Abnormal postexcitatory and interhemispheric motor cortex inhibition in writer's cramp

Focal transcranial magnetic stimulation (TMS) of the motor cortex was used to study excitatory and inhibitory stimulation effects in 25 patients with writer's cramp and 25 healthy volunteers. We investigated excitatory and inhibitory corticospinally mediated motor effects in muscles contralateral to the stimulation side as well as interhemispheric inhibition of tonic motor activity in muscles ipsilateral to stimulation. Motor evoked potentials (MEPs) were recorded from both first dorsal interosseus muscles. Motor thresholds at rest and amplitudes and latencies of MEPs obtained during maximal contraction were always bilaterally normal. The duration of postexcitatory inhibition was significantly shortened (168±55 vs. 198±39 ms in normal subjects, P=0.001) and the duration of interhemispheric inhibition prolonged (30.3±6.6 vs. 26±3.9 ms in normal subjects, P < 0.001). Both observations would be compatible with a decreased inhibition of corticospinal and transcallosal outputs of the motor cortex. The results were not influenced by fatigue effects. Abnormal motor cortex inhibition seems to be a generalized phenomenon in writer's cramp since it was detected in both hemispheres and during a simple isometric motor task which did not evoke dystonic symptoms. Received: 28 February 2000 / Received in revised form: 29 June 2000 / Accepted: 1 August 2000     

Callosal and corticospinal tract function in patients with hydrocephalus: a morphometric and transcranial magnetic stimulation study

In 15 patients with symptomatic hydrocephalus, pressure-induced morphological changes of the brain and the function of callosal and corticospinal fibres were studied. Morphometry of the corpus callosum (CC) was performed on midsagittal MR images. Focal transcranial magnetic stimulation of the motor cortex was used to assess simultaneously excitatory motor responses in contralateral hand muscle (corticospinally mediated effect) and inhibition of tonic EMG activity in ipsilateral hand muscles (transcallosal inhibition (TI) of the contralateral motor cortex). Before a shunt operation, the midsagittal area of the CC was reduced by 34% on average. The height and, to a lesser degree the length, of the CC were increased before the shunt operation. Thresholds and central motor latencies of corticospinally mediated responses were normal, response amplitudes were smaller than in normal subjects. Motor thresholds increased from 38, SD 5 to 52, SD 8% (P<0.01) within 7 days after ventricular drainage, reflecting the increase in the distance between stimulation coil and brain. The threshold increase paralleled a restoration of normal anatomical conditions within 7 days after shunt operation and the improvement of motor symptoms and might be a predictor of successful decompression. Transcallosal inhibition could be elicited in all patients. The measurements of TI lay within the normal range except the duration, which was prolonged in 73% of 15 patients before shunt operation as a probable indicator of an increased dispersion of callosal conduction. The normalization of the area and shape of the CC after shunt operation and the normal corticospinal and callosal conduction times exclude degeneration, demyelination or functional block of a large proportion of callosal or corticospinal tract fibres or a substantial loss of nerve cells in motor cortex. Received: 22 October 1997 Received in revised form: 13 January 1998 Accepted: 17 January 1998     

Demyelination and axonal degeneration in corpus callosum assessed by analysis of transcallosally mediated inhibition in multiple sclerosis.

OBJECTIVE: Following focal transcranial magnetic cortex stimulation (fTMS), inhibition of voluntary EMG activity in the ipsilateral first dorsal interosseus (FDI) muscle was studied, in order to assess the functional integrity of the corpus callosum in patients with multiple sclerosis (MS). METHODS AND RESULTS: Thirty-four patients suffering from definite MS and 12 healthy, age-matched normal subjects were examined. In mid-sagittal slices, 29 patients showed lesions within the truncus corporis callosi in T2-weighted MRI. In 20 patients, all areas (anterior, middle and posterior parts), in one both the anterior and posterior part, in 3 exclusively the anterior, in 4 the middle and in one the posterior area were affected. In 5 patients, lesions of corpus callosum were lacking. In normal subjects, fTMS elicited a transient inhibition (TI) of preactivated (50% of maximal force) isometric voluntary ipsilateral FDI muscle activity. Mean onset latencies of TI were 35.5+/-5.4 ms in right and 36.1+/-4.2 ms in left FDI. Mean duration of TI amounted to 23.0+/-8.4 ms for right and 24.6+/-8.4 ms for left FDI. In the MS group, TI latencies were significantly increased in 23 and TI durations in 16 cases, whereas a lack of TI was found in 5 patients bilaterally and in 6 unilaterally. In patients, mean onset latencies of TI were 40.4+/-13.8 ms in right and 43.3+/-14.4 ms in left FDI, TI duration amounted to 30.5+/-17.4 ms for right and 31.0+/-25.2 ms for left FDI. Increase of onset latencies and durations of TI were positively correlated with the summed area of lesions of corpus callosum in representative mid-sagittal MRI slices. Significant correlations between TI onset latencies and duration on the one hand, and central motor conduction latencies along corticospinal tracts (CML) on the other hand, were not found. CONCLUSION: The present investigation indicates that measurement of TI elicited by fTMS seems to be a sensitive method for an assessment of demyelination and axonal degeneration within corpus callosum in MS patients.     

