the M1 in order to assess the effects of rTMS on corticospinal excitability, intracortical paired-pulse excitability and the duration of the cortical silent period (CSP). In a control experiment, the same measurements were performed after 15min of 1Hz repetitive electrical nerve stimulation (rENS) of the right ulnar nerve. RESULTS: Analysis of variance revealed an interaction between intensity, coil and time of measurement (p<0.035), indicating that the effect of 1Hz rTMS on MEP-rTMS amplitude depended on the intensity and the type of coil used for rTMS. Suppression of corticospinal excitability was strongest after suprathreshold 1Hz rTMS with the Medtronic coil (p<0.01 for both post-rTMS measurements relative to pre-intervention baseline). Regardless of the type of coil, suprathreshold but not subthreshold rTMS transiently prolonged the CSP and attenuated paired-pulse facilitation. Suprathreshold 1Hz rENS also induced a short-lasting inhibition of MEP-rTMS. CONCLUSIONS: Both the stimulation intensity and the type of TMS coil have an impact on the after effects of 1Hz rTMS. Re-afferent feedback activation may at least in part account for the stronger suppression of corticospinal excitability by suprathreshold 1Hz rTMS. SIGNIFICANCE: These data should be considered when rTMS is used as a therapeutic means.     

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。     

Repetitive transcranial magnetic stimulation (rTMS): insights into the treatment of Parkinson's disease by cortical stimulation.

Repetitive transcranial magnetic stimulation (rTMS) is a potent tool that can be used to modify activity of targeted cortical areas. Significant clinical effects have been obtained in patients with Parkinson's disease (PD) by stimulating different cortical regions with rTMS at inhibitory (low) or excitatory (high) frequency. These effects were thought to result from plastic changes in motor cortical networks. Actually cortical dysfunction has been documented in PD by neuroimaging and neurophysiologic studies showing either hypo- or hyper-activation of various brain areas. In addition, cortical excitability studies using transcranial magnetic stimulation disclosed significant alterations in intracortical facilitatory or inhibitory processes according to the resting state or to phases of movement preparation or execution. These observations clearly support the therapeutic potential of cortical neuromodulation in PD. Motor cortex stimulation could impact on any station within the cortico-basal ganglia-thalamo-cortical loops that are involved in motor control, providing alleviation of parkinsonian symptoms. Depending on the target, cortical stimulation might improve motor performance or other symptoms associated with PD, like depression. Clinical application of rTMS to treat PD patients is limited by the short duration of the effects beyond the time of stimulation, even if long-lasting improvements have been observed after repeated rTMS sessions. In any case, the place of cortical stimulation in the therapeutic management of PD patients remains to be determined, as an alternative or a complementary technique to deep brain stimulation. The rTMS technique could be used to better define the targets and the parameters of stimulation subsequently applied in chronic epidural stimulation.     

Induction of long-term plasticity in human swallowing motor cortex following repetitive cortical stimulation.

OBJECTIVE: The excitability of corticobulbar projections to swallowing musculature undergoes remarkable long-term increases after short periods of pharyngeal stimulation. The aim of this study was to investigate the excitability of swallowing motor cortex following repetitive transcranial magnetic stimulation (rTMS). METHODS: Twelve healthy subjects were given 100 rTMS pulses over motor cortex at frequencies of 1, 5 and 10 Hz at an intensity of 80% threshold for corticobulbar activation. The excitability of the corticobulbar projection was assessed before and after rTMS and compared both to sham stimulation and to the corticospinal projection. RESULTS: Stimulation at 5 Hz, but not 1 Hz, 10 Hz or sham stimulation increased the excitability of the corticobulbar projection to the pharynx, reaching a peak 60 min after rTMS (Delta increase: 65%, P=0.016). Excitability in the projection from the opposite hemisphere also increased, suggesting the presence of inter-hemispheric interactions, whereas excitability in the projection to thenar muscles was unchanged. CONCLUSIONS: Corticobulbar and corticospinal projections may differ in response to rTMS, implying differences in relative thresholds of inhibitory and excitatory elements in hand versus swallowing cortex. SIGNIFICANCE: This might be a useful approach in the motor rehabilitation of dysphagic stroke patients who have damage to sensory projections to the swallowing cortex.     

