Modulation of I-Wave Generating Pathways With Repetitive Paired-Pulse Transcranial Magnetic Stimulation: A Transcranial Magnetic Stimulation–Electroencephalography Study

ObjectivesRepetitive paired-pulse transcranial magnetic stimulation (iTMS) at indirect (I) wave intervals increases motor-evoked potentials (MEPs) produced by transcranial magnetic stimulation (TMS) to primary motor cortex (M1). However, the effects of iTMS at early and late intervals on the plasticity of specific I-wave circuits remain unclear. This study therefore aimed to assess how the timing of iTMS influences intracortical excitability within early and late I-wave circuits. To investigate the cortical effects of iTMS more directly, changes due to the intervention were also assessed using combined TMS-electroencephalography (EEG).Material and MethodsEighteen young adults (aged 24.6 ± 4.2 years) participated in four sessions in which iTMS targeting early (1.5-millisecond interval; iTMS_1.5) or late (4.0-millisecond interval; iTMS_4.0) I-waves was applied over M1. Neuroplasticity was assessed using both posterior-to-anterior (PA) and anterior-to-posterior (AP) stimulus directions to record MEPs and TMS-evoked EEG potentials (TEPs) before and after iTMS. Short-interval intracortical facilitation (SICF) at interstimulus intervals of 1.5 and 4.0 milliseconds was also used to index I-wave activity.ResultsMEP amplitude was increased after iTMS (p < 0.01), and this was greater for PA responses (p < 0.01) but not different between iTMS intervals (p = 0.9). Irrespective of iTMS interval and coil current, SICF was facilitated after the intervention (p < 0.01). Although the N45 produced by AP stimulation was decreased by iTMS_1.5 (p = 0.04), no other changes in TEP amplitude were observed.ConclusionsThe timing of iTMS failed to influence which I-wave circuits were potentiated by the intervention. In contrast, decreases in the N45 suggest that the neuroplastic effects of iTMS may include disinhibition of intracortical inhibitory processes.     

Simulation of transcranial magnetic stimulation in head model with morphologically-realistic cortical neurons

BackgroundTranscranial magnetic stimulation (TMS) enables non-invasive modulation of brain activity with both clinical and research applications, but fundamental questions remain about the neural types and elements TMS activates and how stimulation parameters affect the neural response.ObjectiveTo develop a multi-scale computational model to quantify the effect of TMS parameters on the direct response of individual neurons.MethodsWe integrated morphologically-realistic neuronal models with TMS-induced electric fields computed in a finite element model of a human head to quantify the cortical response to TMS with several combinations of pulse waveforms and current directions.ResultsTMS activated with lowest intensity intracortical axonal terminations in the superficial gyral crown and lip regions. Layer 5 pyramidal cells had the lowest thresholds, but layer 2/3 pyramidal cells and inhibitory basket cells were also activated at most intensities. Direct activation of layers 1 and 6 was unlikely. Neural activation was largely driven by the field magnitude, rather than the field component normal to the cortical surface. Varying the induced current direction caused a waveform-dependent shift in the activation site and provided a potential mechanism for experimentally observed differences in thresholds and latencies of muscle responses.ConclusionsThis biophysically-based simulation provides a novel method to elucidate mechanisms and inform parameter selection of TMS and other cortical stimulation modalities. It also serves as a foundation for more detailed network models of the response to TMS, which may include endogenous activity, synaptic connectivity, inputs from intrinsic and extrinsic axonal projections, and corticofugal axons in white matter.     

Involvement of different neuronal components in the induction of cortical plasticity with associative stimulation

Background

Paired associative stimulation (PAS), with stimulus interval of 21.5 or 25?ms, using transcranial magnetic stimulation in the posterior-anterior (PA) current direction, produces a long-term-potentiation-like effect. Stimulation with PA directed current generates both early and late indirect (I)-waves while that in anterior-posterior (AP) current predominantly elicits late I-waves. Short interval intracortical inhibition (SICI) inhibits late I-waves but not early I-waves.