Correlates of disability in multiple sclerosis detected by transcranial magnetic stimulation

OBJECTIVE: To study the usefulness of corticospinally mediated excitatory responses and transcallosal inhibition (TI) elicited by transcranial magnetic stimulation (TMS) as a surrogate marker of disability in patients with different courses of MS. METHODS: Focal TMS of the motor cortex was performed in 118 patients with MS (96 with relapsing-remitting, 19 with primary progressive, and three with secondary progressive disease) who had an Expanded Disability Status Scale (EDSS) score between 0 and 6.5 and in 35 normal subjects. Central motor latencies (CML) and TI (onset latency, duration) were investigated. The Spearman rank correlation was used for statistical analysis. RESULTS: TMS disclosed prolonged CML in 52.5% and abnormal TI in 61% of the patients. In all patients the EDSS correlated with the frequency of abnormal TI (r = 0.58, p < 0.01) and abnormal CML (r = 0.51, p < 0.01). In patients with primary progressive MS (EDSS 1.5 to 6.5) the frequency of TI abnormalities correlated with EDSS (r = 0.65, p < 0.01) whereas CML did not. Delayed corticospinal responses in hand muscles always led to abnormal TI. CONCLUSIONS: The combination of central motor latencies and transcallosal inhibition evoked by transcranial magnetic stimulation yields objective data to estimate disease progression in MS as assessed by the EDSS.     

Dysfunction of transcallosally mediated motor inhibition and callosal morphology in patients with schizophrenia

OBJECTIVE: In order to assess the functional integrity of motor pathways through the corpus callosum (CC) in patients with schizophrenia transcallosally mediated inhibition (TI) of voluntary tonic EMG activity of first dorsal interosseus muscle following ipsilateral focal transcranial magnetic stimulation (fTMS) was investigated. In addition thickness and length of CC were calculated. METHOD: Twelve patients suffering from schizophrenia and 12 healthy controls were investigated. CC morphology was measured in mid-sagittal MRI-slices. Latency and duration of TI were calculated. RESULTS: In schizophrenics the duration of TI was significantly prolonged, whereas latencies were not. In addition, a lack of TI was found unilaterally in three patients. Measurements of CC revealed a significantly reduction of the length and thickness in the anterior part of CC in patients. CONCLUSION: These findings indicate that measurement of TI could be used to detect clinical silent affection of transcallosal motor pathways in schizophrenics. The effect of neuroleptic drugs has to be explored.     

Conduction deficits of callosal fibres in early multiple sclerosis

OBJECTIVE: To study the diagnostic usefulness of transcallosal inhibition (TI) elicited by transcranial magnetic stimulation (TMS) in detecting central conduction deficits in early multiple sclerosis. Corticospinally mediated excitatory responses evoked by TMS are accepted as a sensitive diagnostic tool in multiple sclerosis. Recently, TI evoked by TMS has been introduced as a new paradigm to test the function of callosal fibres interconnecting both hand associated motor cortices. METHODS: Focal TMS of the motor cortex was performed in 50 patients with early relapsing-remitting multiple sclerosis. Corticospinally mediated (central motor latencies, amplitudes) and transcallosally mediated (onset latency and duration of TI) stimulation effects were investigated. RESULTS: TMS disclosed abnormalities of corticospinally mediated responses in 62% and of TI in 80% of the patients. CONCLUSION: The assessment of TI allows the discovery of lesions within the periventricular white matter that were not accessible by neurophysiological techniques before. This new paradigm increases the sensitivity of TMS with which to detect central conduction deficits in early multiple sclerosis.     

