Ankle-Foot-Orthosis "Hermes" compensates pathological ankle stiffness of chronic stroke - A proof of concept

Individuals with an upper motor neuron syndrome, e.g., stroke survivors, may have a pathological increase of passive ankle stiffness due to spasticity, that impairs ankle function and activities such as walking. To improve mobility, walking aids such as ankle-foot orthoses and orthopaedic shoes are...

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Bibliographic Details
Published in:IEEE transactions on neural systems and rehabilitation engineering 2023-01, Vol.31, p.1-1
Main Authors: Rodriguez Hernandez, Karen E., De Groot, Jurriaan H., Baas, Frank, Stijntjes, Marjon, Grootendorst-Heemskerk, Eveline R.M., Schiemanck, Sven K., Van der Helm, Frans C.T., Van der Kooij, Herman, Mugge, Winfred
Format: Article
Language:English
Subjects:
Aids
Ankle
Clinical and Translational Impact Statement—In this early clinical research study
Compensation
Equinus deformity
Feet
Footwear
joint range of motion
Legged locomotion
Manipulators
Motion control
muscle spasticity
Orthopedic apparatus
Orthopedics
Orthoses
orthotic devices
Read only memory
Robot arms
Shoes
Spasticity
Stiffness
Stroke
Torque
Torque measurement
Walking
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Summary:Individuals with an upper motor neuron syndrome, e.g., stroke survivors, may have a pathological increase of passive ankle stiffness due to spasticity, that impairs ankle function and activities such as walking. To improve mobility, walking aids such as ankle-foot orthoses and orthopaedic shoes are prescribed. However, these walking aids generally limit the range of motion (ROM) of the foot and may therewith negatively influence activities that require a larger ROM. Here we present a new ankle-foot orthosis "Hermes", and its first experimental results from four hemiparetic chronic stroke patients. Hermes was designed to facilitate active ankle dorsiflexion by mechanically compensating the passive ankle stiffness using a negative-stiffness mechanism. Four levels of the Hermes' stiffness compensation (0%, 35%, 70% and 100%) were applied to evaluate active ROM in a robotic ankle manipulator and to test walking feasibility on an instrumented treadmill, in a single session. The robotic tests showed that Hermes successfully compensated the ankle joint stiffness in all four patients and improved the active dorsiflexion ROM in three patients. Three patients were able to walk with Hermes at one or more Hermes' stiffness compensation levels and without reducing their preferred walking speeds compared to those with their own walking aids. Despite a small sample size, the results show that Hermes holds great promise to support voluntary ankle function and to benefit walking and daily activities.
ISSN:1534-4320
1558-0210
DOI:10.1109/TNSRE.2023.3310337