Modeling motor-evoked potentials from neural field simulations of transcranial magnetic stimulation

ObjectiveTo develop a population-based biophysical model of motor-evoked potentials (MEPs) following transcranial magnetic stimulation (TMS).MethodsWe combined an existing MEP model with population-based cortical modeling. Layer 2/3 excitatory and inhibitory neural populations, modeled with neural-field theory, are stimulated with TMS and feed layer 5 corticospinal neurons, which also couple directly but weakly to the TMS pulse. The layer 5 output controls mean motoneuron responses, which generate a series of single motor-unit action potentials that are summed to estimate a MEP.ResultsA MEP waveform was generated comparable to those observed experimentally. The model captured TMS phenomena including a sigmoidal input–output curve, common paired pulse effects (short interval intracortical inhibition, intracortical facilitation, long interval intracortical inhibition) including responses to pharmacological interventions, and a cortical silent period. Changes in MEP amplitude following theta burst paradigms were observed including variability in outcome direction.ConclusionsThe model reproduces effects seen in common TMS paradigms.SignificanceThe model allows population-based modeling of changes in cortical dynamics due to TMS protocols to be assessed in terms of changes in MEPs, thus allowing a clear comparison between population-based modeling predictions and typical experimental outcome measures.     

Transcranial Direct Current Stimulation Effects on the Excitability of Corticospinal Axons of the Human Cerebral Cortex

BackgroundTranscranial direct current stimulation (tDCS) of the human cerebral cortex modulates cortical excitability non-invasively in a polarity-specific manner: anodal tDCS leads to lasting facilitation of motor cortex excitability.ObjectiveTo further elucidate the underlying physiological mechanisms of tDCS.MethodsWe recorded corticospinal volleys evoked by single-pulse transcranial magnetic stimulation of the primary motor cortex before and after a 20 min period of anodal tDCS in a conscious patient who had electrode implanted in the cervical epidural space for the control of pain. We performed magnetic stimulation of the motor cortex using a direction of the induced current in the brain capable of activating both corticospinal axons, evoking D-wave activity, and cortico-cortical axons projecting upon corticospinal cells, evoking I-wave activity.ResultsAnodal tDCS increased the excitability of cortical circuits generating both D and I-wave activity, with a more prolonged effect on D-wave activity. The changes in motor evoked potential recorded from hand muscles produced by tDCS were in agreement with the effects produced on intracortical circuitry.ConclusionsEpidural recordings of corticospinal activity in our patient indicate that anodal tDCS develops its facilitatory effects by an increase in the excitability of corticospinal axons and by an increase of activity in cortico-cortical projections onto pyramidal tract neurones, modulating motor cortex excitability with both synaptic (I waves) and non-synaptic (D waves) mechanisms.     

Interneuronal networks mediate cortical inhibition and facilitation

ObjectiveRecruitment of interneuronal circuits generating later indirect (I) waves seem to be important in short-interval intracortical inhibition (SICI) and facilitation (SICF) development. This study assessed whether individual variations in intracortical inhibition and facilitation could be explained by variation in recruitment of interneuronal networks.MethodsCortical excitability was assessed using a figure of eight coil, with motor evoked responses recorded over the contralateral abductor pollicis brevis (APB) muscle. I-wave recruitment was inferred from the measurement of motor evoked potential (MEP) onset latencies, with coil positioned in posterior-to-anterior (early I waves) and anterior-to-posterior (later I waves) directions.ResultsSubtle variability in the recruitment of later I-waves (I3) was evident across subjects. Importantly, mean SICI (P < 0.05) was significantly greater in subjects recruiting I3 waves, as were the two SICI peaks at interstimulus intervals of 1 ms (P < 0.05) and 3 ms (P < 0.05). In addition, mean SICF was significantly greater in participants exhibiting an AP-to-LM latency differences of <4 ms (P < 0.01). There was no significant correlation between I-wave recruitment and intracortical facilitation, motor evoked potential amplitude or cortical silent period duration.ConclusionsDifferential recruitment of interneuronal networks appears to underlie the generation and individual variations in intracortical inhibition and facilitation.SignificanceInvestigating cortical interneuronal networks in human diseases may yield novel pathophysiological insights.     

