TY - GEN
T1 - Validating Predictive Simulation-Derived Electrical Stimulation Cycling in a Person with Spinal Cord Injury
AU - Peres, Alexandre B.
AU - Carmona, Gabriel G.
AU - Gonçalves, Carlos
AU - De Sousa, Ana Carolina C.
AU - Baptista, Roberto De S.
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - Functional electrical stimulation (FES) is commonly used in rehabilitation for its ability to activate muscle groups and functionally apply them. One of the most popular applications of FES is cycling for its safety and proven increase in users' health and quality of life. However, some challenges are intrinsic to the cycling application, among them, finding the best parameters of electrical stimulation to optimize the benefits for each user. While studies have focused on determining the optimal timing for stimulation with a bang-bang control strategy, there has been comparatively less research on its stimulation profile. This study develops and tests a predictive simulation-derived stimulation profile for FES cycling. We applied fully predictive simulations of FES cycling models following a straightforward framework consisting of (1) building torque-driven and muscle-driven models, (2) defining and solving an optimal control problem, (3) converting the optimal solution result to applicable FES control signal, (4) implementing the signal in an experimental setting, and lastly, (5) validating the control signal on a volunteer with spinal cord injury. The results, when compared to a bang-bang control strategy, increased in power output, cadence, and balance in all trials. As far as we know, this is the first study to successfully implement such a strategy. Our results show the potential of predictive simulations to improve the effectiveness of FES cycling rehabilitation.
AB - Functional electrical stimulation (FES) is commonly used in rehabilitation for its ability to activate muscle groups and functionally apply them. One of the most popular applications of FES is cycling for its safety and proven increase in users' health and quality of life. However, some challenges are intrinsic to the cycling application, among them, finding the best parameters of electrical stimulation to optimize the benefits for each user. While studies have focused on determining the optimal timing for stimulation with a bang-bang control strategy, there has been comparatively less research on its stimulation profile. This study develops and tests a predictive simulation-derived stimulation profile for FES cycling. We applied fully predictive simulations of FES cycling models following a straightforward framework consisting of (1) building torque-driven and muscle-driven models, (2) defining and solving an optimal control problem, (3) converting the optimal solution result to applicable FES control signal, (4) implementing the signal in an experimental setting, and lastly, (5) validating the control signal on a volunteer with spinal cord injury. The results, when compared to a bang-bang control strategy, increased in power output, cadence, and balance in all trials. As far as we know, this is the first study to successfully implement such a strategy. Our results show the potential of predictive simulations to improve the effectiveness of FES cycling rehabilitation.
KW - Muscles
KW - Pattern
UR - https://www.scopus.com/pages/publications/105011134926
UR - https://www.webofscience.com/api/gateway?GWVersion=2&SrcApp=pure_univeritat_ramon_llull&SrcAuth=WosAPI&KeyUT=WOS:001552194400199&DestLinkType=FullRecord&DestApp=WOS_CPL
U2 - 10.1109/ICORR66766.2025.11063118
DO - 10.1109/ICORR66766.2025.11063118
M3 - Conference contribution
C2 - 40644061
AN - SCOPUS:105011134926
SN - 979-8-3503-8069-9
T3 - International Conference On Rehabilitation Robotics Icorr
SP - 1245
EP - 1250
BT - 2025 International Conference On Rehabilitation Robotics, ICORR
PB - IEEE Computer Society
T2 - 2025 International Conference on Rehabilitation Robotics, ICORR 2025
Y2 - 12 May 2025 through 16 May 2025
ER -