Reeducação da Marcha na Lesão Medular, a Propósito de Dois Sistemas Robóticos: o Lokomat® e o EKSO GT®

Gonçalo Pires; Jorge Fortunato; Isabel Amorim; Filipa Faria

doi:10.25759/spmfr.273

Authors

Gonçalo Pires Serviço de MFR do Centro de Medicina de Reabilitação do Alcoitão
Jorge Fortunato Serviço de MFR do Centro de Medicina de Reabilitação do Alcoitão
Isabel Amorim Serviço de MFR do Centro de Medicina de Reabilitação do Alcoitão
Filipa Faria Serviço de MFR do Centro de Medicina de Reabilitação do Alcoitão

DOI:

https://doi.org/10.25759/spmfr.273

Keywords:

Gait, Spinal Cord Injuries/rehabilitation, Robotics

Abstract

One of the main goals of rehabilitation following spinal cord injury is gait training. This approach may be associated with the reconfiguration of the spinal and interneuron reflexes, enhancing the neuroplasticity that leads to the recovery of gait capacity. The afferent input related to load and hip-joint position are crucial in generating a gait pattern and consequently in gait training. The recent introduction of robotic devices for the recovery of walking function in patients with incomplete spinal cord injury, improves the consistency of training and increase the intensity of therapy in a safe environment. Functional outcome is assessed by appropriate spinal cord injury scales and tests. The use of robotic devices implies a vast knowledge of the indications, benefits, limitations and safety measures required for each device and each patient. There are several types of robotic systems currently available for use in gait rehabilitation. However, the authors intend to describe the main advantages and limitations of two robotic systems, Lokomat® and EKSO GT®, as well as to perform a brief review of the neurophysiology and evaluation of prognostic factors of walking recovery after spinal cord injury.

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Gait Training in Spinal Cord Injury, Regarding Two Robotic Devices: Lokomat® and EKSO GT®

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