Effect of fatiguing maximal voluntary contraction on excitatory and inhibitory responses elicited by transcranial magnetic motor cortex stimulation

Vertex transcranial magnetic stimulation (TMS) elicited tibialis anterior motor evoked potentials (MEPs) and silent periods (SPs) that were recorded during and following isometric maximal volitional contraction (MVC). During MVC in 6 healthy subjects, MEP amplitudes in the exercised muscle showed an increasing trend from an initial value of 4539 ± 809 μV (mean ± SE) to 550 ± 908 μV (P < 0.13) while force and EMG decreased (P < 0.01). Also, SP duration increased from 165 ± 37 ms to 231 ± 32 ms (P < 0.01). Thus, during a fatiguing MVC both excitatory and inhibitory TMS-induced responses increased. TMS delivered during repeated brief 10% MVC contractions before and after a fatiguing MVC in 5 subjects, showed no change in MEP amplitude but SP duration was prolonged after MVC. This SP prolongation was focal to the exercised muscle. Silent periods recorded after pyramidal tract stimulation were unchanged following the MVC. These results suggest that MEP and SP might have common sources of facilitation during an MVC and that inhibitory mechanisms remain focally augmented following a fatiguing MVC. © 1996 John Wiley & Sons, Inc.     

Handedness is mainly associated with an asymmetry of corticospinal excitability and not of transcallosal inhibition.

OBJECTIVE: The study aims to compare transcallosal inhibition (TI), as assessed by the paired-pulse transcranial magnetic stimulation (TMS) technique, in a sample of right-handed subjects (RH) and left-handed subjects (LH). Motor thresholds (MTs) and motor evoked potential (MEP) amplitudes were also measured in the two groups, as an index of corticospinal activity. METHODS: Thirty-two normal subjects (16 RH and 16 LH) were recorded with a paired-pulse TMS paradigm (intensity of both pulses=120% of MT). The inter-stimulus intervals (ISIs) were 2, 4, 6, 8, 10, 12, 14, 16, 18, and 20 ms for both motor cortices, and MEP responses were recorded from the abductor digiti minimi muscles. RESULTS: Both groups showed a clear TI centred around the 12 ms ISI, but no difference was found as a function of handedness or of hemisphere. On the other hand, the two groups differed in terms of corticospinal activity, since the hand motor dominant hemisphere had lower MTs than the non-dominant one in LH, and larger MEP amplitudes for the right hand were found in RH. CONCLUSIONS: Results point to a functional asymmetry of the motor cortex on the hand-dominant versus the non-dominant hemisphere, while handedness does not seem associated with functional differences in callosal inhibition, as measured by the inter-hemispheric paired-pulse TMS technique.     

Abnormalities of cortical inhibitory neurons in amyotrophic lateral sclerosis

We have used peristimulus time histograms to study how paired, transcranial magnetic stimulation alters the firing of single motor units and the magnitude of unitary excitatory postsynaptic potentials (EPSPs) recorded from the extensor digitorum communis muscle. With stimulus intensity at threshold and an interstimulus interval of 30 ms, normal subjects (n = 20) demonstrated marked inhibition with a mean test/conditioning EPSP ratio of 13.8% (range 0–51%) and in 7 subjects the ratio was 0 (100% inhibition). In amyotrophic lateral sclerosis (ALS) the ratio was 133% (range 64–267%), P < 0.001. Fifty percent of patients had a test/conditioning EPSP ratio greater than 100% (0 inhibition). The abnormalities were independent of disease severity, bulbar versus spinal ALS, more prominent upper versus lower motor neuron findings, and disease duration. Normal inhibition occurred in 3 individuals, 1 each with multiple sclerosis, Kennedy's syndrome, and monomelic amyotrophy. We speculate that the marked loss of inhibition seen in all patients with ALS, which may be unique to this disorder, reflects loss of inhibitory modulation of the corticomotoneuron and could result in their chronic excitatory drive and eventual demise. © 1997 John Wiley & Sons, Inc.     

Stimulus-response properties of motor system in patients with cerebellar ataxia.

