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* To whom correspondence should be addressed. E-mail: nori{at}rehab.go.jp.
It is now well recognized that muscle activity can be induced even in the paralyzed lower limb muscles of persons with spinal cord injury (SCI) by imposing locomotion-like movements on both of their legs. Although the significant role of the afferent input related to hip joint movement and body load has been emphasized considerably in previous studies, the contribution of the "alternate" leg movement pattern has not been fully investigated. The present study was designed to investigate to what extent the alternate leg movement influenced this "locomotor-like" muscle activity. The knee-locked leg swing movement was imposed on ten complete SCI subjects using a gait training apparatus. The following three different experimental conditions were adopted: (i) bilateral alternate leg movement, (ii) unilateral leg movement, and (iii) bilateral synchronous (in-phase) leg movement. In all experimental conditions, the passive leg movement induced electromyographic (EMG) activity in the soleus and medial head of the gastrocnemius muscles in all SCI subjects and in the biceps femoris muscle in eight of ten SCI subjects. On the other hand, the EMG activity was not observed in the tibialis anterior and rectus femoris muscles. The EMG level of these activated muscles, as quantified by integrating the rectified EMG activity recorded from the right leg, was significantly larger for bilateral alternate leg movement than for unilateral and bilateral synchronous movements, although the right hip and ankle joint movements were identical in all experimental conditions. In addition, the difference in the pattern of the load applied to the leg among conditions was unable to explain the enhancement of EMG activity in the bilateral alternate leg movement condition. These results suggest that the sensory information generated by alternate leg movements plays a substantial role in amplifying the induced locomotor-like muscle activity in the lower limbs.
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