X
Ray showing correct hip placement.
X
Ray showing incorrect hip placement.
By John C. Cargill, MA MBA, MS
and Susan Thorpe-Vargas, MS
This is the first in a series of articles addressing canine hip dysplasia. What follows is written from the perspective that the readers of the series are conscientious breeders who are the guardians of the genetic pools that constitute their breeds. While this series of articles will not replace a stack ofveterinary medical texts, it is a relatively in-depth look at the whole problem ofcanine hip dysplasia. Furthermore, the series is designed to be retained as a reference. When you finish reading it you will have a sufficient background tomake rational breeding choices and will be able to discuss the subject from aninformed basis with your veterinarian. You may not like what you read, but youwill be more competent to deal with the problem.
Hip dysplasia is one of the most controversial
and widespread problems in the dog fancy. So many old-wives tales, anecdotes,
misconceptions and even liesabound that one of the goals of this series
of articles must be to lay things out to the reader as they are, supported
with some scientific basis.
Let's start with a hypothetical scenario, but
one which too many of us have faced:
He's major-pointed; he moves like a dream; that
head piece may just be the best you have ever bred. In short, this boy
typifies everything that is good aboutyour breed and is the culmination
of many years of hard work, hopes, tears,frustration and all the ups and
downs, joys and heartaches common to the
fancy. Now it is time to X-ray his hips so that
you can not only use him in your breeding program, but advertise him at
stud. This is one boy that is going tomake it, and we are talking national
specialty here.
Problem - the radiographic results come back with
a diagnosis of canine hip dysplasia-severe. What should you do?
X
Ray showing correct hip placement.
X
Ray showing incorrect hip placement.
More among us than will admit have had this experience,
and most of those who haven't have seen it happen to other breeders concentrating
on similar bloodlines. Now back to our hypothetical scenario:
You never suspected a thing. The dog never appeared
to be in pain and his gait was what won him his major points. You have
invested time, money and your hopes on this animal, and it all has been
for naught! Now is the time forhysteria and self-blame:
What went wrong? Could this have been prevented?
Was he not fed correctly?
Was he kept on an improper surface while growing?
What is this disease that keeps reappearing in the most conscientious of
breeding programs, and which frustrates our attempts to eradicate it?
The first step in understanding canine hip dysplasia is to recognize it as not just one disease but many diseases, which together result in degenerative effects onthe hip joint. An extremely complex disorder, hip dysplasia is now thought by some to be the most noticeable manifestation of a systemic condition that can affect not only the hip joints but also those of the elbow, shoulder and event thejoints between the vertebrae1. Whatever else might result from the systemic conditions of this polygenic and multifactorial disease, hip dysplasia remains acommon, usually painful and often debilitating disease. "Efforts by dog breedersand veterinarians to reduce the prevalence of the disorder have proven marginally effective.
While there is much that we do not know we do
know that canine hip dysplasia is a genetically transmitted disease. If
you need to, or if you disagree at thispoint, please re-read that statement.
We will be repeating it throughout thisseries of articles, and this concept
is the basis for determination of fitness for breeding. The genetic concept
of heritability is a complicating factor and is onereason why hip dysplasia
remains so controversial. So often when you breedyou get more than you
see. Without resorting to too much math, heritability is equal to the statistical
variance due to genetic influence divided by the sum of the statistical
variance due to the genetic influence plus the variance due to the
environmental influence.
It is easier to comprehend the mathematical notation
than the statement of the equation:
H2 = heritability index Vgenetics = variance
due to genetics Venvironment = variance due to environmental influences
Thus, heritability is defined as an estimate of how much environmental
factors
play in the expression of the inherited genes.
A high heritability index means that environmental considerations are not
as important as genetic elements. The numerical value or heritability index
is a function not only of breed type but of the population from which the
data is extracted. "Studies of hip dysplasia genetics have indicated that
the disease is polygenic and multifactorial, withestimates of heritability
index in the range of 0.2 to 0.3"3 For instance, in a 1986 Swedish study,
the heritability of hip dysplasia inGerman Shepherds was 0.40 in Sweden,
but only 0.25 in the British Islesduring the same time period. The difference
between breeds may also reflect their levels of inbreeding. The more inbreeding,
the lower the heritability index because inbreeding reduces the total genetic
variability-that is, the gene pool is smaller. Inbreeding is not a bad
word. It only becomes problematic when
undesirable genetic traits are concentrated within
the gene pool. By definition, every purebred dog of any given breed is
highly inbred, or else it would look likea feral dog. We frequently hear
that the problem with the American KennelClub purebred dogs is that they
are inbred. We should hope so, otherwise we
could never fix type to the point where there
were discernible differences between breeds. On the other hand, we would
hope that the concentrated gene pools for the various breeds would have
been concentrated from stock exhibiting only desirable genetic traits.
We would hope that our field, bench and
obedience champions would be fit to contribute
to the gene pool. Of course, we know that is not true, or there would be
no purpose in writing this article.
