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EspañolEQUINE FORELIMB ANATOMY
The 'equine forelimb' is the front, or ''thoracic limb'' of the horse. It is attached to the trunk of the animal by purely muscular connections (the ''serratus ventralis'', ''trapezius'', ''rhomboideus'', ''latissimus dorsi'', ''brachiocephalicus'', ''subclavius'' and ''pectoralis'' muscles). This is in contrast to the forelimbs of several other vertebrates, including humans, who have skeletal attachments (the coracoid and clavicle bones).
During locomotion, the forelimb functions primarily for weight-bearing rather than propulsion and supports the forehand of the horse. In the standing horse, the forelimbs together support approximately 60% of the weight of the horse, and this pattern is carried over to locomotion, where the forelimb props the weight of the horse, while forward momentum is generated by the hind limbs (Merkens et al., 1993; Merkens and Schamhardt, 1994). As the horse moves, increasing impulsion shifts the horse's weight to the hindquarters.
When referring to equine anatomy, over time horse enthusiasts have often developed terminology for particular features that differs from the correct veterinary terminology. In this article, the acceptable veterinary terminology will be highlighted in 'bold', whereas the more casual terms will be ''italicised''. The definitive reference for veterinary terminology is the Nomina Anatomica Veterinaria, although this is not always adhered to by either researchers or clinicians in the field.
The figure below is a lateral photograph of the bones of the forelimb distal to the carpus:
The equine forelimb contains three 'metacarpal bones'. These are analogous to the bones within the human palm. The large 'third metacarpal' (informally the ''cannon'' or ''shin'' bone) provides the major support of the body weight. The smaller 'second and fourth metacarpals' are positioned medially and laterally respectively, toward the palmar side of the third metacarpal. These smaller metacarpals are often called ''splint bones''. The second and fourth metacarpals terminate distally in small residual swellings, which can be palpated on a living horse. The second and fourth metacarpals are joined to the third metacarpal by fibrous tissue, and occasionally by ossified bridges of bone, which often form after trauma to the region.
The 'proximal sesamoids' are paired bones which lie palmar to the 'metacarpophalangeal joint' (the ''fetlock joint''). These bones are joined to each other by a strong 'intersesamoidean ligament'. These bones are sesamoids of the 'interosseous ligament' (the ''suspensory ligament'') of the forelimb.
The 'proximal phalanx' or 'first phalanx' lies immediately distal to the third metacarpal bone, with which it articulates to form the condylar metacarpophalangeal joint (''fetlock joint''). This joint undergoes large motion in extension (this motion is sometimes called ''dorsiflexion'') during fast locomotion.
The 'middle phalanx' or 'second phalanx' lies distal to the proximal phalanx, forming the 'proximal interphalangeal joint' (the ''pastern joint''). This joint undergoes relatively little movement during locomotion (Degueurce et al., 2001; Crevier-Denoix et al., 2001), although there is evidence to suggest that what little motion it does experience is of quite large importance (Wilson et al., 2001; Ratzlaff and White, 1989).
The 'distal phalanx' or 'third phalanx' (also ''coffin bone'' or ''pedal bone''), is the most distal bone of the forelimb, and lies completely within the hoof capsule. The distal phalanx articulates with both the middle phalanx and the distal sesamoid, forming the 'distal interphalangeal joint' (the ''coffin joint'').
The 'distal sesamoid', or 'navicular bone' (note that "navicular bone" is acceptable in a veterinary context), articulates closely with the distal phalanx, to which it is connected by the 'impar ligament of the navicular bone'. The impar ligament is very strong and permits relatively little motion between the navicular bone and the distal phalanx.
★ Crevier-Denoix, N., Roosen, C., Dardillat, C., Pourcelot, P., Jerbi, H., Sanaa, M. and Denoix, J.-M. (2001) Effects of heel and toe elevation upon the digital joint angles in the standing horse. Equine Vet J, Suppl '33':74-78.
★ Degueurce, C., Chateau, H., Jerbi, H., Crevier-Denoix, N., Pourcelot, P., Audigie, F., Pasqui-Boutard, V., Geiger, D. and Denoix, J.-M. (2001) Three-dimensional kinematics of the proximal interphalangeal joint: effects of raising the heels or the toe. Equine Vet J, Suppl '33':79-83.
★ Merkens, H.W., Schamhardt, H.C., van Osch, G.J.V.M. and van den Bogert, A.J. (1993) Ground reaction force patterns of Dutch Warmblood horses at normal trot. Equine Vet J '25'(2):134-137.
★ Merkens, H.W. and Schamhardt, H.C. (1994) Relationships between ground reaction force patterns and kinematics in the walking and trotting horse. Equine Vet J, Suppl '17':67-70.
★ Ratzlaff, M.H. and White, K.K. (1989) Some biomechanical considerations of navicular disease. J Equine Vet Sci '9'(3):149-153.
★ Wilson, A.M., McGuigan, M.P., Fouracre, L. and MacMahon, L. (2001) The force and contact stress on the navicular bone during trot locomotion in sound horses and horses with navicular disease. Equine Vet J '33'(2):159-165.
