Noriyuki Kamata

Task dependency of the long-latency facilitatory effect on the soleus H-reflex by cerebellar transcranial magnetic stimulation.

We investigated whether cerebellar transcranial magnetic stimulation (C-TMS) facilitates the excitability of the ipsilateral soleus motoneuron pool in resting humans, and whether the facilitation is modulated by a task that promotes cerebellar activity. A test tibial nerve stimulus evoking the H-reflex from the right soleus muscle was delivered before or after conditioning C-TMS in prone individuals. The amplitude of the H-reflex was significantly increased at conditioning-test interstimulus intervals of 110, 120, and 130 ms. Furthermore, we revealed that this facilitation effect was inhibited while the individuals tapped their right index finger. These findings indicate that C-TMS facilitates spinal motoneuronal excitability with an ∼100 ms latency in resting humans, and that this cerebellar spinal facilitation is modulated by a task that might increase cerebellar activity. Cerebellar spinal facilitation could thus be useful for assessing the excitability of the cerebellum, or the cerebellar output to spinal motoneurons.

The effect of eye movement on the control of arm movement to a target.

Abstract The purpose of this study was to investigate the effect of eye movement on the control of arm movement to a target. Healthy humans flexed the elbow to a stationary target in response to a start tone. Simultaneously, the subject moved the eyes to the target (saccade eye movement), visually tracked a laser point moving with the arm (smooth pursuit eye movement), or gazed at a stationary start point at the midline of the horizontal visual angle (non-eye movement—NEM). Arm movement onset was delayed when saccade eye movement accompanied it. The onset of an electromyographic burst in the biceps muscle and the onset of saccade eye movement were almost simultaneous when both the arm and the eyes moved to the target. Arm movement duration during smooth pursuit eye movement was significantly longer than that during saccade eye movement or NEM. In spite of these findings, amplitudes of motor-evoked potential in the biceps and triceps brachii muscles were not significantly different among the eye movement conditions. These findings indicate that eye movement certainly affects the temporal control of arm movement, but may not affect corticospinal excitability in the arm muscles during arm movement.

PREMOVEMENT FACILITATION OF CORTICOSPINAL EXCITABILITY BEFORE SIMPLE AND SEQUENTIAL MOVEMENT

The purpose of this study was to investigate whether premovement facilitation of corticospinal excitability before sequential movement was different from that before simple movement. Each of 7 participants who performed choice reaction tasks with the right hand pressed a force transducer with the index finger in response to a start cue or pressed the transducers sequentially with the index finger, little finger, thumb, little finger, and index finger. Transcranial magnetic stimulation was delivered to the left motor cortex before the electromyographic burst in the first dorsal interosseous muscle and motor evoked potentials were recorded from the first dorsal interosseous muscle. The amplitude of the motor-evoked potential increased as its onset got closer to the onset of the electromyographic burst. The increase before the sequential movement was larger and began earlier than that before the simple movement. These findings indicate that premovement facilitation of corticospinal excitability is different in magnitude and timing between sequential and simple movements.

Effect of cerebellar transcranial magnetic stimulation on soleus Ia presynaptic and reciprocal inhibition.

Previously, we reported that cerebellar transcranial magnetic stimulation (C-TMS) facilitates spinal motoneuronal excitability in resting humans. In this study, we aimed to characterize the descending pathway that is responsible for the C-TMS-associated cerebellar spinal facilitation. We evaluated the effect of C-TMS on ipsilateral soleus Ia presynaptic inhibition (PSI) and reciprocal inhibition (RI) because the vestibulospinal and reticulospinal tracts project from the cerebellum to mediate spinal motoneurons via interneurons associated with PSI. PSI and RI were measured with a soleus H-reflex test following operant conditioning using electrical stimulation of the common peroneal nerve. C-TMS was delivered before test tibial nerve stimulation with conditioning-test interstimulus intervals of 110 ms. C-TMS did not generate motor-evoked potentials, and it did not increase electromyography activity in the ipsilateral soleus muscle, indicating that C-TMS does not directly activate the corticospinal tract and motoneurons. However, C-TMS facilitated the ipsilateral soleus H-reflex and reduced the amount of soleus Ia PSI, but not RI. These findings indicate that C-TMS may facilitate the excitability of the spinal motoneuron pool via the vestibulospinal or reticulospinal tracts associated with PSI. Cerebellar spinal facilitation may be useful for assessing the functional connectivity of the cerebellum and vestibular nuclei or reticular formation.

The effect of advance information about the sequence of a to-be-signaled motor response on corticospinal excitability during the foreperiod.

We investigated the effect of advance information about the sequence of a to-be-signaled motor response on corticospinal excitability during the foreperiod in healthy humans. Advance information about the sequence of a to-be-signaled motor response was provided by a precue signal 600 ms before a response signal during a warned choice reaction task. The precue signal indicated the sequence of one of three to-be-signaled motor responses: simple, repetitive, or sequential motor responses. The amplitude of the motor-evoked potential (MEP) decreased significantly 100 ms before the response signal in both the first dorsal interosseous (FDI) and abductor pollicis brevis (APB) muscles, but a significant decrease was present only in the APB muscle 300 ms before the response signal. The decrease in the MEP amplitude 100 ms before the response signal induced by the precue signal indicating the repetitive motor response was significantly smaller than that induced by the precue signal indicating the simple or sequential motor response in the FDI muscle, and was significantly smaller than that induced by the precue signal indicating the sequential motor response in the APB muscle. The decrease in corticospinal excitability in the middle foreperiod is larger when the advance information about a to-be-signaled motor response is unrelated to the muscle tested, and the decrease in the late foreperiod is affected by advance information about the sequence of a to-be-signaled motor response.

P694: Task dependency of long latency facilitatory effect on soleus H-reflex by cerebellar transcranial magnetic stimulation

A. Matsugi1, S. Uehara2,3, N. Kamata4, N. Mori5, K. Oku6, K. Mukai1, K. Nagano1 1Shijonawate gakuen university, Faculty of Rehabilitation, Osaka, Japan; 2Center for Information and Neural Networks (CiNet), National Institute of Information and Communications Technology, Osaka, Japan; 3Japan Society for the Promotion of Science, Osaka, Japan; 4Osaka University Hospital, Rehabilitation Unit, Osaka, Japan; 5Yamamoto Hospital, Rehabilitation, Wakayama, Japan; 6Hannachuo Hospital, Rehabilitation, Nara, Japan