OBJECTIVE: The goal of this study was to investigate the learning patterns in leg pivoting neuromuscular control performance over six-week pivoting neuromuscular control training (POINT) and to estimate how many sessions at beginning are needed to estimate the overall pivoting neuromuscular control learning curve. METHODS: Twenty subjects (ten females, ten males) participated in 18 sessions of POINT (three sessions per week for six weeks) program using an off-axis elliptical trainer. Performance measures including pivoting instability and stepping speed were quantified for each study session during a stepping task while subjects were asked to control pivoting movements under a slippery condition. Learning curve relating the pivoting instability to training sessions was quantified by the power law and by the exponential curve as a function of sessions or days with three parameters: The limit of learning, rate of learning, and learning capacity. RESULTS: The power and exponential learning models characterized the learning curves similarly with no differences in [Formula: see text]. No significant sex differences were found in the limit of learning, rate of learning, and learning capacity. Based on [Formula: see text] and RMSE, data from the first three study sessions might be enough to estimate the pivoting neuromuscular performance over the whole training period. CONCLUSION: The findings showed that subjects' motor skills to improve pivoting instability followed the learning curve models. SIGNIFICANCE: The findings and models can potentially be used to develop more effective subject-specific therapy scheduling.
OBJECTIVE: The goal of this study was to investigate the learning patterns in leg pivoting neuromuscular control performance over six-week pivoting neuromuscular control training (POINT) and to estimate how many sessions at beginning are needed to estimate the overall pivoting neuromuscular control learning curve. METHODS: Twenty subjects (ten females, ten males) participated in 18 sessions of POINT (three sessions per week for six weeks) program using an off-axis elliptical trainer. Performance measures including pivoting instability and stepping speed were quantified for each study session during a stepping task while subjects were asked to control pivoting movements under a slippery condition. Learning curve relating the pivoting instability to training sessions was quantified by the power law and by the exponential curve as a function of sessions or days with three parameters: The limit of learning, rate of learning, and learning capacity. RESULTS: The power and exponential learning models characterized the learning curves similarly with no differences in [Formula: see text]. No significant sex differences were found in the limit of learning, rate of learning, and learning capacity. Based on [Formula: see text] and RMSE, data from the first three study sessions might be enough to estimate the pivoting neuromuscular performance over the whole training period. CONCLUSION: The findings showed that subjects' motor skills to improve pivoting instability followed the learning curve models. SIGNIFICANCE: The findings and models can potentially be used to develop more effective subject-specific therapy scheduling.
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