NEW THEORY MAY HELP AVOID NAVICULAR
What does a horse's foot have in common with a Nike
running shoe? A lot,
according to Dr. Robert Bowker, an associate professor in the
College of
Veterinary Medicine's Department of Anatomy.
Bowker has put together a new picture of equine foot physiology that
suggests
vascular systems in the horse foot functions in much the same way
that air- or
gel-filled running shoes do.
"Moving liquids are the best way to dissipate energy," he said.
"That is why some of the major running shoe manufacturers market
products that contain liquids in their soles."
Bowker has theorized a "hemodynamic flow" process in which he
proposes that much of the blood in horse feet fulfills purposes
other than providing nutrients to
hoof tissues.
"It dissipates energy within feet that is created during the act of
galloping,
trotting or walking," he said.
Currently, equine foot physiology researchers subscribe to one of
two anatomical theories--pressure theory or depression theory--which
are, in many respects, mirror images of each other.
"Pressure theory says that when the hoof hits the ground, the
pressure of the
impact hits the frog of the hoof, which causes the back part of the
foot to move
outward," Bowker said.
Depression theory suggests that when impact on the ground occurs,
the pastern
descends and depresses the digital cushion inside the hoof.
"According to both theories, these actions push hoof cartilage to
the outside,
with the digital cushion absorbing the energy," he said. Both
theories state
that blood is pumped from the hoof at impact.
Yet both theories share a single problem. Researchers who attempt to
duplicate
depression or pressure theory in the lab or on live horses are
unable to do so.
Problems arise when researchers attempt to account for how the
energy of the
hoof's impact with the ground is dissipated.
"The digital cushion is made of soft, elastic tissue and acts like a
spring,"
said Bowker. "So for every action, we would expect a reaction of
equal force."
Yet when researchers put energy measurement devices into digital
cushions, that does not happen.
"When the hoof is in the air, it registers zero pressure," he said.
"But when it
hits the ground, instead of registering positive pressure, it is
actually
negative."
Bowker's hemodynamic flow hypothesis suggests this negative pressure
is actually created by the outward movement of the hoof cartilage.
This movement creates a vacuum action that sucks blood from beneath
the coffin into the rear portion of the hoof.
"As the blood moves to the rear of the hoof through microvessels in
the lateral
hoof cartilage, it dissipates the energy caused by its impact on the
ground, much
like fluid-filled running shoes do," he said.
In developing this new theory, Bowker observed that horses with good
feet have more blood vessels in the lateral cartilage of their
hooves than those that had histories of foot problems.
Additionally, blood vessels in healthier animals were located inside
the lateral
cartilage of the hoof, and the digital cushion on these animals
tended to be made
of cartilaginous material instead of elastic tissue.
Bowker's theory not only proposes a new physiology for horse feet,
it also
suggests some of the more widely held views in the equine industry
should be
revised or, at least, reexamined.
For example, he presents a wholly different view of the horse foot
that sees it
as very responsive and adaptable to ground impact. Stimulation of
the internal
foot structures will result in the development of more efficient
ways to
dissipate energy and support the horse's weight, he believes.
It also suggests horses with navicular disease may not need to be
put down and
that hoof trimming techniques might need to be reviewed.
"We need to be trimming hooves so that more of the back part of the
foot--including the frog--bears the initial ground impact forces and
weight,"
Bowker stated.
He has been working with Gene Ovnicek, a farrier from Montana, and
Dr. Barbara Page, a veterinarian in Colorado, who are putting some
of these principles into practice. They are trimming the feet so
that the breakover is much shorter and the frog and back part of the
feet support a lot of the weight of the horse.
These farrier techniques seem to encourage development of tissues
that dissipate more energy when hooves hit the ground.
"If hooves are trimmed so that the frog rests on the ground," Bowker
said, "it
stimulates the back part of the hoof to grow more fibrous and
cartilaginous
digital cushions, which appear to be 'protective' of the more
chronic foot
problems."
Conversely, with digital cushions constructed of only elastic and
fatty tissues
with little or no fibrocartilage, the ground impact energy is
transmitted to foot
bones and ligaments, resulting in internal foot problems, such as
navicular
disease.
Across most of the breeds examined, environmental (i.e. nongenetic)
factors seem to be a major contribution to the development of the
internal tissues of the back part of the foot, Bowker said.
Some of these factors include the frog resting on the ground,
husbandry of the
horse, trimming and shoeing methods, and so forth.
"Horse feet with good environmental stimulation of the back part of
the foot, the
digital cushion, and the lateral cartilages will respond by becoming
more robust
structures to dissipate the initial impact energies and provide
better support
for the horse when the horse is standing," he said.
In those horses that do not have good environmental stimulation of
the back part of the foot (for example, a trimmed or recessed frog,
rather than one resting on the ground), regardless of the breed, the
internal tissues of the back part of the foot will be
underdeveloped, which will lead to internal foot problems such as
navicular syndrome, according to Bowker.
"We can develop trimming and shoeing methods that can stimulate the
back part of the foot--much like physical therapy to the back part
of the foot, which will stimulate the internal tissues of the
foot--to provide a more efficient system of energy dissipation and
provide better support for the weight of the horse," he said.
Bowker firmly believes that as we begin to understand internal foot
biology, we
will be able to decrease the incidence of navicular-type and other
foot diseases.
Dr. Robert Bowker, an associate professor in the College of
Veterinary Medicine's Department of Anatomy.