Abnormal cortical facilitation and L-dopa-induced dyskinesia in Parkinson's disease

BackgroundAnimal models of Parkinson's Disease (PD) demonstrated increased facilitatory cortico-striatal activity, reflecting overactive glutamatergic neurotransmission and contributing to the pathophysiology of l-dopa induced dyskinesias (LIDs).ObjectiveTo assess different facilitatory intracortical circuits in the primary motor cortex (M1) in patients with PD and LIDs by means of a combination of transcranial magnetic stimulation (TMS) protocols.MethodsWe tested the Input/Output (I/O) curve, intracortical facilitation (ICF) and short-interval intracortical facilitation (SICF) at baseline (T0), ‘OFF’ and ‘ON’ state, in 20 PD patients with LIDs. The same parameters were examined after 2 weeks of chronic intake of 50 mg (T1) and 100 mg/day (T2) of safinamide. Finally, we tested SICF in a further group of patients without LIDs.ResultsAt T0, patients with LIDs showed increased I/O curve steepness, which was partly ameliorated by l-dopa. These patients also had normal ICF, and abnormally increased SICF, which did not change with l-dopa. Safinamide improved the I/O curve both at T1 and T2, it reduced SICF at T1 and normalized this measure at T2. In patients with PD and LIDs, SICF correlated with the severity of dyskinesia. In patients without LIDs, SICF was less prominently abnormal and responsive to l-dopa.ConclusionsPatients with PD and LIDs have abnormal cortical facilitation, possibly suggesting overactive glutamatergic neurotransmission in specific circuits within M1. Although not responsive to l-dopa, this dysfunction is restored by the anti-glutamatergic properties of safinamide 100 mg. The results suggest that the abnormal cortical facilitation in M1 contributes to the pathophysiology of LIDs.     

Ongoing brain rhythms shape I-wave properties in a computational model

Background

Responses to transcranial magnetic stimulation (TMS) are notoriously variable. Previous studies have observed a dependence of TMS-induced responses on ongoing brain activity, for instance sensorimotor rhythms. This suggests an opportunity for the development of more effective stimulation protocols through closed-loop TMS-EEG. However, it is not yet clear how features of ongoing activity affect the responses of cortical circuits to TMS.

Influence of Waveform and Current Direction on Short-Interval Intracortical Facilitation: A Paired-Pulse TMS Study

BackgroundTranscranial magnetic stimulation (TMS) of the human primary motor hand area (M1-HAND) can produce multiple descending volleys in fast-conducting corticospinal neurons, especially so-called indirect waves (I-waves) resulting from trans-synaptic excitation. Facilitatory interaction between these I-waves can be studied non-invasively using a paired-pulse paradigm referred to as short-interval intracortical facilitation (SICF).Objective/hypothesisWe examined whether SICF depends on waveform and current direction of the TMS pulses.MethodsIn young healthy volunteers, we applied single- and paired-pulse TMS to M1-HAND. We probed SICF by pairs of monophasic or half-sine pulses at suprathreshold stimulation intensity and inter-stimulus intervals (ISIs) between 1.0 and 5.0 ms. For monophasic paired-pulse stimulation, both pulses had either a posterior–anterior (PA) or anterior–posterior (AP) current direction (AP–AP or PA–PA), whereas current direction was reversed between first and second pulse for half-sine paired-pulse stimulation (PA–AP and AP–PA).ResultsMonophasic AP–AP stimulation resulted in stronger early SICF at 1.4 ms relative to late SICF at 2.8 and 4.4 ms, whereas monophasic PA–PA stimulation produced SICF of comparable size at all three peaks. With half-sine stimulation the third SICF peak was reduced for PA–AP current orientation compared with AP–PA.ConclusionSICF elicited using monophasic as well as half-sine pulses is affected by current direction at clearly suprathreshold intensities. The impact of current orientation is stronger for monophasic compared with half-sine pulses. The direction-specific effect of paired-pulse TMS on the strength of early versus late SICF shows that different cortical circuits mediate early and late SICF.     

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.     

