Training balance recovery in people with incomplete SCI wearing a wearable exoskeleton

E. H.F. van Asseldonk; A. Emmens; T. J.H. Brug; I. Pisotta; M. Arquilla; F. Tamburella; M. Masciullo; N. L. Tagliamonte; R. Valette; M. Molinari; H. van der Kooij

doi:10.1007/978-3-030-01887-0_64

Training balance recovery in people with incomplete SCI wearing a wearable exoskeleton

E. H.F. van Asseldonk^*, A. Emmens, T. J.H. Brug, I. Pisotta, M. Arquilla, F. Tamburella, M. Masciullo, N. L. Tagliamonte, R. Valette, M. Molinari, H. van der Kooij

^*Corresponding author for this work

Research output: Contribution to book/anthology/report/conference proceeding › Book chapter › Research › peer-review

2 Citations (Scopus)

Abstract

Improving stability of people wearing a lower extremity Wearable Exoskeleton (WE) is one of the biggest challenges in the field. The goal of this preliminary study was to improve balance recovery from perturbations in people with incomplete Spinal Cord Injury (SCI) assisted by a WE with specifically developed balance controller. The WE has actuated ankle and knee joints, which were controlled by using a body sway-based balance controller. Two test pilots participated in 5 training sessions, devoted to enhance the use of the robot, and in pre/post assessments. Their balance during quiet standing was perturbed through pushes in forward direction. The controller was effective in supporting balance recovery in both tests pilots as reflected by a smaller sway amplitude and recovery time when compared with a minimal impedance controller. Moreover, the training resulted in a further reduction of the sway amplitude and recovery time in one of the test pilots whereas it had not an additional beneficial effect for the other subject. In conclusion, the novel balance controller can effectively assist people with incomplete SCI in maintaining standing balance and a dedicated training has the potential to further improve balance.

Original language	English
Title of host publication	Biosystems and Biorobotics
Number of pages	5
Publisher	Springer Publishing Company
Publication date	2019
Pages	334-338
DOIs	https://doi.org/10.1007/978-3-030-01887-0_64
Publication status	Published - 2019
Externally published	Yes

Series	Biosystems and Biorobotics
Volume	22
ISSN	2195-3562

Bibliographical note

Funding Information:
SYMBITRON is supported by EU research program FP7-ICT-2013-10 (contract #611626). SYMBITRON is coordinated by University of Twente.

Funding Information:
Acknowledgment. SYMBITRON is supported by EU research program FP7-ICT-2013-10 (contract #611626). SYMBITRON is coordinated by University of Twente.

Publisher Copyright:
© Springer Nature Switzerland AG 2019.

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van Asseldonk, E. H. F., Emmens, A., Brug, T. J. H., Pisotta, I., Arquilla, M., Tamburella, F., Masciullo, M., Tagliamonte, N. L., Valette, R., Molinari, M., & van der Kooij, H. (2019). Training balance recovery in people with incomplete SCI wearing a wearable exoskeleton. In Biosystems and Biorobotics (pp. 334-338). Springer Publishing Company. https://doi.org/10.1007/978-3-030-01887-0_64

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title = "Training balance recovery in people with incomplete SCI wearing a wearable exoskeleton",

abstract = "Improving stability of people wearing a lower extremity Wearable Exoskeleton (WE) is one of the biggest challenges in the field. The goal of this preliminary study was to improve balance recovery from perturbations in people with incomplete Spinal Cord Injury (SCI) assisted by a WE with specifically developed balance controller. The WE has actuated ankle and knee joints, which were controlled by using a body sway-based balance controller. Two test pilots participated in 5 training sessions, devoted to enhance the use of the robot, and in pre/post assessments. Their balance during quiet standing was perturbed through pushes in forward direction. The controller was effective in supporting balance recovery in both tests pilots as reflected by a smaller sway amplitude and recovery time when compared with a minimal impedance controller. Moreover, the training resulted in a further reduction of the sway amplitude and recovery time in one of the test pilots whereas it had not an additional beneficial effect for the other subject. In conclusion, the novel balance controller can effectively assist people with incomplete SCI in maintaining standing balance and a dedicated training has the potential to further improve balance.",