Effects of DBS,premotor rTMS,and levodopa on motor function and silent period in advanced Parkinson's disease

Deep brain stimulation (DBS) of the subthalamic nucleus (STN) is a widely used and highly effective treatment for patients with advanced Parkinson's disease (PD). Repetitive TMS (rTMS) applied to motor cortical areas has also been shown to improve symptoms in PD and modulate motor cortical excitability. Here, we compared clinical and neurophysiological effects of STN stimulation with those of 1 Hz rTMS given to the dorsal premotor cortex (PMd) and those following intake of levodopa in a group of PD patients with advanced disease. Ten PD patients were studied on 2 consecutive days before and after surgery. Clinical effects were determined using the UPDRS motor score. Motor thresholds, motor‐evoked potential (MEP) amplitudes during slight voluntary contraction, and the cortical silent periods (SP) were measured using TMS. Before surgery effects of levodopa and 1 Hz PMd rTMS and after surgery those of STN stimulation with or without additional levodopa were determined. Levodopa significantly improved clinical symptoms and increased the SP duration. STN stimulation improved clinical symptoms without changing the SP duration. In contrast, 1 Hz PMd rTMS was not effective clinically but normalized the SP duration. Whereas levodopa had widespread effects at different levels of an abnormally active motor network in PD, STN stimulation and PMd rTMS led to either clinical improvement or SP normalization, i.e., only partially reversed abnormal motor network activity. © 2009 Movement Disorder Society     

Modulation of input-output curves by low and high frequency repetitive transcranial magnetic stimulation of the motor cortex.

OBJECTIVES: Exploring the modulatory effects of different frequencies of repetitive transcranial magnetic stimulation (rTMS) on the excitability of the motor cortex as measured by the input-output curve technique (I-O curve). METHODS: Sixteen healthy subjects participated in this experiment. On two different sessions, conducted 1 week apart, rTMS was applied either at a frequency of 20 or 1 Hz at 90% of individual motor threshold (MT) for a total of 1600 pulses each. Before and after rTMS, the cortical excitability was assessed by measuring MT and the size of motor evoked potentials (MEPs) collected at different intensities of stimulation. RESULTS: The analysis on the whole population showed a significant decrease of cortical excitability after 1 Hz rTMS and an increase after 20 Hz rTMS. A subsequent cluster analysis pointed out the presence of two distinct groups of subjects with opposite responses at the same frequency of stimulation. Significant variations on MT were found for both groups only for the facilitatory effect irrespective of the frequency of stimulation. CONCLUSIONS: The results provide further insight into interindividual differences in the effects of rTMS and suggest the existence of subpopulations with specific patterns of response to rTMS.     

Low frequency rTMS of the SMA transiently ameliorates peak-dose LID in Parkinson's disease.

OBJECTIVE: To determine whether low-frequency repetitive transcranial magnetic stimulation (rTMS) may modulate l-DOPA-induced dyskinesia (LID) in dyskinetic Parkinson's disease (PD) patients. LID is a severe motor complication in advanced PD patients. The neural mechanisms involved in LID are not clear, and it is apparent that both an excessive decrease in internal pallidus firing and a modification and overactivation of cortical motor and premotor areas are involved in its pathogenesis. METHODS: Using low frequency 1Hz repetitive rTMS we investigated whether decrease of excitability of the supplementary motor area (SMA) may result in modification of LID in PD patients. Furthermore we tested whether it was possible to enhance and/or prolong the beneficial effects of the treatment with repeated sessions of stimulation. RESULTS: We observed that 1Hz rTMS induced a transient reduction of dyskinesias. A single session of rTMS improved LID, while repeated sessions of stimulation failed to enhance and/or prolong the beneficial effects of the procedure, without causing motor deterioration or other adverse effects. CONCLUSIONS: These results suggest that LID may depend on an increased excitability of the SMA. SIGNIFICANCE: SMA rTMS is effective in reducing transiently LID, although cannot yet be considered clinically useful.     

Motor cortical excitability studied with repetitive transcranial magnetic stimulation in patients with Huntington's disease.

OBJECTIVE: TMS techniques have provided controversial information on motor cortical function in Huntington's disease (HD). We investigated the excitability of motor cortex in patients with HD using repetitive transcranial magnetic stimulation (rTMS). METHODS: Eleven patients with HD, and 11 age-matched healthy subjects participated in the study. The clinical features of patients with HD were evaluated with the United Huntington's Disease Rating Scale (UHDRS). rTMS was delivered with a Magstim Repetitive Magnetic Stimulator through a figure-of-8 coil placed over the motor area of the first dorsal interosseus (FDI) muscle. Trains of 10 stimuli were delivered at 5 Hz frequency and suprathreshold intensity (120% resting motor threshold) with the subjects at rest and during voluntary contraction of the target muscle. RESULTS: In healthy subjects at rest, rTMS produced motor evoked potentials (MEPs) that increased in amplitude over the course of the trains. Conversely in patients, rTMS left the MEP size almost unchanged. In both groups, during voluntary contraction rTMS increased the silent period (SP) duration. CONCLUSIONS: Because rTMS modulates motor cortical excitability by activating cortical excitatory and inhibitory interneurons these findings suggest that in patients with HD the excitability of facilitatory intracortical interneurones is decreased. SIGNIFICANCE: We suggest that depressed excitability of the motor cortex in patients with HD reflects a disease-related weakening of cortical facilitatory mechanisms.     