Unidirectional visual motion adaptation induces reciprocal inhibition of human early visual cortex excitability

ObjectivesBehavioural observations provided by the waterfall illusion suggest that motion perception is mediated by a comparison of responsiveness of directional selective neurones. These are proposed to be optimally tuned for motion detection in different directions. Critically however, despite the behavioural observations, direct evidence of this relationship at a cortical level in humans is lacking. By utilising the state dependant properties of transcranial magnetic stimulation (TMS), one can probe the excitability of specific neuronal populations using the perceptual phenomenon of phosphenes.MethodWe exposed subjects to unidirectional visual motion adaptation and subsequently simultaneously measured early visual cortex (V1) excitability whilst viewing motion in the adapted and non-adapted direction.ResultFollowing adaptation, the probability of perceiving a phosphene whilst viewing motion in the adapted direction was diminished reflecting a reduction in V1 excitability. Conversely, V1 excitability was enhanced whilst viewing motion in the opposite direction to that used for adaptation.ConclusionOur results provide support that in humans a process of reciprocal inhibition between oppositely tuned directionally selective neurones in V1 facilitates motion perception.SignificanceThis paradigm affords a unique opportunity to investigate changes in cortical excitability following peripheral vestibular disorders.     

Threshold Tracked Short-Interval Intracortical Inhibition More Closely Predicts the Cortical Response to Transcranial Magnetic Stimulation

ObjectivesShort-interval intracortical inhibition (SICI) is a paired-pulse transcranial magnetic stimulation (TMS) technique that is commonly used to quantify intracortical inhibitory tone in the primary motor cortex. Whereas conventional measures of SICI (C-SICI) quantify inhibition by the amplitude of the motor evoked potential (MEP), alternative measures involving threshold tracked SICI (TT-SICI) instead record the TMS intensity required to maintain a consistent MEP amplitude. Although both C-SICI and TT-SICI are thought to reflect inhibition mediated by γ-aminobutyric acid type A (GABA_A) receptors, recent evidence suggests that the mechanisms involved with each measure may not be equivalent. This study aimed to use combined TMS-electroencephalography (TMS-EEG) to investigate the cortical mechanisms contributing to C-SICI and TT-SICI.Materials and MethodsIn 20 young adults (30.6 ± 8.1 years), C-SICI and TT-SICI were recorded with multiple conditioning intensities, using both posterior-to-anterior (PA) and anterior-to-posterior (AP) induced currents, and this was compared with the TMS-evoked EEG potential (TEP).ResultsWe found no relationship between the magnitude of C-SICI and TT-SICI within each current direction. However, there was a positive relationship between the slope (derived from multiple conditioning intensities) of inhibition recorded with C-SICI and TT-SICI, but only with a PA current. Furthermore, irrespective of conditioning intensity or current direction, measures of C-SICI were unrelated to TEP amplitude. In contrast, TT-SICI was predicted by the P30 generated with AP stimulation.ConclusionsOur findings further demonstrate that C-SICI and TT-SICI likely reflect different facets of GABA_A-mediated processes, with inhibition produced by TT-SICI appearing to align more closely with TMS-EEG measures of cortical excitability.     

Associative plasticity in intracortical inhibitory circuits in human motor cortex

ObjectivePaired associative stimulation (PAS) is a transcranial magnetic stimulation technique inducing Hebbian-like synaptic plasticity in the human motor cortex (M1). PAS is produced by repetitive pairing of a peripheral nerve shock and a transcranial magnetic stimulus (TMS). Its effect is assessed by a change in size of a motor evoked response (MEP). MEP size results from excitatory and inhibitory influences exerted on cortical pyramidal cells, but no robust effects on inhibitory networks have been demonstrated so far.MethodIn 38 healthy volunteers, we assessed whether a PAS intervention influences three intracortical inhibitory circuits: short (SICI) and long (LICI) intracortical inhibitions reflecting activity of GABA_A and GABA_B interneurons, respectively, and long afferent inhibition (LAI) reflecting activity of somatosensory inputs.ResultsAfter PAS, MEP sizes, LICI and LAI levels were significantly changed while changes of SICI were inconsistent. The changes in LICI and LAI lasted 45 min after PAS. Their direction depended on the delay between the arrival time of the afferent volley at the cortex and the TMS-induced cortical activation during the PAS.ConclusionsPAS influences inhibitory circuits in M1.SignificancePAS paradigms can demonstrate Hebbian-like plasticity at selected inhibitory networks as well as excitatory networks.     

Are there differences in cortical excitability between akinetic-rigid and tremor-dominant subtypes of Parkinson's disease?

