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Dustin A. Bruening
Researcher at Brigham Young University
Publications - 54
Citations - 999
Dustin A. Bruening is an academic researcher from Brigham Young University. The author has contributed to research in topics: Ankle & Medicine. The author has an hindex of 14, co-authored 46 publications receiving 688 citations. Previous affiliations of Dustin A. Bruening include Shriners Hospitals for Children & Wright-Patterson Air Force Base.
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Sex differences in whole body gait kinematics at preferred speeds
TL;DR: Sex differences in whole body gait kinematics from a large sample of subjects walking at self selected speeds showed that in the frontal plane, women walked with greater pelvic obliquity than men, but exhibited a more stable torso and head.
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Analysis of a kinetic multi-segment foot model part II: Kinetics and clinical implications
TL;DR: An ankle joint powers are shown to be overestimated when using a traditional single-segment foot model, as substantial angular velocities are attributed to the mid-tarsal joint.
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Analysis of a kinetic multi-segment foot model. Part I: Model repeatability and kinematic validity
TL;DR: A three-segment kinetic foot model is presented and thorough evaluation of model performance during normal gait and segment rigidity analysis suggested rigid body behavior for the Shank and Hindfoot, with the Forefoot violating the rigid body assumptions in terminal stance/pre-swing.
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Interactions of sex and aging on spatiotemporal metrics in non-pathological gait: a descriptive meta-analysis
TL;DR: Non-dimensional gaitspeed analysis suggests that gait speed differences between men and women may be an artifact of size rather than sex, and men may take longer step lengths than women, and women might have a higher cadence than men.
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Energy neutral: the human foot and ankle subsections combine to produce near zero net mechanical work during walking.
TL;DR: This study deconstructed the mechanical work production during barefoot walking in a segment-by-segment manner (hallux, forefoot, hindfoot, and shank) by isolating the forces acting within each foot segment through controlling the placement of the participants’ foot as it contacted a ground-mounted force platform.