Correlates of disability in multiple sclerosis detected by transcranial magnetic stimulation

Interhemispheric inhibition in distal and proximal arm representations in the primary motor cortex

Interhemispheric inhibitory interactions (IHI) operate between homologous distal hand representations in primary motor cortex (M1). It is not known whether proximal arm representations exhibit comparable effects on their homologous counterparts. We studied IHI in different arm representations, targeting triceps brachii (TB, n = 13), first dorsal interosseous (FDI, n = 13), and biceps brachii (BB, n = 7) muscles in healthy volunteers. Transcranial magnetic stimulation test stimuli (TS) were delivered to M1 contralateral to the target muscle preceded 10 ms by a conditioning stimulus (CS) to the opposite M1 at 110-150% resting motor threshold (RMT). IHI was calculated as the ratio between motor-evoked potential (MEP) amplitudes in conditioned relative to unconditioned trials. Mean RMTs were 38.9, 46.9, and 46.0% of stimulator output in FDI, TB, and BB muscles, respectively. IHI was 0.45 +/- 0.41 (FDI), 0.78 +/- 0.38 (TB), and 0.52 +/- 0.32 (BB, P < 0.01) when test MEP amplitudes were matched and 0.28 +/- 0.17 (FDI) and 0.85 +/- 0.31 (TB, P < 0.05) when TS intensities expressed as percentage RMT were matched. Significant IHI (P < 0.05) was identified with minimal CS intensities (expressed as percentage stimulator output) in the 30 s for FDI, 60 s for TB, and 40 s for BB. Additionally, a CS of roughly 120% RMT suppressed the test MEP but not a test H-reflex in BB, suggesting IHI observed in BB is likely mediated by a supraspinal mechanism. We conclude that IHI differs between different arm muscle representations, comparable between BB and FDI but lesser for TB. This finding suggests the amount of IHI between different arm representations does not strictly follow a proximal-to-distal gradient, but may be related to the role of each muscle in functional movement synergies.

Ipsilateral silent period: A marker of callosal conduction abnormality in early relapsing–remitting multiple sclerosis?

OBJECTIVE

The corpus callosum (CC) is commonly affected in multiple sclerosis (MS). The ipsilateral silent period (iSP) is a putative electrophysiological marker of callosal demyelination. The purpose of this study was to re-assess, under recently established optimised protocol conditions [Jung P., Ziemann U. Differences of the ipsilateral silent period in small hand muscles. Muscle Nerve in press.], its diagnostic sensitivity in MS, about which conflicting results were reported in previous studies.

METHODS

ISP measurements (onset, duration, and depth) were obtained in the abductor pollicis brevis (APB) muscle of either hand in 49 patients with early relapsing-remitting MS (RRMS) (mean EDSS, 1.3). Standard central motor conduction times to the APB (CMCT(APB)) and tibial anterior muscles (CMCT(TA)), and magnetic resonance images (MRI) were also obtained.

RESULTS

ISP measurements showed a similar diagnostic sensitivity (28.6%) as CMCT(APB) (24.5%), while diagnostic sensitivities of CMCT(TA) (69.4%) and MRI of the CC (78.6%) were much higher. Prolongation of iSP duration was the most sensitive single iSP measure. ISP prolongation occurred more frequently when CMCT(APB) to the same hand was also prolonged (40.0% vs. 8.4%, p<0.0001). The correlation between iSP duration and CMCT(APB) was significant (Pearson's r=0.24, p<0.02), suggesting that iSP duration can be contaminated by demyelination of the contralateral corticospinal tract. ISP duration did not correlate with MRI abnormalities of the CC.

CONCLUSIONS

ISP measures are neither a sensitive nor a specific marker of callosal conduction abnormality in early RRMS.

