Literature DB >> 33468002

The extensibility of the plantar fascia influences the windlass mechanism during human running.

Lauren Welte1, Luke A Kelly2, Sarah E Kessler2,3, Daniel E Lieberman3, Susan E D'Andrea4, Glen A Lichtwark2, Michael J Rainbow1.   

Abstract

The arch of the human foot is unique among hominins as it is compliant at ground contact but sufficiently stiff to enable push-off. These behaviours are partly facilitated by the ligamentous plantar fascia whose role is central to two mechanisms. The ideal windlass mechanism assumes that the plantar fascia has a nearly constant length to directly couple toe dorsiflexion with a change in arch shape. However, the plantar fascia also stretches and then shortens throughout gait as the arch-spring stores and releases elastic energy. We aimed to understand how the extensible plantar fascia could behave as an ideal windlass when it has been shown to strain throughout gait, potentially compromising the one-to-one coupling between toe arc length and arch length. We measured foot bone motion and plantar fascia elongation using high-speed X-ray during running. We discovered that toe plantarflexion delays plantar fascia stretching at foot strike, which probably modifies the distribution of the load through other arch tissues. Through a pure windlass effect in propulsion, a quasi-isometric plantar fascia's shortening is delayed to later in stance. The plantar fascia then shortens concurrently to the windlass mechanism, likely enhancing arch recoil at push-off.

Entities:  

Keywords:  arch-spring; biplanar videoradiography; foot arch biomechanics; plantar fascia; running; windlass mechanism

Mesh:

Year:  2021        PMID: 33468002      PMCID: PMC7893268          DOI: 10.1098/rspb.2020.2095

Source DB:  PubMed          Journal:  Proc Biol Sci        ISSN: 0962-8452            Impact factor:   5.349


  32 in total

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2.  Combining prehension and propulsion: the foot of Ardipithecus ramidus.

Authors:  C Owen Lovejoy; Bruce Latimer; Gen Suwa; Berhane Asfaw; Tim D White
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3.  Regulation of foot and ankle quasi-stiffness during human hopping across a range of frequencies.

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Review 4.  Rethinking the evolution of the human foot: insights from experimental research.

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6.  Influence of the windlass mechanism on arch-spring mechanics during dynamic foot arch deformation.

Authors:  Lauren Welte; Luke A Kelly; Glen A Lichtwark; Michael J Rainbow
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7.  The spring in the arch of the human foot.

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8.  Finite element analysis of plantar fascia under stretch-the relative contribution of windlass mechanism and Achilles tendon force.

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Authors:  Sarah M Stearne; Kirsty A McDonald; Jacqueline A Alderson; Ian North; Charles E Oxnard; Jonas Rubenson
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  8 in total

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Journal:  Front Bioeng Biotechnol       Date:  2022-05-16

2.  The extensibility of the plantar fascia influences the windlass mechanism during human running.

Authors:  Lauren Welte; Luke A Kelly; Sarah E Kessler; Daniel E Lieberman; Susan E D'Andrea; Glen A Lichtwark; Michael J Rainbow
Journal:  Proc Biol Sci       Date:  2021-01-20       Impact factor: 5.349

3.  Contribution of Plantar Fascia and Intrinsic Foot Muscles in a Single-Leg Drop Landing and Repetitive Rebound Jumps: An Ultrasound-Based Study.

Authors:  Masanori Morikawa; Noriaki Maeda; Makoto Komiya; Arisu Hirota; Rami Mizuta; Toshiki Kobayashi; Kazuki Kaneda; Yuichi Nishikawa; Yukio Urabe
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4.  Three-Dimensional Innate Mobility of the Human Foot on Coronally-Wedged Surfaces Using a Biplane X-Ray Fluoroscopy.

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5.  The influence of the windlass mechanism on kinematic and kinetic foot joint coupling.

Authors:  Lauren R Williams; Sarah T Ridge; A Wayne Johnson; Elisa S Arch; Dustin A Bruening
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6.  Flexor digitorum brevis utilizes elastic strain energy to contribute to both work generation and energy absorption at the foot.

Authors:  Ross E Smith; Glen A Lichtwark; Luke A Kelly
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7.  Novel Multi-Segment Foot Model Incorporating Plantar Aponeurosis for Detailed Kinematic and Kinetic Analyses of the Foot With Application to Gait Studies.

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8.  Effects of Barefoot and Shod on the In Vivo Kinematics of Medial Longitudinal Arch During Running Based on a High-Speed Dual Fluoroscopic Imaging System.

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  8 in total

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