Effects of successive repetitive transcranial magnetic stimulation on motor performances and brain perfusion in idiopathic Parkinson's disease

We studied the effects of 0.2 Hz repetitive transcranial magnetic stimulation (rTMS) successively performed 6 times for 2 weeks in 12 patients with idiopathic Parkinson's disease (PD). Ten patients received rTMS to the bilateral frontal cortex (frontal rTMS) and six patients received rTMS to the bilateral occipital cortex (occipital rTMS). Before and after rTMS, we evaluated regional cerebral blood flow (rCBF) using 99m-Tc-ECD single photon emission computed tomography (SPECT) and clinical tests.In an analysis with statistic parametric mapping, both frontal and occipital rTMS reduced rCBF in the cortical areas around the stimulated site. The activities of daily living (ADL) and motor scores of Unified Parkinson's Disease Rating Scale (UPDRS), pronation-supination movements, and buttoning up significantly improved after frontal rTMS than before it, while occipital rTMS had no significant effects in clinical tests.The findings of the present study suggest that successive 0.2 Hz rTMS has outlasting inhibitory effects on neuronal activity around the stimulated cortical areas. Because there were no significant relations between improved clinical tests and reduced rCBF, we speculate that the indirect effects of 0.2 Hz rTMS on subcortical structures are related to improved parkinsonian symptoms. Further studies recruiting large numbers of subjects are required to confirm the efficacy of 0.2 Hz rTMS on PD.     

Changes in motor cortical excitability induced by high-frequency repetitive transcranial magnetic stimulation of different stimulation durations.

OBJECTIVE: To investigate the changes in cortical excitability of the human motor cortex induced by high-frequency repetitive transcranial magnetic stimulation (rTMS) of different stimulation durations. METHODS: Twenty healthy subjects participated in the study. Subjects received 20 trains of 10-Hz rTMS at 80% of the resting motor threshold (RMT) intensity with two different stimulation durations (5 and 1.5s) over the motor hot spot for left first dorsal interosseous (FDI) muscle. Electromyographic responses (motor-evoked potentials, MEPs) to single-pulse stimulation, and intracortical inhibition (ICI) and intracortical facilitation (ICF) by paired-pulse stimulation were measured bilaterally in the relaxed FDI muscles before, immediately after, and 30, 60, 90 and 120 min after rTMS. RESULTS: After 5s of 10-Hz rTMS, the mean amplitude of MEP for the stimulated M1 cortex decreased for up to 90min (P=0.002) and that of the unstimulated M1 cortex decreased for up to 60 min (P=0.008). Enhancement of ICI and suppression of ICF were observed and sustained for more than 90 min in both stimulated (P=0.001) and unstimulated (P=0.003) M1 cortex after 5s of 10-Hz rTMS. After 1.5s of 10-Hz rTMS, the mean amplitude of MEP increased in stimulated cortex for up to 120 min (P=0.005). CONCLUSIONS: With different stimulation durations, high-frequency subthreshold rTMS can produce different patterns of long-lasting changes in corticospinal and intracortical excitability in stimulated and unstimulated motor cortex in healthy subjects. SIGNIFICANCE: The results have important implications for the selection of stimulation parameters other than the frequency of rTMS. The clinical application of rTMS for the purpose of motor enhancement should be considered along with the mechanism of different stimulation parameters.     

Effects of theta burst stimulation on motor cortex excitability in Parkinson's disease

ObjectiveLong-term potentiation (LTP)-like plasticity induced by paired associative stimulation (PAS) is impaired in Parkinson’s disease (PD). Intermittent theta burst stimulation (iTBS) is another rTMS protocol that produces LTP-like effects and increases cortical excitability but its effects are independent of afferent input. The aim of the present study was to examine the effects of iTBS on cortical excitability in PD.MethodsiTBS was applied to the motor cortex in 10 healthy subjects and 12 PD patients ON and OFF dopaminergic medications. Motor evoked potential (MEP) before and for 60 min after iTBS were used to examine the changes in cortical excitability induced by iTBS. Paired-pulse TMS was used to test whether intracortical circuits, including short interval intracortical inhibition, intracortical facilitation, short and long latency afferent inhibition, were modulated by iTBS.ResultsAfter iTBS, the control, PD ON and OFF groups had similar increases in MEP amplitude compared to baseline over the course of 60 min. Changes in intracortical circuits induced by iTBS were also similar for the different groups.ConclusionsiTBS produced similar effects on cortical excitability for PD patients and controls.SignificanceSpike-timing dependent heterosynaptic LTP-like plasticity induced by PAS may be more impaired in PD than frequency dependent homosynaptic LTP-like plasticity induced by iTBS.