Differences of the ipsilateral silent period in small hand muscles

The ipsilateral silent period (iSP) is thought to depend on activity transmitted by the corpus callosum but ipsilateral corticospinal pathways may also contribute. Because the presence of ipsilateral corticospinal pathways differs between small hand muscles, we compared the iSP in the first dorsal interosseous (FDI) and abductor pollicis brevis (APB) muscles. The iSP was elicited in 20 healthy subjects by focal transcranial magnetic stimulation of one primary motor cortex during maximal voluntary contraction of the ipsilateral target muscle. The iSP duration was significantly longer in the FDI than APB because of an irregularly occurring second phase of inhibition in the FDI that was absent in the APB. Although the first phase of inhibition is transmitted by the corpus callosum, we provide evidence that the second phase is mediated through ipsilateral corticospinal pathways. Therefore, for specific assessment of callosal conduction, the iSP should be measured in the APB rather than FDI.

Loss of interhemispheric inhibition in patients with multiple sclerosis is related to corpus callosum atrophy

Axonal injury and loss in the corpus callosum (CC) is characteristic of the pathology of multiple sclerosis (MS). Functional magnetic resonance imaging (fMRI) potentially allows neurophysiological consequences of this interhemispheric axonal loss to be defined quantitatively. Here we have used 3T fMRI to study the activation in the contralateral primary sensorimotor cortex and deactivation (mediated by transcallosal tracts) in the homologous ipsilateral region in 14 patients with MS and in 14 matched healthy controls during a simple hand-tapping task. Both healthy controls and MS patients showed similar activation in the motor cortex contralateral to the hand moved, but the patients showed a significantly smaller relative deactivation in the ipsilateral motor cortex (P = 0.002). The difference was accounted for by the sub-group of MS patients who previously had impairment of motor function of the hand tested (MS-phd). The CC of the whole patient group was significantly thinner than for the controls (P = 0.001). Atrophy of the CC was correlated with loss of deactivation for the whole patient group (r = -0.50, P = 0.035), but particularly for MS-phd (r = -0.914, P = 0.004). Interhemispheric physiological inhibition thus is impaired in patients with MS, potentially contributing to impairment of motor control. This work suggests one way in which FMRI monitoring of the transcallosal interactions in motor cortex could become a tool for evaluation of therapies that may enhance function in reversibly impaired pathways.

La stimulation magnétique transcrânienne : applications en Neurologie

INTRODUCTION

Transcranial magnetic stimulation (TMS) was first applied to assess conduction time along the corticospinal tract, namely by recording motor evoked potentials.

STATE OF ART

At present, TMS techniques include cortical excitability and mapping studies using single or paired-pulse paradigms on the one hand, and repetitive TMS to induce cortical plasticity and to modify brain function on the other hand. TMS is a valuable, non-invasive tool in the diagnosis and the pathophysiological assessment of cortical dysfunction involved in various neurological diseases (multiple sclerosis, myelopathy, amyotrophic lateral sclerosis, movement disorders, epilepsy, stroke).

PERSPECTIVES AND CONCLUSION

In the near future, repetitive TMS could have therapeutic applications in neurology (epilepsy, stroke rehabilitation program) as is already the case in some psychiatric diseases. However, most of the new indications for treatment with cortical stimulation will be based on surgically-implanted neuromodulation procedures.

Corticomotor organisation and motor function in multiple sclerosis

Our objective was to determine whether there are changes in the corticomotor map for the hand in multiple sclerosis, and whether these changes correlate with indices of motor function and measures of corticomotor conduction or excitability. Transcranial magnetic stimulation (TMS) maps, motor evoked potential (MEP) latency and amplitude, motor threshold and EDSS and Purdue-pegboard measurements were made in 26 subjects with relapsing-remitting multiple sclerosis. Correlations were sought between these measurements using the Pearson product-moment correlation with a level of significance of p = 0.05 (two-tailed). Map displacement was positively correlated with MEP latency (p = 3 x 10(-4)) and EDSS (p = 0.007), and negatively correlated with Purdue score (p = 4 x 10(-4)). Purdue scores correlated with all MEP parameters (latency, p = 4 x 10(-10); threshold, p = 4 x 10(-6); amplitude, p = 0.003). We conclude that motor reorganisation is associated with impaired corticomotor conduction and may reflect a process of neural plasticity associated with axonal demyelination in MS. An understanding of motor function in MS should incorporate models of both axonal demyelination and conduction deficits as well as neural plasticity.