ObjectiveTo assess by transcranial magnetic stimulation (TMS) the excitability of various cortical circuits in akinetic-rigid and tremor-dominant subtypes of Parkinson's disease (PD).MethodsThe study included 92 patients with PD according to UK Brain Bank criteria, with akinetic-rigid (n = 64) or tremor-dominant (n = 28) subtype. Cortical excitability study, including resting and active motor thresholds (rMT and aMT), input—output curve of motor evoked potentials, contralateral and ipsilateral silent periods (cSP and iSP), short and long-interval intracortical inhibition (SICI and LICI), and intracortical facilitation (ICF) were measured. The results obtained were compared to a control group of 30 age- and sex-matched healthy subjects.ResultsThe patients in the tremor group had significantly lower rMT and aMT compared to controls and akinetic-rigid patients and significantly shorter iSP duration compared to akinetic-rigid patients, while iSP latency tended to be longer in akinetic-rigid patients compared to controls. There were no significant differences between the two PD subgroups regarding other cortical excitability parameters, including paired-pulse TMS parameters.ConclusionsOnly subtle differences of cortical excitability were found between patients with akinetic-rigid vs. tremor-dominant subtype of PD.SignificanceThe clinical heterogeneity of PD patients probably has an impact on cortical excitability measures, far beyond the akinetic-rigid versus tremor-dominant profile.     

Cortical myoclonus in childhood and juvenile onset Huntington's disease

ObjectiveHuntington's disease (HD) appearing before the age of 20 years gives rise to a distinct phenotype with respect to the classical adult-onset disease. Here we describe three patients with childhood or juvenile HD onset presenting with action myoclonus.MethodsWe performed jerk-locked back-averaging (JLBA), EEG-EMG coherence and phase analysis, long-loop reflexes (LLRs) and somatosensory evoked potentials (SSEPs). In one patient, we also performed transcranial magnetic stimulation (TMS) using single and paired pulses.ResultsIn all patients, the EMG features revealed movement activated quasi-rhythmic repetitive jerks; the JLBA and EEG-EMG spectral and coherence profiles indicated a cortical generator of the myoclonus. All patients had enhanced LLRs during muscle contraction, while none showed giant SSEPs. The evaluation of intracortical inhibition by means of TMS revealed reduced inhibition at short and long interstimulus intervals.ConclusionsThe rhythmic course of the action myoclonus and the characteristics of the LLRs suggest that myoclonus is due to a reverberant circuit involving the motor cortex, possibly because of an imbalance between excitatory and inhibitory cortical neuronal systems.SignificanceOur findings suggest a similar cortical dysfunction in childhood and juvenile onset HD, which probably results from a specific circuitry impairment.     

Age-related Differences in Short- and Long-interval Intracortical Inhibition in a Human Hand Muscle

BackgroundEffects of age on the assessment of intracortical inhibition with paired-pulse transcranial magnetic stimulation (TMS) have been variable, which may be due to between-study differences in test TMS intensity and test motor evoked potential (MEP) amplitude.ObjectiveTo investigate age-related differences in short- (SICI) and long-interval intracortical inhibition (LICI) across a range of test TMS intensities and test MEP amplitudes.MethodsIn 22 young and 18 older subjects, SICI and LICI were recorded at a range of test TMS intensities (110%–150% of motor threshold) while the first dorsal interosseous (FDI) muscle was at rest, or producing a precision grip of the index finger and thumb. Data were subsequently compared according to the amplitude of the MEP produced by the test alone TMS.ResultsWhen pooled across all test TMS intensities, SICI in resting muscle and LICI in active muscle were similar in young and older adults, whereas SICI in active muscle and LICI in resting muscle were reduced in older adults. Regrouping data based on test MEP amplitude demonstrated similar effects of age for SICI and LICI in resting muscle, whereas more subtle differences between age groups were revealed for SICI and LICI in active muscle.ConclusionsAdvancing age influences GABA-mediated intracortical inhibition, but the outcome is dependent on the experimental conditions. Age-related differences in SICI and LICI were influenced by test TMS intensity and test MEP amplitude, suggesting that these are important considerations when assessing intracortical inhibition in older adults, particularly in an active muscle.     