OBJECTIVE: The aim of the study was to examine the stimulus-response properties of the excitatory and inhibitory components of corticospinal projections at rest and during voluntary contraction in cerebellar patients. METHODS: We investigated motor evoked potential (MEP) and cortical silent period recruitment curves in response to increasing intensities of transcranial magnetic stimulation in 8 patients with 'pure' cerebellar syndromes and in 14 age-matched controls. The transcranial magnetic stimulation intensity was increased from 90 to 180% of the resting motor threshold. MEP recruitment curves were recorded at rest and during voluntary contraction in the right abductor pollicis brevis muscle. RESULTS: No statistical differences were found between patients and controls in MEP recruitment curves in either the resting or active condition. A significant difference was found between patients and controls in the cortical silent period threshold (patients: 33.2+/-3.4% of maximal stimulator output; controls 39.4+/-3.2%; P=0.01) and recruitment curve, the duration of the cortical silent period being longer in patients at transcranial magnetic stimulation intensities ranging from 90 to 130% of the resting motor threshold (patients: 135-191 ms; controls: 53-158 ms). No changes were found in the silent period evoked by peripheral nerve stimulation. CONCLUSIONS: Inhibitory components of corticospinal projections were recruited with a lower threshold in patients. No abnormalities were found in the recruitment of the excitatory networks. Our data show a prevalence of inhibitory phenomena in the motor cortex of cerebellar patients. These findings would appear to be specific to cerebellar diseases and are the opposite of those previously documented in movement disorders such as dystonia and Parkinson's disease. Our results suggest that the cerebellum and the basal ganglia may counteract each other in modulating the level of motor system excitability.     

Modulation of single motor unit discharges using magnetic stimulation of the motor cortex in incomplete spinal cord injury

OBJECTIVES: Motor evoked potentials (MEPs) and inhibition of voluntary contraction to transcranial magnetic stimulation (TMS) of the motor cortex have longer latencies than normal in patients with incomplete spinal cord injury (iSCI) when assessed using surface EMG. This study now examines the modulation of single motor unit discharges to TMS with the aim of improving resolution of the excitatory and inhibitory responses seen previously in surface EMG recordings. METHODS: A group of five patients with iSCI (motor level C4-C7) was compared with a group of five healthy control subjects. Single motor unit discharges were recorded with concentric needle electrodes from the first dorsal interosseus muscle during weak voluntary contraction (2%-5% maximum). TMS was applied with a 9 cm circular stimulating coil centred over the vertex. Modulation of single motor unit discharges was assessed using peristimulus time histograms (PSTHs). RESULTS: Mean (SEM) threshold (expressed as percentage of maximum stimulator output (%MSO)) for the excitatory peak (excitation) or inhibitory trough (inhibition) in the PSTHs was higher (p<0.05) in the patients (excitation = 47.1 (5.9) %MSO; inhibition = 44.3 (3.2) %MSO) than in controls (excitation=31.6 (1.2) %MSO; inhibition = 27.4 (1.0) %MSO). Mean latencies of excitation and inhibition were longer (p<0.05) in the patients (excitation=35 (1.8) ms; inhibition = 47.1 (1.8) ms) than in the controls (excitation = 21.1 (1.6) ms; inhibition = 27 (0.4) ms). Furthermore, the latency difference (inhibition-excitation) was longer (p<0.05) in the patients (10.4 (2.1) ms) than in the controls (6.2 (0.6) ms). CONCLUSION: Increased thresholds and latencies of excitation and inhibition may reflect degraded corticospinal transmission in the spinal cord. However, the relatively greater increase in the latency of inhibition compared with excitation in the patients with iSCI may reflect a weak or absent early component of cortical inhibition. Such a change in cortical inhibition may relate to the restoration of useful motor function after iSCI.     

Pseudo-bilateral hand motor responses evoked by transcranial magnetic stimulation in patients with deep brain stimulators.

