Horse Stay Apparatus - Anatomy PDF

Summary

This document provides a detailed explanation of the Horse's stay apparatus. The stay apparatus is a crucial group of ligaments and tendons that allow the horse to remain standing for extended periods. It helps reduce muscle fatigue and maintain balance.

Full Transcript

Horse sleeping while standing
THE PASSIVE STAY APPARATUS

The stay apparatus is a group of ligaments, tendons
and muscles which "lock" major joints in the limbs of
the horse, allowing the animal to sleep in a standing
position while expending minimal energy.
The stay apparatus allows animals to relax their
muscles and doze without collapsing. (Horses are able
to sleep lying down as well).
 The Passive Stay Apparatus
Horses remain on their feet for long periods, much
longer than other animals.
Most of the weight when a horse is at rest is carried
by the tendons, ligaments and deep fascia of each
leg.
This means that when standing, the horse requires
minimal muscle activity and does not tire quickly.
The supportive mechanisms in both the fore and hind
limbs are very similar in the horse.
When a horse is standing, muscles on opposite sides of the
joints delicately contract and relax so that it stays in balance.
This obviously puts considerable strain and stress on the
muscles.
To combat this, the horse has increased the fibrous content of
many muscles.
These collagenous muscles have been named collectively as
the stay apparatus.
This is further divided into the suspensory apparatus and the
check apparatus
 Overview of Passive Stay Apparatus -Thoracic Limb
Left thoracic limb- lateral view
What is the function of the stay apparatus? The
horse uses its thoracic limb stay apparatus to
support the weight of the front end of its body
while using a minimal amount of muscular
activity. The stay apparatus helps prevent
fatigue of the limb muscles by reducing the
amount of energy required to keep the limb
stable.

How does the stay apparatus function?
The stay apparatus transfers weight from the
thoracic limb muscles to connective tissue
structures that do not tire, namely tendons,
ligaments or bone. With the weight shifted
from muscle to connective tissue elements or
bone, the horse requires less muscular activity
to keep the limb stable and hold up the front
end of the body.
The stay apparatus helps the limb resist
gravitational forces that would otherwise cause
the thoracic limb joints to flex and allow the
body to collapse to the ground.

From: http://cal.vet.upenn.edu
Thoracic Limb
The stay apparatus has three main components;
1. The suspensory apparatus.
2. The stay apparatus.

3. The check apparatus.

Pelvic Limb
The stay apparatus has three main components;
1. The patellar locking mechanism.
2. The reciprocal mechanism.
3. The check apparatus.
Stay apparatus of the front limb

Fixing the shoulder
-Extrinsic muscles e.g. serratus
ventralis
-Tenon of origin of Biceps brachii
-Lacertus fibrosus
Passive Stay Apparatus of the Thoracic Limb

The stay apparatus has three main components;
1. The suspensory apparatus.
2. The stay apparatus.
3. The check apparatus
The Passive Stay Apparatus of the Thoracic Limb

1. Suspensory Apparatus

'Interosseous medius/Suspensory ligament'
Attaches to the distal row of carpal bones and metacarpus.
Runs distally on the palmar surface of the metacarpal bone
and then bifurcates proximal to the fetlock joint, with a small
branch connecting to each sesamoid.
continues distally on the dorsal surface of the proximal
phalanx and joins the common digital extensor tendon, which
continues to insert on the PII and PIII.
 Ligaments Associated with the Stay Apparatus
i. Collateral sesamoid ligaments - connect the
abaxial surface of the sesamoid to the
metacarpus and proximal phalanx.
ii. Palmar ligaments - connect the sesamoid bones
together.
iii. Distal sesamoidean ligaments - connect the
sesamoids to the proximal and middle phalanges.
This ligament can be seen as a direct continuation
of the interosseous muscle with the sesamoids
embedded in it.
 Ligaments Associated with the Stay Apparatus

Thus by virtue of the ligamentous arrangement, the
suspensory apparatus without any muscular action can
resist extension of the fetlock and pastern through the
distal sesamoidean ligaments and resist flexion of the
pastern and coffin joints through the common digital
extensor tendon.
 2. Stay Apparatus
i. The serratus ventralis supports the cranial part of