To further complicate matters is the fact that
the pattern of inheritance indicates that more than one gene is involved.
Hip dysplasia is polygenic (involves manydifferent genes) and multifactorial
(influenced by many non-genetic factors). Thismakes sense when you think
of the complexity of the various structures
involved. Every cell in the body, except for
sex cells, carries two copies of each gene and each gene codes for a specific
characteristic.
One very simple example is eye color:
If the cell's two sets of genes for a specific
characteristic are exactly alike, then the animal is homozygous for that
characteristic.
If the two genes are different, i.e., heterozygous,
then one copy of the genes could code for blue eyes and the other could
code for brown eyes.
Let's complicate the matter even further.
If the animal carries two different copies of the same gene for eye
color, only one copy can be expressed in any given eye. Closer
to home, in humans for example, a child born to parents heterozygous
for eye color (both parents have a blue-eyed gene and
brown-eyed gene) will have a one-in-four
chance of having blue eyes. This is because the gene for blue
eyes is recessive and both copies for that code for blue eyes must
be present before that characteristic can be expressed. On the other
hand, if the child has brown eyes, we don't know what type of genes for
eye color he or she has. This is because
the gene for brown eyes is dominant and is
able to "mask" the physical expression of the blue-eyed gene. Alternatively,
the child could have only the genes that code for brown eyes. It is
beyond the scope of this article to address the various "odd" eye color
combinations, but co-dominance and variable penetrance may be what we are
dealing with in canine hip dysplasia.
What you have just read is an example of phenotype
vs. Genotype. Phenotype is the physical expression of a genetic characteristic.
Genotype is genetic composition of the organism. Using our eye-color example,
the child with twodifferent copies of the gene will express the brown-eyed
phenotype, but his or
her genotype will be heterozygous.
Let's add to the complexity once again. Co-dominance
of genes is a situation where neither gene is dominant. A clear example
illustrating the concept of genetic co-dominance is flower color. A snap
dragon homozygous (both copiesof color genes exactly alike) for white petals
crossed with a snap dragon
homozygous for red petals will produce a flower
with pink petals, not a flower with either white or red petals or a mixture
of red and white petals. Many researchers feel that hip dysplasia may be
a mixture of dominant, recessive andco-dominant genes. Quite probably,
this is one of the reasons why isolation of
the causative genetic factors of canine hip dysplasia
has been so elusive.
The concepts that you need to be clear on as we
leave this mini-course on genetics are:
heritability index; genetic and environmental
variability; dominant vs. Recessive genes; homozygous vs. heterozygous;
genetic co-dominance; and most importantly that hip dysplasia is genetically
inheritable and is polygenic andmultifactorial. In short, you can get it
in your breeding program when you bred
from animals that did not show it.
Before we can discuss an abnormal process (disease),
we need to first understand the normal process. In this case, we must be
able to answer the question, "What is a normal hip, what makes it normal,
and how does it get thatway?"
First, what is the hip? The hip joint is a main
weight-bearing joint consisting principally of a ball and socket. This
joint connects the pelvis to the lowerextremities. The ball is on the end
of the femur (thigh bone) and the socket(acetabulum) is part of the pelvis.
The acetabulum is formed from the embryonic process
of fusion of the ilium (top of the hip), the ischium (lowest part of the
hip) and the pubis (below the ilium but above the pubis) and the acetabular
bone. Most researchers feel thatnormal development requires close conformity
(close, tight fit) between the
acetabulum and the femoral head throughout their
growth period. In other words, the joint must fit tightly, deeply and snugly.
This is how a puppy's hip starts out-dysplastic and non-dysplastic puppies'
hips are indistinguishable. The first six months of life seem to be the
most critical growth period when the
depth of the socket must be maintained. It is
believed that the depth of the socket in the growing puppy may be in part
a function of the amount of stressthe femoral head can produce on the immature
acetabulum. Think of it as a thumb pushing into a ball of clay. The harder
the thumb pushes, the deeper theindentation in the clay. Much as a knife
edge concentrates force onto a relatively small surafce area (and a pin
of a diameter equal to the width of theknife edge even more), the two phenotypic
traits that maximize the forces between these two developing bony structures
are a small femoral head and a
long femoral neck. Note, however, that the normal
acetabulum is well-formed in utero, thus the stress may only serve to maintain
that socket depth. To cushion the force between these two bony surfaces,
there is a trulyremarkable substance called articular cartilage. This cartilage
is similar to a hard
sponge with a slick hard surface facing the interior
of the joint. In the normal joint, articular cartilage is able to change
its shape slightly when force is appliedto it, thus spreading and distributing
force more evenly into the subchrondalbone directly beneath the articular
cartilage. This is of major importance to thelong-term integrity of the
joint. Holding everything in place is another structure that does more
than just enhance the stability of the joint. The joint capsule is afibrous
structure filled with synovial fluid that surrounds, isolates and protects
the joint. This joint capsule is essential to proper development and functioning
ofthe joint. This structure is similar to the rubber grease bladder around
a ball joint
in the front suspension of your car. The cushioning
effect of the grease with the fluid pressure of the grease and the elasticity
of the bladder helps to stabilize thejoint. The bladder helps keep out
contaminants. This function becomes evenmore important as the joint agesand
surfaces become worn. The joint capsule contains the all-important synovial
fluid, the most important ingredients of
which are nutrients, which diffuse into the joint
from the blood supply, and hyaluronic acid (HA). The tissues within the
joint extract nutrients from the synovial fluid in which they are bathed.
