DEVIATIONS IN WHOLE BODY ANGULAR MOMENTUM ARE LARGELY CORRECTED BEFORE FOOT PLACEMENT

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This paper investigated how mediolateral foot placement is controlled after mechanical perturbations that mainly altered either whole-body linear momentum or whole-body angular momentum, using 10 healthy adults walking on a treadmill at 2 and 5 km/h. Participants received either a pelvis pull (translation perturbation) or opposing pelvis and shoulder pulls (rotation perturbation), with perturbations applied at heel strike; 3D motion capture and OpenSim were used to compute linear and angular momentum and evaluate predictive foot placement models. The authors found that translation perturbations produced large deviations in linear momentum with minimal angular momentum changes, while rotation perturbations caused strong angular momentum deviations with smaller linear momentum changes, and that adding angular momentum only minimally improved early-swing foot placement prediction after rotation perturbations. This paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

This study examined how mediolateral foot placement is controlled following mechanical perturbations that affected either whole-body linear or angular momentum. Predictive foot placement models based on center of mass state alone were compared with models that additionally included whole-body angular momentum to determine whether whole-body angular momentum contributes to foot placement control beyond linear momentum. Ten healthy adults walked on a treadmill at 2 km/h and 5 km/h while being exposed to two perturbation types: (1) a pull to the pelvis that primarily altered linear momentum (translation perturbation) and (2) simultaneous pulls to the pelvis and shoulder in opposite directions that primarily altered angular momentum (rotation perturbation). Perturbations were applied at heel strike, with a magnitude of ∼120 N and a duration of 300 ms. Whole-body kinematics were recorded using 3D motion capture and processed in OpenSim to compute linear and angular momentum. Translation perturbations caused large deviations in whole-body linear momentum with minimal changes in whole-body angular momentum, whereas rotation perturbations induced strong whole-body angular momentum deviations with smaller changes in linear momentum. Including whole-body angular momentum minimally improved foot placement predictions during early swing after rotation perturbations. These findings indicate that mediolateral foot placement is primarily governed by linear momentum dynamics.
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Abstract This study examined how mediolateral foot placement is controlled following mechanical perturbations that affected either whole-body linear or angular momentum. Predictive foot placement models based on center of mass state alone were compared with models that additionally included whole-body angular momentum to determine whether whole-body angular momentum contributes to foot placement control beyond linear momentum. Ten healthy adults walked on a treadmill at 2 km/h and 5 km/h while being exposed to two perturbation types: (1) a pull to the pelvis that primarily altered linear momentum (translation perturbation) and (2) simultaneous pulls to the pelvis and shoulder in opposite directions that primarily altered angular momentum (rotation perturbation). Perturbations were applied at heel strike, with a magnitude of ∼120 N and a duration of 300 ms. Whole-body kinematics were recorded using 3D motion capture and processed in OpenSim to compute linear and angular momentum. Translation perturbations caused large deviations in whole-body linear momentum with minimal changes in whole-body angular momentum, whereas rotation perturbations induced strong whole-body angular momentum deviations with smaller changes in linear momentum. Including whole-body angular momentum minimally improved foot placement predictions during early swing after rotation perturbations. These findings indicate that mediolateral foot placement is primarily governed by linear momentum dynamics. Competing Interest Statement The authors have declared no competing interest. Footnotes Revised manuscript based on review comments.

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last seen: 2026-05-20T01:45:00.602351+00:00