Feasibility of a real-time pattern-based kinematic feedback system for gait retraining in pediatric cerebral palsy
Introduction Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that uses wearable inertial measurement units to provide kinematic feedback on error measures generated during periods of gait in which the knee i...
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| Published in | Journal of rehabilitation and assistive technologies engineering Vol. 8; p. 20556683211014125 |
|---|---|
| Main Authors | , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
London, England
SAGE Publications
01.01.2021
Sage Publications Ltd |
| Subjects | |
| Online Access | Get full text |
| ISSN | 2055-6683 2055-6683 |
| DOI | 10.1177/20556683211014125 |
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| Abstract | Introduction
Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that uses wearable inertial measurement units to provide kinematic feedback on error measures generated during periods of gait in which the knee is predominantly extended (‘extension period’) and flexed (‘flexion period’).
Methods
We describe the principles of operation of the system, a validation study on the inertial measurement unit derived knee flexion angle on which the system is based, and a feasibility study to assess the ability of a child with cerebral palsy to modify a gait deviation (decreased swing phase knee flexion) in response to the feedback.
Results
The validation study demonstrated strong convergent validity with an independent measurement of knee flexion angle. The gait pattern observed during training with the system exhibited increased flexion in the flexion period with maintenance of appropriate extension in the extension period.
Conclusions
Inertial measurement units can provide robust feedback during gait training. A child with cerebral palsy was able to interpret the novel two phase visual feedback and respond with rapid gait adaptation in a single training session. With further development, the system has the potential to support clinical retraining of deviated gait patterns. |
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| AbstractList | Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that uses wearable inertial measurement units to provide kinematic feedback on error measures generated during periods of gait in which the knee is predominantly extended ('extension period') and flexed ('flexion period').INTRODUCTIONVisual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that uses wearable inertial measurement units to provide kinematic feedback on error measures generated during periods of gait in which the knee is predominantly extended ('extension period') and flexed ('flexion period').We describe the principles of operation of the system, a validation study on the inertial measurement unit derived knee flexion angle on which the system is based, and a feasibility study to assess the ability of a child with cerebral palsy to modify a gait deviation (decreased swing phase knee flexion) in response to the feedback.METHODSWe describe the principles of operation of the system, a validation study on the inertial measurement unit derived knee flexion angle on which the system is based, and a feasibility study to assess the ability of a child with cerebral palsy to modify a gait deviation (decreased swing phase knee flexion) in response to the feedback.The validation study demonstrated strong convergent validity with an independent measurement of knee flexion angle. The gait pattern observed during training with the system exhibited increased flexion in the flexion period with maintenance of appropriate extension in the extension period.RESULTSThe validation study demonstrated strong convergent validity with an independent measurement of knee flexion angle. The gait pattern observed during training with the system exhibited increased flexion in the flexion period with maintenance of appropriate extension in the extension period.Inertial measurement units can provide robust feedback during gait training. A child with cerebral palsy was able to interpret the novel two phase visual feedback and respond with rapid gait adaptation in a single training session. With further development, the system has the potential to support clinical retraining of deviated gait patterns.CONCLUSIONSInertial measurement units can provide robust feedback during gait training. A child with cerebral palsy was able to interpret the novel two phase visual feedback and respond with rapid gait adaptation in a single training session. With further development, the system has the potential to support clinical retraining of deviated gait patterns. Introduction Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that uses wearable inertial measurement units to provide kinematic feedback on error measures generated during periods of gait in which the knee is predominantly extended (‘extension period’) and flexed (‘flexion period’). Methods We describe the principles of operation of the system, a validation study on the inertial measurement unit derived knee flexion angle on which the system is based, and a feasibility study to assess the ability of a child with cerebral palsy to modify a gait deviation (decreased swing phase knee flexion) in response to the feedback. Results The validation study demonstrated strong convergent validity with an independent measurement of knee flexion angle. The gait pattern observed during training with the system exhibited increased flexion in the flexion period with maintenance of appropriate extension in the extension period. Conclusions Inertial measurement units can provide robust feedback during gait training. A child with cerebral palsy was able to interpret the novel two phase visual feedback and respond with rapid gait adaptation in a single training session. With further development, the system has the potential to support clinical retraining of deviated gait patterns. Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that uses wearable inertial measurement units to provide kinematic feedback on error measures generated during periods of gait in which the knee is predominantly extended ('extension period') and flexed ('flexion period'). We describe the principles of operation of the system, a validation study on the inertial measurement unit derived knee flexion angle on which the system is based, and a feasibility study to assess the ability of a child with cerebral palsy to modify a gait deviation (decreased swing phase knee flexion) in response to the feedback. The validation study demonstrated strong convergent validity with an independent measurement of knee flexion angle. The gait pattern observed during training with the system exhibited increased flexion in the flexion period with maintenance of appropriate extension in the extension period. Inertial measurement units can provide robust feedback during gait training. A child with cerebral palsy was able to interpret the novel two phase visual feedback and respond with rapid gait adaptation in a single training session. With further development, the system has the potential to support clinical retraining of deviated gait patterns. Introduction Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that uses wearable inertial measurement units to provide kinematic feedback on error measures generated during periods of gait in which the knee is predominantly extended (‘extension period’) and flexed (‘flexion period’). Methods We describe the principles of operation of the system, a validation study on the inertial measurement unit derived knee flexion angle on which the system is based, and a feasibility study to assess the ability of a child with cerebral palsy to modify a gait deviation (decreased swing phase knee flexion) in response to the feedback. Results The validation study demonstrated strong convergent validity with an independent measurement of knee flexion angle. The gait pattern observed during training with the system exhibited increased flexion in the flexion period with maintenance of appropriate extension in the extension period. Conclusions Inertial measurement units can provide robust feedback during gait training. A child with cerebral palsy was able to interpret the novel two phase visual feedback and respond with rapid gait adaptation in a single training session. With further development, the system has the potential to support clinical retraining of deviated gait patterns. |
| Author | Liu, Xuan Bentley, Katherine Shoval, Hannah Oliveira, Nuno Blochlinger, Sheila Cheng, JenFu Ehrenberg, Naphtaly Barrance, Peter |
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| Cites_doi | 10.1097/PEP.0000000000000362 10.1186/s12984-018-0389-4 10.1016/j.gaitpost.2019.06.016 10.1016/j.parkreldis.2015.11.004 10.3758/s13423-012-0333-8 10.1016/j.clinbiomech.2018.09.020 10.1109/TASSP.1978.1163055 10.1111/j.1469-8749.2008.03089.x 10.1016/j.gaitpost.2016.11.021 10.1016/j.neuropsychologia.2015.04.020 10.1111/dmcn.12246 10.1016/j.gaitpost.2010.08.009 |
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| Keywords | biofeedback cerebral palsy knee Gait retraining real-time feedback |
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| References | Schliessmann, Nisser, Schuld 2018; 15 Ginis, Nieuwboer, Dorfman 2016; 22 Booth, Buizer, Harlaar 2018; 100 Byl, Zhang, Coo 2015; 79 Sakoe, Chiba 1978; 26 Palisano, Rosenbaum, Bartlett 2008; 50 Schliessmann, Schuld, Schneiders 2014; 8 Bovi, Rabuffetti, Mazzoleni 2011; 33 Novak, McIntyre, Morgan 2013; 55 Sigrist, Rauter, Riener 2013; 20 Levin, Lewek, Feasel 2017; 29 van Gelder, Barnes, Wheat 2018; 59 Oliveira, Ehrenberg, Cheng 2019; 74 van Gelder, Booth, van de Port 2017; 52 bibr12-20556683211014125 bibr3-20556683211014125 Booth AT (bibr8-20556683211014125) 2018; 100 bibr6-20556683211014125 bibr9-20556683211014125 bibr16-20556683211014125 bibr2-20556683211014125 bibr13-20556683211014125 Accardo PJ (bibr1-20556683211014125) 2008 bibr15-20556683211014125 bibr10-20556683211014125 bibr7-20556683211014125 Schliessmann D (bibr5-20556683211014125) 2014; 8 bibr11-20556683211014125 bibr14-20556683211014125 bibr4-20556683211014125 |
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| Snippet | Introduction
Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that... Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that uses wearable... Introduction Visual biofeedback of lower extremity kinematics has the potential to enhance retraining of pathological gait patterns. We describe a system that... |
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| SubjectTerms | Cerebral palsy Feasibility studies Kinematics Original Pediatrics Validation studies |
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| Title | Feasibility of a real-time pattern-based kinematic feedback system for gait retraining in pediatric cerebral palsy |
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