John C. Rothwell scite author profile

1. EMG responses evoked in hand muscles by transcranial stimulation over the motor cortex were conditioned by a single motor threshold electrical stimulus to the median nerve at the wrist in a total of ten healthy subjects and in five patients who had electrodes implanted chronically into the cervical epidural space. 2. The median nerve stimulus suppressed responses evoked by transcranial magnetic stimulation (TMS) in relaxed or active muscle. The minimum interval between the stimuli at which this occurred was 19 ms. A similar effect was seen if electrical stimulation was applied to the digital nerves of the first two fingers. 3. Median or digital nerve stimulation could suppress the responses evoked in active muscle by transcranial electrical stimulation over the motor cortex, but the effect was much less than with magnetic stimulation. 4. During contraction without TMS, both types of conditioning stimuli evoked a cutaneomuscular reflex that began with a short period of inhibition. This started about 5 ms after the inhibition of responses evoked by TMS. 5. Recordings in the patients showed that median nerve stimulation reduced the size and number of descending corticospinal volleys evoked by magnetic stimulation. 6. We conclude that mixed or cutaneous input from the hand can suppress the excitability of the motor cortex at short latency. This suppression may contribute to the initial inhibition of the cutaneomuscular reflex. Reduced spinal excitability in this period could account for the mild inhibition of responses to electrical brain stimulation.

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Pathophysiology of bradykinesia in Parkinson's disease

Berardelli¹,

Rothwell²,

Thompson

et al. 2001

748

548

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Bradykinesia means slowness of movement and is one of the cardinal manifestations of Parkinson's disease. Weakness, tremor and rigidity may contribute to but do not fully explain bradykinesia. We argue that bradykinesia results from a failure of basal ganglia output to reinforce the cortical mechanisms that prepare and execute the commands to move. The cortical deficit is most apparent in midline motor areas. This leads to particular difficulty with self-paced movements, prolonged reaction times and abnormal pre-movement EEG activity. Movements are often performed with normally timed EMG bursts but the amount of EMG activity is underscaled relative to the desired movement parameters. There are also abnormalities in sensory scaling and sensorimotor integration. The brain appears to be able to compensate to some degree for the basal ganglia deficit. There is overactivity in the lateral premotor areas during task performance and movements can be speeded by giving sensory cues. Attention to movement is also beneficial. However, we propose that the engagement of compensatory processes may also lead to reduced performance in other tasks. For example, patients' problems in performing more than one task at the same time could result from lack of sufficient resources both to compensate for their basal ganglia deficit and to run two tasks simultaneously. Surgical therapies are unlikely to work solely by normalizing basal ganglia output to that seen in healthy individuals. It seems more plausible that surgery removes an interfering signal that allows more efficient compensation by other structures.

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Electric and magnetic stimulation of human motor cortex: surface EMG and single motor unit responses.

Day

Dressler

Noordhout

et al. 1989

The Journal of Physiology

854

507

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SUMMARY1. The effects of different forms of brain stimulation on the discharge pattern of single motor units were examined using the post-stimulus time histogram (PSTH) technique and by recording the compound surface clectromyographic (EMG) responses in the first dorsal interosseous (FDI) muscle. Electrical and magnetic methods were used to stimulate the brain through the intact scalp of seven normal subjects. Electrical stimuli were applied either with the anode over the lateral central scalp and the cathode at the vertex (anodal stimulation) or with the anode at the vertex and the cathode lateral (cathodal stimnulation). Magnetic stiinulation used a 9 cm diameter coil centred at the vertex; current in the coil flowed either clockwise or anticlockwise when viewed from above.2. Supramotor threshold stimuli produced one or more narrow (< 2 ms) peaks of increased firing in the PSTH of all thirty-two units studied. Anodal stimulation always produced an early peak. The latencies of the peaks produced by other forms of stimulation, or by high intensities of anodal stimulation, were grouped into four time bands relative to this early peak, at intervals of -0 5 to 0U5, 1-2, 2-5-3-5 and 4-5-5 ms later. Peaks occurring within these intervals are referred to as P0 (the earliest an6dal), P1, P2 and P3 respectively.3. At threshold, anodal stimulation evoked only the P0 peak; at higher intensities, the P2 or more commonly the P3 peak also was recruited. The size of the P0 peak appeared to saturate at high intensities.4. In five of six subjects, cathodal stimulation behaved like anodal stimulation, except that there was a lower threshold for recruitment of the P2 or P3 peak relative to that of the P0 peak. In the other subject, the P3 peak was recruited before the PO peak.5. Clockwise magnetic stimulation, at threshold, often produced several peaks. These always included a PI peak, and usually a P3 peak. A P0 peak in the PSTH was never produced by a clockwise stimulation at intensities which we could explore with the technique.6. Anticlockwise magnetic stimulation never recruited a P1 peak; in most subjects a P3 peak was recruited first and at higher intensities was accompanied by P0 or P2 peaks. 15PHY 412 B. L. DA ' AND) OTHERS 7. On most occasions when more than one peak was observed in a PSTH, the uniit fired in only one of the preferred intervals after each shock. However, double firing was seen in five units when high intensities of stimulation were used. The intervals between the two discharges was the same as the intervals between peaks in the PSTH.8. Surface EMG responses in the FDI muscle behaved in a way predietable from the behaviour of the single motor units which had been studied.9. These results are discussed in terms of the D and I wave hypothesis proposed for responses of pyramidal tract neurones to surface anodal stimulation of the exposed motor cortex in primates.

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John C. Rothwell

Theta burst stimulation on human motor cortex

Short latency inhibition of human hand motor cortex by somatosensory input from the hand

Pathophysiology of bradykinesia in Parkinson's disease

Electric and magnetic stimulation of human motor cortex: surface EMG and single motor unit responses.

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