the body, and connects the costal side of the
scapula to points of attachment on the caudal
cervical vertebrae and cranial ribs.
It contains a tendinous layer that suspends the
body once the muscles relax.
This will, however, cause flexion of the shoulder
which needs to be balanced by the extensors of the
shoulder.
 2. Stay Apparatus
ii. The Biceps brachii fulfills this role.
Its collagenous tendon extends the length of the muscle
and divides near the elbow.
The short tendon inserts on the radial tuberosity, the long
tendon (lacertus fibrosus) continues distally and blends with
the tendon of the extensor carpi radialis and forearm fascia.
Combined, these insert on the proximal end of the
metacarpus.
Thus, the biceps have provision to be able to relax without
the collapse of the shoulder, elbow and carpal joints.
 3. Check Apparatus
i. The superficial digital flexor muscle, continues past the
carpus as a thick tendon.
ii. The accessory or superior check ligament is its tendinous
radial head that joins the muscle at this point.
The tendons continue distally and bifurcate by the
fetlock into slips, that attach to the medial and lateral aspect
of the pastern joint.
There is therefore a ligamentous connection from the distal
radius to the pastern that can help prevent extension of the
carpal and fetlock joints without muscle contractions.
 3.Check Apparatus
iii. The deep digital flexor also forms a thick tendon just
proximal to the carpus.
iv. The accessory ligament or inferior check ligament, joins
the tendon at the middle of the metacarpus.
They then continue through the bifurcation of the superficial
digital flexor tendon , through the intersesamoidean groove
at the fetlock joint, over the pastern and insert on PIII.
This ligamentous tissue between the metacarpal region and
distal phalanx helps prevent extension of the fetlock , pastern
and coffin joints.
Passive stay apparatus of Pelvic Limb

The stay apparatus has three main components;
1. The patellar locking mechanism.
2. The reciprocal mechanism.
3. The check apparatus.
Passive stay apparatus of Pelvic Limb
The equine hind limb skeleton supports a massive
amount of weight from the main body of the horse.
This weight is centered on the femoral head and
then continues in a vertical line down to the ground
by intersecting the hoof.
This would result in a collapse of the leg by flexion
of the stifle and hock, and overextension of the
fetlock and pastern, if there wasn't some
supporting mechanism.
The stay apparatus is a collection of tendons and
ligaments that provide this support, whilst using
minimal muscular effort.
The stay apparatus has three main components;
patellar locking, the reciprocal mechanism and the
check apparatus.
 1. Patellar Locking Mechanism

This important in reducing muscle fatigue by
immobilizing the stifle joint.
It is the specific anatomy of the equine stifle that
enables the locking to occur and includes a number
of anatomical structures.
The trochlea groove is wide for the gliding movement
of the patella and the medial trochlear ridge is the
larger of the two ridges.
 1. Patellar Locking Mechanism

It is wide and round proximally and surmounted by
the tubercle of the trochlea. The articular aspect of
the patella has a vertical ridge which sits in the
trochlear groove and is flanked by two concave
areas which relate to the trochlea ridges.
The medial concavity is continued by the patellar
cartilage.
This is a strong curved plate of fibrocartilage that is
adapted to the medial ridge.
 Patellar Locking Mechanism
During normal flexion and extension of the stifle the
patella will glide in the trochlear groove.
When the horse rests its weight on the hind limb the
stifle can extend beyond a certain point.
This causes the patella to move to the proximal
extremity of the trochlear groove, a medial twist then
results in the medial ridge protruding between the
middle and medial patellar ligaments with the patellar
cartilage hooking over the trochlea tubercle.
 Patellar Locking Mechanism

Thus the patella is locked and further flexion is not possible.
This results in an immobile stifle joint and so no muscle
activity is needed to maintain the leg in this position; thus
allowing the horse to rest a lot of its weight on this leg.
To release the patella, the horse shifts its weight to the other
limb and the quadriceps contract drawing the patella
proximally. It then twists laterally and is returned to the
trochlear groove.
 2. Reciprocal Mechanism

The reciprocal mechanism is a modification made of
largely tendinous muscles on either side of the tibia.
Cranial Aspect
i. Peroneus tertius is on the cranial aspect.
It's origin is between the trochlea and lateral condyle.
It bifurcates distally, both parts inserting in the tarso-
metatarsal region.
 2. Reciprocal Mechanism

This fibrous muscle ensures that flexion of the stifle
is accompanied by flexion of the hock.
Caudal aspect
ii. the superficial digital flexor
iii. the associated fibrous band of the gastrocnemius.
The band of the gastrocnemius originates on the
lateral supracondyloid tuberosity of the femur and
inserts on the calcaneus.
 2. Reciprocal Mechanism

The superficial digital flexor originates as a strong
tendon from the caudal aspect of the femur between
the two heads of the gastrocnemius.
It runs distally covering the gastrocnemius tendon
and partially attaches to the point of the hock.
It continues distally and inserts as in the forelimb.
 2. Reciprocal Mechanism

These two muscles ensure that when the stifle is in
extension the hock is also in extension.
These structures thus receive their name from the
reciprocating action of when the femur moves
cranially the distal limb swings caudally and visa
versa.
This apparatus also ensures that when the patella is
locked the hock is also immobilized.
These results are obtained with no muscle fatigue.
 3. Check Apparatus
The check apparatus of the accessory
ligament of the deep digital flexor tendon is
very similar to that of the thoracic limb.
The superficial digital flexor muscle is entirely
tendinous and so there is little/no muscle to
be fatigued, thus a 'check' ligament would be
of no advantage and so there is none in the
hind limb.