Functional impacts of exoskeleton-based rehabilitation in chronic stroke: multi-joint versus single-joint robotic training

Will your therapist change your stroke protocols based on this? If you are lucky enough to have a robotic exoskeleton.
http://www.jneuroengrehab.com/content/10/1/113/abstract

Giuliana Grimaldi¹ and Mario Manto^12*

• * Corresponding author: Mario Manto mmanto@ulb.ac.be

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Journal of NeuroEngineering and Rehabilitation 2013, 10:113  doi:10.1186/1743-0003-10-113
Published: 19 December 2013

Abstract

Stroke is a major cause of disability in the world. The activities of upper limb segments are often compromised following a stroke, impairing most daily tasks. Robotic training is now considered amongst the rehabilitation methods applied to promote functional recovery. However, the implementation of robotic devices remains a major challenge for the bioengineering and clinical community. Latest exoskeletons with multiple degrees of freedom (DOF) may become particularly attractive, because of their low apparent inertia, the multiple actuators generating large torques, and the fact that patients can move the arm in the normal wide workspace. A recent study published in JNER by Milot and colleagues underlines that training with a 6-DOF exoskeleton impacts positively on motor function in patients being in stable phase of recovery after a stroke. Also, multi-joint robotic training was not found to be superior to single-joint robotic training. Although it is often considered that rehabilitation should start from simple movements to complex functional movements as the recovery evolves, this study challenges this widespread notion whose scientific basis has remained uncertain.