Hyaluronic acid has a critical function:to provide lubrication. This slippery
and viscous substance prevents rapid
erosion of the articular cartilage and the surfaces
of the femoral head and the acetabulum. A membrane called the synovial
membrane lines the inside of the joint capsule, providing further isolation
of the joint space. Should the synovialmembrane become injured or ruptured,
white blood cells release enzymes and
oxygen radials (free radicals) that attack and
destroy hyaluronic acid. When this occurs, the loss of HA reduces the lubrication
that prevents friction and limitserosion of the articular cartilage. Even
worse, loss of HA allows the enzymesfrom white blood cells to join forces
with oxygen free radicals and attack the
articular cartilage. Free radicals play a major
role in degenerative arthritis.
The ball-and-socket (coxofemoral) joints of an
affected puppy radiographically appear to be structurally and functionally
normal at birth. The hips of anaffected puppy are indistinguishable from
a normal puppy at birth. This is animportant point to remember. As an affected
puppy grows, the hip joint undergoes severe structural alterations. The
changes result from joint laxity andadulteration/destruction of the constituents
of the synovial fluid and subsequent loss of lubrication and nourishment,
which serve to reduce the regenerative and elastic (force-absorbing and
distributing) properties of the articular cartilage. The normal joint retains
its tightness and close fit. Whereas in the geneticallydysplastic-to-be
puppy, the acetabular rim and femoral head become eroded. Remember that
the acetabular depth is partially a function of the small "footprint" of
the femoral head which concentrates force into a small surface
area. As the femoral head is flattened, the coxofemoral
joint no longer fits snugly. Excessive force is applied unevenly, especially
at the edges of the flattened femoral head. Visualize this joint looseness
as the difference betweenthe impact of a boxer's fist when the punch is
thrown with the glove already in
contact with the opponent's jaw as contrasted
with an initial stand-off distance of say 20 inches. In the first case,
little impact force is transmitted and nodamage is done; in the second,
there may be a knock-out. In the joint, theincrease in stress results not
only in abnormal wear of the articular cartilage, but causes tiny micro-stress
fractures to appear in the subchondral bone. The bodyattempts to heal these
fissures, causing the acetabulum to become filled in, i.e.,made shallower.
It is this cycle of damage and repair (osteophyte formation) that leads
to deformation of the joint, and degenerative hip disease.
Conclusions: Hip dysplasia is not something a
dog acquires; a dog either is genetically dysplastic or it is not. Initially,
the hips of affected and normalpuppies are indistinguishable. Later in
life, an affected animal can exhibit a wide range of phenotypes, all the
way from normal to severely dysplastic and
functionally crippled. You should take away from
this article the idea that hip dysplasia is genetically inherited. Never
believe a fellow breeder or fancier whoclaims there is no hip dysplasia
in his or her line. Never believe breeders whoclaim that if their breeding
lines carried the genes for hip dysplasia they would be able to see it
in their animals' gaits. This just is not true. Although work has been
started to find the genetic markers for the disease, wehave as yet no method
of genetic analysis that can tell breeders whether theirdogs are dysplastic
or not. We only have physical expression of the disease, and an effort
to "back door" into clear stock for breeding purposes. Breedersmust come
to understand that the only way to reduce the incidence of hip dysplasia
is by trying to breed from as few animals that have progenitors,
siblings, get, or get of siblings that had clinical
manifestations of hip dysplasia.
Obviously, a great amount of information is lacking
to make a rational breeding choice. These are hard words to have read,
but much of our problem has come from thousands of years of less than natural
selection resulting from thedomestication of the dog.
CREDITS
References 1. Olsewski J.M., Lust G., Rendano
B.T., et al. "Degenerative
joint disease:
Multiple joint involvement in young and mature
dogs." Am J Vet Res. 1983;
vol 44:1300-1308.
2. Smith G.K., Biery D.N.
"New concepts of coxofemoral joint stability
and the development of a clinical
stress-radiographic method for quantitating hip
joint laxity in the dog." J Am
Vet Med Assoc. 1990;196:59-70.
3. Ibid., p. 59.
4. Cargill J. "Truth in advertising: breeder
self-regulation I." Dog World.
1990(Jul);75 No.7:38-82.
5. Cargill J. "Truth in advertising: breeder
self-regulation II." Dog World.
1990(Aug);75 No.8:111-116.
6. Cargill J. "What should 'champion' mean?"
Dog World. 1993(Feb);78
No.2:34-35.
