Characterizing the mechanical function of the foot’s arch across steady-state gait modes

The arch of the human foot has historically been likened to either a truss, a rigid lever, or a spring. Growing evidence indicates that energy is stored, generated, and dissipated actively by structures crossing the arch, suggesting that the arch can further function in a motor- or springlike manner. In the present study, participants walked, ran with a rearfoot strike pattern, and ran with a non-rearfoot strike pattern overground while foot segment motions and ground reaction forces were recorded. To quantify the midtarsal joint’s (i.e., arch’s) mechanical behavior, a brake-spring-motor index was defined as the ratio between midtarsal joint net work and the total magnitude of joint work. This index was statistically significantly different between each gait condition. Index values decreased from walking to rearfoot strike running to non-rearfoot strike running, indicating that the midtarsal joint was most motor-like when walking and most springlike in non-rearfoot running. The mean magnitude of elastic strain energy stored in the plantar aponeurosis mirrored the increase in spring-like arch function from walking to non-rearfoot strike running. However, the behavior of the plantar aponeurosis could not account for a more motor-like arch in walking and rearfoot strike running, given the lack of main effect of gait condition on the ratio between net work and total work performed by force in the plantar aponeurosis about the midtarsal joint. Instead, the muscles of the foot are likely altering the motor-like mechanical function of the foot’s arch, the operation of these muscles between gait conditions warrants further investigation.

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Work Title Characterizing the mechanical function of the foot’s arch across steady-state gait modes
Access
Open Access
Creators
  1. Daniel J Davis
  2. John Henry Challis
Keyword
  1. Foot arch
  2. Midtarsal joint
  3. Plantar aponeurosis
  4. Walking
  5. Running
License CC BY 4.0 (Attribution)
Work Type Article
Publisher
  1. Journal of Biomechanics
Publication Date 2023
Publisher Identifier (DOI)
  1. https://doi.org/10.1016/j.jbiomech.2023.111529
Deposited September 02, 2023

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  • Added Creator Daniel J Davis
  • Added Creator John Henry Challis
  • Added Davis&Challis_ArchMechanics_JournalOfBiomechanics.pdf
  • Updated Description, License Show Changes
    Description
    • The arch of the human foot has historically been likened to either a truss, a rigid lever, or a spring. Growing evidence indicates that energy is stored, generated, and dissipated actively by structures crossing the arch, suggesting that the arch can further function in a motor- or spring-like manner. In the present study, participants walked, ran with a rearfoot strike pattern, and ran with a non-rearfoot strike pattern overground while foot segment motions and ground reaction forces were recorded. To quantify the midtarsal joint’s (i.e., arch’s) mechanical behavior, a brake-spring-motor index was defined as the ratio between midtarsal joint net work and the total magnitude of joint work. This index was statistically significantly different between each gait condition. Index values decreased from walking to rearfoot strike running to non-rearfoot strike running, indicating that the midtarsal joint was most motor-like when walking and most spring-like in non-rearfoot running. The mean magnitude of elastic strain energy stored in the plantar aponeurosis mirrored the increase in spring-like arch function from walking to non-rearfoot strike running. However, the behavior of the plantar aponeurosis could not account for a more motor-like arch in walking and rearfoot strike running, given the lack of main effect of gait condition on the ratio between net work and total work performed by force in the plantar aponeurosis about the midtarsal joint. Instead, the muscles of the foot are likely altering the motor-like mechanical function of the foot’s arch, the operation of these muscles between gait conditions warrants further investigation.
    • Journal of Biomechanics, 151, 111529
    License
    • https://creativecommons.org/licenses/by/4.0/
  • Published
  • Updated Keyword, Publisher, Publisher Identifier (DOI), and 1 more Show Changes
    Keyword
    • Foot arch, Midtarsal joint, Plantar aponeurosis, Walking, Running
    Publisher
    • Journal of Biomechanics
    Publisher Identifier (DOI)
    • https://doi.org/10.1016/j.jbiomech.2023.111529
    Description
    • Journal of Biomechanics, 151, 111529
    • The arch of the human foot has historically been likened to either a truss, a rigid lever, or a spring. Growing evidence indicates that energy is stored, generated, and dissipated actively by structures crossing the arch, suggesting that the arch can further function in a motor- or springlike manner. In the present study, participants walked, ran with a rearfoot strike pattern, and ran with a non-rearfoot strike pattern overground while foot segment motions and ground reaction forces were recorded. To quantify the midtarsal joint’s (i.e., arch’s) mechanical behavior, a brake-spring-motor index was defined as the ratio between midtarsal joint net work and the total magnitude of joint work. This index was statistically significantly different between each gait condition. Index values decreased from walking to rearfoot strike running to non-rearfoot strike running, indicating that the midtarsal joint was most motor-like when walking and most springlike in non-rearfoot running. The mean magnitude of elastic strain energy stored in the plantar aponeurosis mirrored the increase in spring-like arch function from walking to non-rearfoot strike running. However, the behavior of the plantar aponeurosis could not account for a more motor-like arch in walking and rearfoot strike running, given the lack of main effect of gait condition on the ratio between net work and total work performed by force in the plantar aponeurosis about the midtarsal joint. Instead, the muscles of the foot are likely altering the motor-like mechanical function of the foot’s arch, the operation of these muscles between gait conditions warrants further investigation.
  • Updated