SUMMARY
Unilateral skipping or bipedal galloping is one of the gait types that humans are able to perform. In contrast to many animals, where gallop is the preferred gait at higher speeds, human bipedal gallop only occurs spontaneously in very specific conditions (e.g. fast downhill locomotion). This study examines the lower limb mechanics and explores the possible reasons why humans do not spontaneously opt for gallop for steady-state locomotion on level ground. In 12 subjects, who were required to run and gallop overground at their preferred speed, kinematic and kinetic data were collected and mechanical work at the main lower limb joints (hip, knee, ankle) was calculated. In a separate treadmill experiment, metabolic costs were measured. Analysis revealed that the principal differences between running and galloping are located at the hip. The asymmetrical configuration of gallop involves distinct hip actions and foot placing, giving galloping legs different functions compared with running legs: the trailing leg decelerates the body in the vertical direction but propels it forward while the leading leg acts in the opposite way. Although both legs conserve mechanical energy by interchanging external mechanical energy with potential elastic energy, the specific orientation of the legs causes more energy dissipation and generation compared with running. This makes gallop metabolically more expensive and involves high muscular stress at the hips, which may be why humans do not use gallop for steady-state locomotion.
FOOTNOTES
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FUNDING
This study was supported by a research project funding [grant no. G.0183.09N to P.A. and D.D.C.] from the Research Foundation – Flanders (Belgium).
LIST OF SYMBOLS AND ABBREVIATIONS
- BW
- body weight
- COMwb
- whole-body centre of mass
- CV
- coefficient of variation
- Eext
- mechanical external energy
- Ekin
- kinetic energy
- Ekin,f
- forward kinetic energy
- Ekin,v
- vertical kinetic energy
- Epot
- gravitational potential energy
- FC
- foot contact
- g
- gravitational constant
- G
- gallop
- Glead
- leading leg of gallop
- GRFh
- horizontal ground reaction force
- GRFs
- ground reaction forces
- GRFv
- vertical ground reaction force
- Gtrail
- trailing leg of gallop
- HL1
- power absorption by the hip extensors of the leading leg
- HL2
- power generation by the hip extensors of the leading leg
- HL3
- power absorption by the hip flexors of the leading leg
- HL4
- power generation by the hip flexors of the leading leg
- HT1
- power absorption by the hip flexors of the trailing leg
- HT2
- power generation by the hip flexors of the trailing leg
- hwb
- height of the COMwb
- IC
- initial contact
- m
- mass
- R
- run
- SF
- stride frequency
- SL
- stride length
- SLIP
- spring-loaded inverted pendulum
- TO
- toe-off
- vf
- instantaneous forward velocity of the COMwb
- vpref
- preferred velocity
- vv
- instantaneous vertical velocity of the COMwb
- © 2013. Published by The Company of Biologists Ltd
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