Physiological measures of therapeutic response to interferon beta-1a treatment in remitting-relapsing MS

OBJECTIVE

This pilot study was designed to determine the effects of interferon beta-1a (IFNB) therapy (Avonex) on cortically evoked motor potentials (MEPs) during resting and fatigued states in individuals with multiple sclerosis (MS).

METHODS

Eight women with relapsing-remitting MS (mean age 36) and mean Expanded Disability Status Scale (EDSS) score of 3.1 were evaluated before and after 3, 6, and 12 months of IFNB therapy. At each test period, MEPs were recorded at rest and following a fatigue paradigm (3 min maximal contraction). Effects of IFNB on neurological and functional (7.7 m walk and 10 s finger tapping) status and fatigue were also examined.

RESULTS

Recovery from post-exercise depression of MEP amplitudes (PED) was 41, 43, and 43.5% faster at 3, 6, and 12 months, respectively, compared to baseline (P < 0.05). Percent reduction of MEP amplitude was significantly less at 6 months (P < 0.05) The majority of subjects (5/8 at 3 months; 6/8 at 6 and 12 months) reported decreased physical fatigue. Functional improvements were observed for walk and finger tapping scores after 3 months of IFNB treatment. MEP latencies were unchanged over the course of the intervention.

CONCLUSIONS

Results indicate that IFNB therapy may improve the rate of recovery from central fatigue.

SIGNIFICANCE

Transcranial magnetic stimulation (TMS) may have promise as an objective physiological tool to evaluate disease activity and treatment responses in MS.

Should transcranial magnetic stimulation research in children be considered minimal risk?

OBJECTIVE

Transcranial magnetic stimulation (TMS) is a neurophysiologic technique with research applications. Institutional Review Boards (IRBs) must carefully consider potential risks and possible benefits in research involving children. The purpose of this study is to provide concise information for investigators and IRBs about the safety of single and paired pulse TMS research in children.

METHODS

This paper has 4 sections: (I) Regulations governing research in children are reviewed and applied to the use of TMS. (II) Energy imparted by TMS is assessed in terms of theoretical biological risks to human subjects. (III) Through MEDLINE review, the empirical evidence of risk from TMS is assessed. Reported adverse events, including issues related to risk of seizures and of hearing loss, are summarized. (IV) Safety data are presented from a study of TMS in children with Tourette Syndrome.

RESULTS

No published or empirical evidence was found to suggest that single or paired pulse TMS is associated with more than minimal risk in children.

CONCLUSIONS

IRBs may consider well-designed studies using single and paired pulse TMS protocols similar to those described in this study as bearing minimal risk to children.

SIGNIFICANCE

This manuscript may be useful as a reference to IRBs and TMS investigators.

Bimanual recoupling by visual cueing in callosal disconnection

The cerebral control of bimanual movements is not completely understood. We investigated a 59-year-old, right-handed man who presented with an acute bimanual coordination deficit. Magnetic resonance imaging showed a lesion involving the entire corpus callosum, which was found on stereotactic biopsy to be an ischemic infarct. Paired-pulse transcranial magnetic stimulation indicated that the patient had a lack of interhemispheric inhibition, while intracortical inhibition in motor cortex of either side was normal. Functional magnetic resonance imaging showed activation of the left SMA, the bilateral motor cortex and anterior cerebellum during spontaneous bimanual thumb-index oppositions, which were uncoupled as evident from simultaneous electromyographic recordings. In contrast, when the bimanual thumb-index oppositions were cued by a visual stimulus, the movements of both hands were tightly correlated. This synchronized activity was accompanied by additional activations bilateral in lateral occipital cortex, dorsal premotor cortex and cerebellum. The data suggest that the visually cued movements of both hands were recoupled by action of a bihemispheric motor network.

