Contractile behavior of the forelimb digital flexors during steady-state locomotion in horses ( Equus caballus): An initial test of muscle architectural hypotheses about in vivo function

The forelimb digital flexors of the horse display remarkable diversity in muscle architecture despite each muscle–tendon unit having a similar mechanical advantage across the fetlock joint. We focus on two distinct muscles of the digital flexor system: short compartment deep digital flexor (DDF sc)...

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Bibliographic Details
Published in:Comparative biochemistry and physiology. Part A, Molecular & integrative physiology Molecular & integrative physiology, 2009, Vol.152 (1), p.100-114
Main Authors: Butcher, M.T., Hermanson, J.W., Ducharme, N.G., Mitchell, L.M., Soderholm, L.V., Bertram, J.E.A.
Format: Article
Language:English
Subjects:
Animals
Biomechanical Phenomena
Digital flexors
Elastic energy
Elasticity
Electromyography
Equus caballus
Forelimb - physiology
Gait - physiology
Horse
Horses - physiology
Locomotion - physiology
Models, Biological
Muscle Contraction - physiology
Muscle work
Muscles - anatomy & histology
Muscles - physiology
Organ Size
Strain
Stress
Weight-Bearing - physiology
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Summary:The forelimb digital flexors of the horse display remarkable diversity in muscle architecture despite each muscle–tendon unit having a similar mechanical advantage across the fetlock joint. We focus on two distinct muscles of the digital flexor system: short compartment deep digital flexor (DDF sc) and the superficial digital flexor (SDF). The objectives were to investigate force–length behavior and work performance of these two muscles in vivo during locomotion, and to determine how muscle architecture contributes to in vivo function in this system. We directly recorded muscle force ( via tendon strain gauges) and muscle fascicle length ( via sonomicrometry crystals) as horses walked (1.7 m s − 1 ), trotted (4.1 m s − 1 ) and cantered (7.0 m s − 1 ) on a motorized treadmill. Over the range of gaits and speeds, DDF sc fascicles shortened while producing relatively low force, generating modest positive net work. In contrast, SDF fascicles initially shortened, then lengthened while producing high force, resulting in substantial negative net work. These findings suggest the long fibered, unipennate DDF sc supplements mechanical work during running, whereas the short fibered, multipennate SDF is specialized for economical high force and enhanced elastic energy storage. Apparent in vivo functions match well with the distinct architectural features of each muscle.
ISSN:1095-6433
1531-4332
DOI:10.1016/j.cbpa.2008.09.007