★ Terms for anatomical location
★ Horse anatomy
★ The Anatomy of the Equine Hoof & Leg
During locomotion, the forelimb functions primarily for weight-bearing rather than propulsion and supports the forehand of the horse. In the standing horse, the forelimbs together support approximately 60% of the weight of the horse, and this pattern is carried over to locomotion, where the forelimb props the weight of the horse, while forward momentum is generated by the hind limbs (Merkens et al., 1993; Merkens and Schamhardt, 1994). As the horse moves, increasing impulsion shifts the horse's weight to the hindquarters.
When referring to equine anatomy, over time horse enthusiasts have often developed terminology for particular features that differs from the correct veterinary terminology. In this article, the acceptable veterinary terminology will be highlighted in 'bold', whereas the more casual terms will be ''italicised''. The definitive reference for veterinary terminology is the Nomina Anatomica Veterinaria, although this is not always adhered to by either researchers or clinicians in the field.
| Contents |
| Bones of the distal forelimb |
| Metacarpal bones |
| Proximal sesamoids |
| Proximal phalanx |
| Middle phalanx |
| Distal phalanx |
| Distal sesamoid |
| References |
| See also |
| External links |
Bones of the distal forelimb
The figure below is a lateral photograph of the bones of the forelimb distal to the carpus:
The bones of the equine forelimb distal to the carpus.
Metacarpal bones
The equine forelimb contains three 'metacarpal bones'. These are analogous to the bones within the human palm. The large 'third metacarpal' (informally the ''cannon'' or ''shin'' bone) provides the major support of the body weight. The smaller 'second and fourth metacarpals' are positioned medially and laterally respectively, toward the palmar side of the third metacarpal. These smaller metacarpals are often called ''splint bones''. The second and fourth metacarpals terminate distally in small residual swellings, which can be palpated on a living horse. The second and fourth metacarpals are joined to the third metacarpal by fibrous tissue, and occasionally by ossified bridges of bone, which often form after trauma to the region.
Proximal sesamoids
The 'proximal sesamoids' are paired bones which lie palmar to the 'metacarpophalangeal joint' (the ''fetlock joint''). These bones are joined to each other by a strong 'intersesamoidean ligament'. These bones are sesamoids of the 'interosseous ligament' (the ''suspensory ligament'') of the forelimb.
Proximal phalanx
The 'proximal phalanx' or 'first phalanx' lies immediately distal to the third metacarpal bone, with which it articulates to form the condylar metacarpophalangeal joint (''fetlock joint''). This joint undergoes large motion in extension (this motion is sometimes called ''dorsiflexion'') during fast locomotion.
Middle phalanx
The 'middle phalanx' or 'second phalanx' lies distal to the proximal phalanx, forming the 'proximal interphalangeal joint' (the ''pastern joint''). This joint undergoes relatively little movement during locomotion (Degueurce et al., 2001; Crevier-Denoix et al., 2001), although there is evidence to suggest that what little motion it does experience is of quite large importance (Wilson et al., 2001; Ratzlaff and White, 1989).
Distal phalanx
Close up of the coffin bone.
The 'distal phalanx' or 'third phalanx' (also ''coffin bone'' or ''pedal bone''), is the most distal bone of the forelimb, and lies completely within the hoof capsule. The distal phalanx articulates with both the middle phalanx and the distal sesamoid, forming the 'distal interphalangeal joint' (the ''coffin joint'').
Distal sesamoid
The 'distal sesamoid', or 'navicular bone' (note that "navicular bone" is acceptable in a veterinary context), articulates closely with the distal phalanx, to which it is connected by the 'impar ligament of the navicular bone'. The impar ligament is very strong and permits relatively little motion between the navicular bone and the distal phalanx.
References
★ Crevier-Denoix, N., Roosen, C., Dardillat, C., Pourcelot, P., Jerbi, H., Sanaa, M. and Denoix, J.-M. (2001) Effects of heel and toe elevation upon the digital joint angles in the standing horse. Equine Vet J, Suppl '33':74-78.
★ Degueurce, C., Chateau, H., Jerbi, H., Crevier-Denoix, N., Pourcelot, P., Audigie, F., Pasqui-Boutard, V., Geiger, D. and Denoix, J.-M. (2001) Three-dimensional kinematics of the proximal interphalangeal joint: effects of raising the heels or the toe. Equine Vet J, Suppl '33':79-83.
★ Merkens, H.W., Schamhardt, H.C., van Osch, G.J.V.M. and van den Bogert, A.J. (1993) Ground reaction force patterns of Dutch Warmblood horses at normal trot. Equine Vet J '25'(2):134-137.
★ Merkens, H.W. and Schamhardt, H.C. (1994) Relationships between ground reaction force patterns and kinematics in the walking and trotting horse. Equine Vet J, Suppl '17':67-70.
★ Ratzlaff, M.H. and White, K.K. (1989) Some biomechanical considerations of navicular disease. J Equine Vet Sci '9'(3):149-153.
★ Wilson, A.M., McGuigan, M.P., Fouracre, L. and MacMahon, L. (2001) The force and contact stress on the navicular bone during trot locomotion in sound horses and horses with navicular disease. Equine Vet J '33'(2):159-165.
See also
★ Terms for anatomical location
★ Horse anatomy
External links
★ The Anatomy of the Equine Hoof & Leg
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