OBJECTIVES: In 3 of 5 patients with dystonia and bilaterally implanted deep brain stimulating electrodes, focal transcranial magnetic stimulation (TMS) of one motor cortex elicited bilateral hand motor responses. The aim of this study was to clarify the origin of these ipsilateral responses. METHODS: TMS and electrical stimulation of corticospinal fibres by the implanted electrodes were performed and the evoked hand motor potentials were analysed. RESULTS: In comparison with responses elicited by contralateral motor cortex stimulation, ipsilateral responses were smaller in amplitude (3.0+/-1.4 versus 5.8+/-1.5 mV), had shorter peak latencies (first negative peak: 20.9+/-0.8 versus 25.1+/-0.4 ms) and were followed by a shorter-lasting silent period (46+/-4 versus 195+/-35 ms). Ipsilateral responses following TMS had similar peak latencies to responses elicited subcortically by deep brain stimulation (DBS) (20.4+/-0.9 ms). CONCLUSIONS: Hand motor responses ipsilateral to TMS result from a subcortical activation of corticospinal fibres, via the implanted electrode in the other hemisphere, secondary to currents induced by TMS in subcutaneous wire loops that underlie the magnetic coil. Studies of TMS in patients with DBS have to take this potential source of confounding into account.     

Transcallosal motor pathway from affected motor cortex to affected hand in a patient with corona radiata infarct A diffusion tensor tractography and transcranial magnetic stimulation study

The mechanisms of motor recovery through the transcallosal pathway remain poorly understood.The present study reports on a hemiplegic patient with corona radiata infarct; it attempts to confirm motor recovery through the transcallosal motor pathway, from the affected motor cortex to the affected hand, using diffusion tensor tractography and transcranial magnetic stimulation. A 54-year-old, male patient and eight age-matched, normal subjects were enrolled in the study. The patient's right hand was initially completely paralyzed, but slowly recovered over 6 months. In the control subjects and the unaffected hemisphere (right) of the patient, the corticospinal tracts originated from the motor cortex and descended along the known corticospinal tract pathway.However, the corticospinal tract of the affected hemisphere was disrupted at the upper pons.Following transcranial stimulation of the affected (left) motor cortex, motor evoked potential from the affected (right) abductor pollicis brevis muscle exhibited longer latency than opposite motor evoked potential. Results from the present study suggest that motor function of the affected (right) hand recovered via the transcallosal motor pathway from the affected (left) motor cortex in this patient.     

Absence of transcallosal inhibition following focal mangnetic stimulation in preschool children

Focal transcranial magnetic stimulation of the hand-associated motor cortex was used to study normal healthy preschool children (n = 7; mean age, 4.6 years) and adults (n = 7; mean age, 29.4 years) under the conditions of standardized tonic voluntary contraction of small hand muscles. Callosally mediated inhibitory as well as corticospinally mediated inhibitory and excitatory motor effects were investigated. Although children had no detectable transcallosal inhibition, their corticospinally mediated postexcitatory silent period was present (mean, 140.8 ± 30.2 msec). It was significantly shorter then in adults (mean, 192.5 ± 32.0 msec). The motor thresholds of the cortically elicited muscle responses, measured as the lowest stimulus intensity, were significantly higher in children (mean, 89 ± 5%) than in adults (mean, 46 ± 6%). The corticomuscular latency of transcranially elicited motor responses revealed no difference between children and adults. These observations may reflect maturation processes in the motor system. Maturation of at least some direct corticospinal fibers occurs early in life and is followed by that of intracortical excitatory and inhibitory connections. The maturation of functionally competent callosal connections appears to occur after the age of 5 years.     

Changes of inhibitory interneurons during transcallosal stimulations

Summary The present study was performed in order to determine the influence of ipsilateral transcranial magnetic stimulations (TMS) on the silent period evoked by contralateral cortical stimulations. Ipsilateral TMS preceded the contralateral magnetic or electrical cortex stimulation by 0–50ms. In all subjects, the duration of the silent period was decreased in interstimulus intervals of 20–30ms when using magnetic ipsi- and contralateral stimuli. No change in the silent period was seen with ipsilateral magnetic and contralateral electrical stimulations. Decreases of motor evoked potential amplitudes were an inconsistant phenomenon.The results indicate that ipsilateral TMS in activate inhibitory cortical interneurons, probably via transcallosal pathways. Different time courses and different degrees of inhibition indicate that motor excitation and inhibition may be mediated by different neuronal circuits.     

