Human feet have evolved to facilitate bipedal locomotion, losing
an opposable digit that grasped branches in favor of a longitudinal
arch (LA) that stiffens the foot and aids bipedal gait. Passive elastic
structures are credited with supporting the LA, but recent
evidence suggests that plantar intrinsic muscles (PIMs) within the
foot ...
Human feet have evolved to facilitate bipedal locomotion, losing
an opposable digit that grasped branches in favor of a longitudinal
arch (LA) that stiffens the foot and aids bipedal gait. Passive elastic
structures are credited with supporting the LA, but recent
evidence suggests that plantar intrinsic muscles (PIMs) within the
foot actively contribute to foot stiffness. To test the functional
significance of the PIMs, we compared foot and lower limb
mechanics with and without a tibial nerve block that prevented
contraction of these muscles. Comparisons were made during
controlled limb loading, walking, and running in healthy humans.
An inability to activate the PIMs caused slightly greater compres-
sion of the LA when controlled loads were applied to the lower
limb by a linear actuator. However, when greater loads were
experienced during ground contact in walking and running, the
stiffness of the LA was not altered by the block, indicating that the
PIMs
’
contribution to LA stiffness is minimal, probably because of
their small size. With the PIMs blocked, the distal joints of the foot
could not be stiffened sufficiently to provide normal push-off
against the ground during late stance. This led to an increase in
stride rate and compensatory power generated by the hip muscu-
lature, but no increase in the metabolic cost of transport. The results
reveal that the PIMs have a minimal effect on the stiffness of the LA
when absorbing high loads, but help stiffen the distal foot to aid
push-off against the ground when walking or running bipedally.