Transcranial magnetic stimulation modulation of corticospinal excitability by targeting cortical I-waves with biphasic paired-pulses

Background

Transcranial magnetic stimulation (TMS) induced I-wave behavior can be demonstrated at neuronal population level using paired-pulses and by observing short-interval cortical facilitation (SICF). Advancements in stimulator technology have made it possible to apply biphasic paired-pulses to induce SICF.

Determination of anodal tDCS duration threshold for reversal of corticospinal excitability: An investigation for induction of counter-regulatory mechanisms

BackgroundTranscranial direct current stimulation (tDCS) is used to induce neuroplasticity in the human brain. Within certain limits of stimulation duration, anodal tDCS (a-tDCS) over the primary motor cortex induces long term potentiation- (LTP) like plasticity. A reversal of the direction of plasticity has however been described with prolonged a-tDCS protocols.ObjectiveWe aimed to systematically investigate the intervention duration threshold for reversal of a-tDCS-induced effects on corticospinal excitability (CSE) and to determine the probable mechanisms involved in these changes.MethodsFifteen healthy participants received a-tDCS of 1 mA for five different durations in pseudo-random session order. Transcranial magnetic stimulation (TMS) was delivered over the left M1, and motor evoked potentials (MEPs) of a contralateral hand muscle were recorded before, immediately and 30 min following intervention to measure CSE changes. Short-interval intracortical inhibition (SICI), intracortical facilitation (ICF), and long interval facilitation (LIF) were assessed via paired-pulse TMS protocols.ResultsA-tDCS significantly increased CSE as expected at stimulation durations of 22 and 24 min. However, this effect of a-tDCS on CSE decreased and even reversed when stimulation duration increased to 26, 28, and 30 min. Respective alterations of ICF, LIF, and SICI indicate the involvement of glutamatergic, and GABAergic systems in these effects.ConclusionsThese results confirm a duration threshold for reversal of the excitability-enhancing effect of a-tDCS with stimulation durations ≥ 26 min. Counter-regulatory mechanisms are discussed as a mechanistic foundation for these effects, which might prevent excessive brain activation.     

Motor cortex excitability in transient global amnesia

Abstract.Objective: To investigate the physiology of motor cortical areas in patients with transient global amnesia (TGA).Materials and methods: We performed transcranial magnetic stimulation (TMS) and single photon emission computed tomography (SPECT) in 13 patients during and after the acute phase of a typical episode of TGA. Measures of cortical excitability included motor threshold (MT) to magnetic stimulation, cortical silent period (SP) duration and intracortical inhibition (ICI) using a paired-pulse TMS technique.Results: We found thalamic hypoperfusion and an ipsilateral significantly decreased ICI during the acute phase of TGA.Conclusions: Reduced activity in inhibitory circuits may explain why PET studies of patients with TGA showed neocortical hypometabolism. Our findings are consistent with the hypothesis that frontal cortex dysfunction probably due to damage affecting the thalamocortical circuits may play an important role in the pathogenesis of the syndrome.     

Effects of lacosamide and carbamazepine on human motor cortex excitability: A double-blind,placebo-controlled transcranial magnetic stimulation study

PurposeLacosamide (LCM) and carbamazepine (CBZ) are antiepileptic drugs both acting on neuronal voltage-gated sodium channels. Patch-clamp studies demonstrated significant differences in how LCM and CBZ affect neuronal membrane excitability. Despite valuable information patch-clamp studies provide, they also comprise some constraints. For example, little is known about effects of LCM on intracortical synaptic excitability. In contrast, transcranial magnetic stimulation (TMS) can describe drug-induced changes at the system level of the human cerebral cortex.MethodsThe present study was designed to explore dose-depended effects of LCM and effects of CBZ on motor cortex excitability with TMS in a randomized, double-blind, placebo-controlled crossover trial in healthy human subjects. Subjects received 600 mg CBZ, 200 mg LCM, 400 mg LCM or placebo preceding TMS measurements.ResultsCompared to placebo, TMS motor thresholds were significantly increased after carbamazepine and lacosamide, with a trend for a dose dependent effect of lacosamide. Both, carbamazepine and lacosamide did not affect TMS parameters of intracortical synaptic excitability.ConclusionsTMS measurements suggest that lacosamide and carbamazepine predominantly act on neuronal membrane excitability.