TY - JOUR
T1 - Predicting Gait Patterns of Children With Spasticity by Simulating Hyperreflexia
AU - Veerkamp, Kirsten
AU - Carty, Christopher P.
AU - Waterval, Niels F. J.
AU - Geijtenbeek, Thomas
AU - Buizer, Annemieke I.
AU - Lloyd, David G.
AU - Harlaar, Jaap
AU - van der Krogt, Marjolein M.
N1 - Publisher Copyright: © 2023 Human Kinetics, Inc.
PY - 2023/10/1
Y1 - 2023/10/1
N2 - Spasticity is a common impairment within pediatric neuromusculoskeletal disorders. How spasticity contributes to gait deviations is important for treatment selection. Our aim was to evaluate the pathophysiological mechanisms underlying gait deviations seen in children with spasticity, using predictive simulations. A cluster analysis was performed to extract distinct gait patterns from experimental gait data of 17 children with spasticity to be used as comparative validation data. A forward dynamic simulation framework was employed to predict gait with either velocity- or force-based hyperreflexia. This framework entailed a generic musculoskeletal model controlled by reflexes and supraspinal drive, governed by a multiobjective cost function. Hyperreflexia values were optimized to enable the simulated gait to best match experimental gait patterns. Three experimental gait patterns were extracted: (1) increased knee flexion, (2) increased ankle plantar flexion, and (3) increased knee flexion and ankle plantar flexion when compared with typical gait. Overall, velocity-based hyperreflexia outperformed force-based hyperreflexia. The first gait pattern could mostly be explained by rectus femoris and hamstrings velocity-based hyperreflexia, the second by gastrocnemius velocity-based hyperreflexia, and the third by gastrocnemius, soleus, and hamstrings velocity-based hyperreflexia. This study shows how velocity-based hyperreflexia from specific muscles contributes to different spastic gait patterns, which may help in providing targeted treatment.
AB - Spasticity is a common impairment within pediatric neuromusculoskeletal disorders. How spasticity contributes to gait deviations is important for treatment selection. Our aim was to evaluate the pathophysiological mechanisms underlying gait deviations seen in children with spasticity, using predictive simulations. A cluster analysis was performed to extract distinct gait patterns from experimental gait data of 17 children with spasticity to be used as comparative validation data. A forward dynamic simulation framework was employed to predict gait with either velocity- or force-based hyperreflexia. This framework entailed a generic musculoskeletal model controlled by reflexes and supraspinal drive, governed by a multiobjective cost function. Hyperreflexia values were optimized to enable the simulated gait to best match experimental gait patterns. Three experimental gait patterns were extracted: (1) increased knee flexion, (2) increased ankle plantar flexion, and (3) increased knee flexion and ankle plantar flexion when compared with typical gait. Overall, velocity-based hyperreflexia outperformed force-based hyperreflexia. The first gait pattern could mostly be explained by rectus femoris and hamstrings velocity-based hyperreflexia, the second by gastrocnemius velocity-based hyperreflexia, and the third by gastrocnemius, soleus, and hamstrings velocity-based hyperreflexia. This study shows how velocity-based hyperreflexia from specific muscles contributes to different spastic gait patterns, which may help in providing targeted treatment.
KW - cerebral palsy
KW - forward dynamics
KW - neuromusculoskeletal modeling
KW - predictive simulations
KW - spastic diplegia
UR - http://www.scopus.com/inward/record.url?scp=85174391062&partnerID=8YFLogxK
U2 - https://doi.org/10.1123/jab.2023-0022
DO - https://doi.org/10.1123/jab.2023-0022
M3 - Article
C2 - 37532263
SN - 1065-8483
VL - 39
SP - 333
EP - 346
JO - Journal of applied biomechanics
JF - Journal of applied biomechanics
IS - 5
ER -