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Laubis-Herrmann U, Dichgans J, Bilow H, et al. Motor reorganization after spinal cord injury: evidence of adaptive changes in remote muscles. Restor Neurol Neurosci. 2000;17(4):175-181
Laubis-Herrmann, U., Dichgans, J., Bilow, H., & Topka, H. (2000). Motor reorganization after spinal cord injury: evidence of adaptive changes in remote muscles. Restorative neurology and neuroscience, 17(4), 175-181.
Laubis-Herrmann, U., et al. "Motor reorganization after spinal cord injury: evidence of adaptive changes in remote muscles." Restorative neurology and neuroscience vol. 17,4 (2000): 175-181.
Laubis-Herrmann U, Dichgans J, Bilow H, Topka H. Motor reorganization after spinal cord injury: evidence of adaptive changes in remote muscles. Restor Neurol Neurosci. 2000;17(4):175-181. PMID: 11490089.
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Restor Neurol Neurosci. 2000;17(4):175-181.

Motor reorganization after spinal cord injury: evidence of adaptive changes in remote muscles.

Restorative neurology and neuroscience

U. Laubis-Herrmann, J. Dichgans, H. Bilow, H. Topka

Affiliations

  1. Department of Neurology, University of Tübingen, Tübingen, Germany.

PMID: 11490089

Abstract

Purpose: Given that SCI leads to substantial changes in biomechanical properties of the body and to widespread postlesional reorganization of the motor system as determined by functional imaging studies, we sought to identify neurophysiological correlations and time course of reorganization affecting muscles more distant to a SCI. Methods: Two arm muscles distant to a SCI (T2-L3), M.biceps brachii (BIC), M.abductor pollicis brevis (APB), were studied in 13 SCI-patients and 15 controls. Motor thresholds at rest (MT), facilitatory effects on MEP-amplitudes (FE) with voluntary activation, MEP-amplitudes with maximal stimulation (MA) and recruitment curves (RC) were measured and correlated with level, age and severity of the lesion. Follow-up studies (t2) were performed in five patients with clinical recovery. Results: Patients exhibited smaller MA from activated BIC, a tendency towards smaller FE and smaller RC-slopes at t1. With clinical recovery, activated BIC-FE, MA and RC-slopes tended to normalize. Conclusions: Our data support the hypothesis that postlesional reorganization of the motor system also involves remote muscles. Considering pattern and time course of reorganization, we speculate that they appear as sequelae of the trauma, possibly representing an adaptation of the motor system to an altered biomechanical status after SCI.

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