Brain excitability changes in the relapsing and remitting phases of multiple sclerosis: a study with transcranial magnetic stimulation

OBJECTIVE

Recent functional and imaging studies have substantially contributed to extend the concept of multiple sclerosis (MS), classically regarded as a disease limited to the myelin axonal sheath. Several findings, in fact, point to a parallel involvement of neuronal components of the central nervous system (CNS) in the course of MS. In the present study, therefore, we explored, in MS patients, some characteristics of central motor pathways related to changes of neuronal excitability as measured using transcranial magnetic stimulation (TMS).

METHODS

Seventy-nine patients affected by relapsing-remitting (RR) MS were examined using single and paired TMS in order to assess excitability changes in the hand motor cortex occurring during relapse and/or remission of the disease. The analyzed parameters were: motor-evoked potential (MEP) threshold, silent period (SP), intracortical inhibition (ICI) with paired pulses from 1 to 6 ms interstimulus intervals (ISIs), and central motor conduction time (CMCT).

RESULTS

The analysis of variance exhibited a strong correlation (P<0.001) between the clinical phase and the type of excitability changes: 'relapsing' patients showed increased threshold and reduced SP duration. 'Relapsing' patients also displayed a significant lack of normal intracortical inhibition (ICI). By contrast, 'remitting' patients showed a significant SP prolongation with normal motor thresholds.

CONCLUSIONS

The present findings reveal changes in cortical excitability that might play a role in the pathophysiology of MS symptoms. In particular, the relapsing phase of MS has been found to be associated with cortical hyperexcitability irrespective of the site of clinical manifestation or new plaque formation. These results might help to explain the puzzling picture of neurological symptoms observed in MS patients during different phases of the disease.

SIGNIFICANCE

Alterations of neuronal components of the CNS play a role in MS.

Transcranial magnetic stimulation in children

Single and paired pulse transcranial magnetic stimulation (TMS) provide a non-invasive, painless method of probing the motor system. These techniques are of particular interest for studying maturation of the motor system and may provide insights into those developmental disabilities strongly associated with specific delays of motor development. This article will review studies using single pulse and paired pulse TMS in children, with particular reference to insights into neurodevelopment in children. It will also briefly touch on the potential of TMS as a diagnostic tool in neurological disorders. It will not address the use of repetitive TMS in children.

Cortical correlates of neuromotor development in healthy children

OBJECTIVE

To examine the relationship between acquisition of fine motor skills in childhood and development of the motor cortex.

METHODS

We measured finger tapping speed and mirror movements in 43 healthy right-handed subjects (6-26 years of age). While recording surface electromyographic activity from right and left first dorsal interosseus, we delivered focal transcranial magnetic stimulation (TMS) over the hand areas of each motor cortex. We measured motor evoked potential (MEP) threshold, and ipsilateral (iSP) and contralateral (CSP) silent periods.

RESULTS

As children got older, finger speeds got faster, MEP threshold decreased, iSP duration increased and latency decreased. Finger tapping speed got faster as motor thresholds and iSP latency decreased, but was unrelated to CSP duration. In all subjects right hemisphere MEP thresholds were higher than those on the left and duration of right hemisphere CSP was longer than that on the left. Children under 10 years of age had higher left hand mirror movement scores, and fewer left hemisphere iSPs which were of longer duration.

CONCLUSIONS

Maturation of finger tapping skills is closely related to developmental changes in the motor threshold and iSP latency. Studies are warranted to explore the relationship between these measures and other neuromotor skills in children with motor disorders.

SIGNIFICANCE

TMS can provide important insights into certain functional aspects of neurodevelopment in children.