author = "{van Asseldonk}, {E. H.F.} and A. Emmens and Brug, {T. J.H.} and I. Pisotta and M. Arquilla and F. Tamburella and M. Masciullo and Tagliamonte, {N. L.} and R. Valette and M. Molinari and {van der Kooij}, H.",

note = "Funding Information: SYMBITRON is supported by EU research program FP7-ICT-2013-10 (contract #611626). SYMBITRON is coordinated by University of Twente. Funding Information: Acknowledgment. SYMBITRON is supported by EU research program FP7-ICT-2013-10 (contract #611626). SYMBITRON is coordinated by University of Twente. Publisher Copyright: {\textcopyright} Springer Nature Switzerland AG 2019.",

year = "2019",

doi = "10.1007/978-3-030-01887-0_64",

language = "English",

series = "Biosystems and Biorobotics",

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van Asseldonk, EHF, Emmens, A, Brug, TJH, Pisotta, I, Arquilla, M, Tamburella, F, Masciullo, M, Tagliamonte, NL, Valette, R, Molinari, M & van der Kooij, H 2019, Training balance recovery in people with incomplete SCI wearing a wearable exoskeleton. in Biosystems and Biorobotics. Springer Publishing Company, Biosystems and Biorobotics, vol. 22, pp. 334-338. https://doi.org/10.1007/978-3-030-01887-0_64

Training balance recovery in people with incomplete SCI wearing a wearable exoskeleton. / van Asseldonk, E. H.F.; Emmens, A.; Brug, T. J.H. et al.
Biosystems and Biorobotics. Springer Publishing Company, 2019. p. 334-338 (Biosystems and Biorobotics, Vol. 22).

Research output: Contribution to book/anthology/report/conference proceeding › Book chapter › Research › peer-review

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T1 - Training balance recovery in people with incomplete SCI wearing a wearable exoskeleton

AU - van Asseldonk, E. H.F.

AU - Emmens, A.

AU - Brug, T. J.H.

AU - Pisotta, I.

AU - Arquilla, M.

AU - Tamburella, F.

AU - Masciullo, M.

AU - Tagliamonte, N. L.

AU - Valette, R.

AU - Molinari, M.

AU - van der Kooij, H.

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PY - 2019

Y1 - 2019

N2 - Improving stability of people wearing a lower extremity Wearable Exoskeleton (WE) is one of the biggest challenges in the field. The goal of this preliminary study was to improve balance recovery from perturbations in people with incomplete Spinal Cord Injury (SCI) assisted by a WE with specifically developed balance controller. The WE has actuated ankle and knee joints, which were controlled by using a body sway-based balance controller. Two test pilots participated in 5 training sessions, devoted to enhance the use of the robot, and in pre/post assessments. Their balance during quiet standing was perturbed through pushes in forward direction. The controller was effective in supporting balance recovery in both tests pilots as reflected by a smaller sway amplitude and recovery time when compared with a minimal impedance controller. Moreover, the training resulted in a further reduction of the sway amplitude and recovery time in one of the test pilots whereas it had not an additional beneficial effect for the other subject. In conclusion, the novel balance controller can effectively assist people with incomplete SCI in maintaining standing balance and a dedicated training has the potential to further improve balance.

AB - Improving stability of people wearing a lower extremity Wearable Exoskeleton (WE) is one of the biggest challenges in the field. The goal of this preliminary study was to improve balance recovery from perturbations in people with incomplete Spinal Cord Injury (SCI) assisted by a WE with specifically developed balance controller. The WE has actuated ankle and knee joints, which were controlled by using a body sway-based balance controller. Two test pilots participated in 5 training sessions, devoted to enhance the use of the robot, and in pre/post assessments. Their balance during quiet standing was perturbed through pushes in forward direction. The controller was effective in supporting balance recovery in both tests pilots as reflected by a smaller sway amplitude and recovery time when compared with a minimal impedance controller. Moreover, the training resulted in a further reduction of the sway amplitude and recovery time in one of the test pilots whereas it had not an additional beneficial effect for the other subject. In conclusion, the novel balance controller can effectively assist people with incomplete SCI in maintaining standing balance and a dedicated training has the potential to further improve balance.

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AN - SCOPUS:85055054614

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SP - 334

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BT - Biosystems and Biorobotics

PB - Springer Publishing Company

ER -

Training balance recovery in people with incomplete SCI wearing a wearable exoskeleton

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