Abnormalities of inhibitory neuronal mechanisms in the motor cortex of patients with schizophrenia

BACKGROUND: Focal transcranial magnetic stimulation (TMS) of the motor cortex was used to study two cortically activated inhibitory neuronal mechanisms that suppress ongoing tonic voluntary electromyographic activity in contralateral (postexcitatory inhibition [PI]) and ipsilateral (transcallosal inhibition [TI]) hand muscles. The PI follows the corticospinally mediated excitatory motor response (MEP) and is influenced by dopaminergic neurotransmission. TI reflects transcallosally mediated inhibition of the contralateral motor cortex, leading to motor inhibition in muscles ipsilateral to stimulation. PI and TI were studied to explore whether dopaminergic neurotransmission or interhemispheric transfers are altered in schizophrenia. METHODS: TMS was performed in 16 patients with this disease and in 16 healthy control subjects. Surface electromyographic activity was recorded bilaterally from the first dorsal interosseous muscle during a sustained strong isometric contraction. RESULTS: When compared with the findings in healthy subjects, patients with schizophrenia had a significantly longer PI and TI. The changes of the PI support the notion of an overactivity of the central dopaminergic system in schizophrenia. CONCLUSION: The prolonged TI suggests an abnormal activation of interhemispheric connections between the motor cortices and may be related to previously reported pathology of the corpus callosum in schizophrenic patients.     

Interhemispheric inhibition in patients with multiple sclerosis

Objectives: A single focal magnetic stimulus applied to the motor cortex of normal subjects can suppress ongoing voluntary electromyographic activity in ipsilateral small hand muscles. This inhibition is mediated from one motor cortex to the contralateral side via a transcallosal pathway. Methods: We have investigated transcallosal inhibition in 24 patients with definite multiple sclerosis (MS) and in 24 healthy volunteers. A focal magnetic stimulus was applied to the hand area of the motor cortex and the onset latency of the inhibition of the ongoing EMG activity of the ipsilateral first dorsal interosseus muscle was evaluated. Cortico-motor conduction time to the same muscle was revealed, using a magnetic stimulus over the contralateral motor cortex. The difference between these values was calculated as transcallosal conduction time. Cerebral magnetic resonance imaging (MRI) scans including sagittal T2-weighted images were performed in 18 patients. Results: The depth of inhibition (maximal inhibition as percentage of the baseline EMG) in the MS patients was comparable to normal values, but the transcallosal conduction time was significantly delayed (patients 17.2±6.4 ms; normal subjects 12.2±2.6 ms; P<0.001). The duration of the inhibition was significantly prolonged in MS patients (patients 47.9±20.9 ms; normal subjects 38.9±10.1 ms; P=0.02). Transcallosal conduction time was delayed in 11 (46%) of 24 patients, compared with normal subjects. It exceeded the normal range (mean±2.5 SD) in one normal subject (specifity 96%). No correlation could be found between the size or extent of the lesions obtained from the MRI scan and the onset latency or the depth of the inhibition. Conclusions: We conclude that conduction over transcallosal connections is significantly slower in patients with MS.     

Absence of transcallosal inhibition in adolescents with diplegic cerebral palsy

The role of intracortical organization in the pathophysiology of cerebral palsy (CP) is not clear. We used transcranial magnetic stimulation to investigate the paradigm of transcallosal inhibition (TI) in a group of adolescent patients with diplegic CP (n = 4), hereditary spastic paraplegia (n = 2), and healthy control adolescents (n = 4). None of the patients with CP showed TI, whereas all other subjects had normal TI. These findings indicate a lack of inhibitory control of the motor cortex in CP.     

Covariation of corticospinal efficiency and silent period in motoneuron diseases

For a better understanding of the changes affecting the cortically induced silent period (SP) in motoneuron disease, the excitatory and inhibitory effects of transcranial magnetic stimulation were explored repeatedly in 8 patients with amyotrophic lateral sclerosis (ALS), 3 patients with Kennedy's disease (KD), and 10 healthy subjects. In KD, the background electromyogram (EMG) and the motor evoked potential (MEP) area were both enhanced. However, neither the corticospinal efficiency (MEP gain, the ratio between MEP and background EMG) nor the duration of the SP differed from healthy subjects. In ALS patients, the MEP gain and the SP duration decreased conspicuously with time. We conclude that use of the MEP gain improves detection of corticospinal dysfunction in ALS patients. Part of the SP shortening in ALS seems to reflect the reduced activation of cortical or spinal inhibitory networks by the abnormal corticospinal pathway.