Neonatal Isoerythrolysis in Kittens

Although feline neonatal isoerythrolysis is rare, associated mortality rate is high

Imagine this tragic scenario:

A mother cat in a cattery carries her litter normally and gives birth to a healthy litter of kittens. She cleans them, nurses them, cares for them but within a few days they have all weakened and died.  This may happen litter after litter with the cattery breeder wondering what keeps going wrong. While there are many reasons why newborn kittens might not survive, in this hypothetical the kitten loss is predictable and preventable. We are describing neonatal isoerythrolysis.

A mother cat carries her litter normally and gives birth to a healthy litter of kittens. She cleans them, nurses them, cares for them but within a few days they have all weakened and died. This may happen litter after litter with the cattery breeder wondering what went wrong. While there are many reasons why newborn kittens might not survive, this particular condition is preventable.

Neonatal isoerythrolysis is a tragedy among breeders of kittens and is often written off as infectious disease, genetic defects, or simply natural selection. In fact, it is simply a matter of mismatched blood typing.

A Human Example: Rh Disease

Many of us know our blood type: it is either A, B, O, or AB and comes with a negative or positive after it. It is the negative or positive that is important when it comes to HUMAN isoerythrolysis. The negative or positive in your blood type refers to whether you are negative or positive for a red blood cell protein called Rh factor, named for the Rhesus monkeys used in initial studies of this disease.

Problems do not occur when both parents are Rh positive or when both parents are Rh negative or even when the father is Rh negative and the mother is Rh positive. Problems occur with a certain combination.

When a man who is positive for Rh factor fathers a child with a woman who is negative for Rh factor, the child will be Rh positive. When the mother gives birth, her immune system becomes exposed to the baby’s blood. Her immune system mounts a response against Rh factor and soon she is armed with anti-Rh factor antibodies. This is not a problem for the first-born child. It is the second child who is in danger.

When the mother is pregnant again with another Rh positive child, the antibodies of her bloodstream cross the placenta and destroy her unborn child’s developing red blood cells. The unborn child will likely die. Luckily, this condition is preventable by first being aware of one’s Rh status when one becomes pregnant and by the administration of a product called RhIg when the first child is born. RhIg is an anti-Rh factor antibody that destroys any Rh factor entering the mother’s body at the time of the first birth. The Rh factor is destroyed before the mother’s immune system “sees it” thus preventing her from producing the antibodies that would attack her second child’s blood.

See more information on human Rh disease.

The Feline Disease

Cats do not have Rh factor but a similar parental blood mismatch can occur involving the feline blood types A, B, and AB blood. Cats with type A blood naturally carry antibodies against type B blood and cats with type B blood naturally have antibodies against type A blood. These antibodies do not need exposure to another cat's blood during birth (as with human Rh disease) or from an incompatible transfusion; those antibodies are just naturally there, ready to attack the opposite blood type.

It turns out that type A cats carry so little anti-B antibodies that few problems result, but type B cats carry a significant amount of anti-A antibodies. This means type B cats cannot safely receive type A blood and type B female cats will have difficulty raising kittens from a type A father. Type B feline blood is somewhat unusual in the mixed breed domestic short hair population, but it is fairly common in purebred cats, particularly the Asian breeds.

Type A is genetically dominant to type B so that the mating of a type B mother to a type A father will produce at least a 50% chance of type A kittens. These kittens will develop normally and have normal birth. Disaster strikes with nursing.

What is Colostrum?

Colostrum is milk produced by the mother of any mammal species for the first 12-24 hours or so. The first day of life is extra special for baby mammals as this is the time when the mother gives them a copy of her own immunity. The milk produced in this period is rich with all the antibodies the mother has to give: vaccination-generated antibodies, antibodies from exposure to all sorts of proteins she has experienced or infections she has survived, and, of course, antibodies against the “wrong” blood type.

The infant’s intestine is in a sensitive time during this period. The antibodies delivered in the mother’s colostrum are not digested like regular proteins; instead, they are absorbed intact and provide the basis for the baby’s protection against infectious disease until the baby’s immune system is mature enough to make its own antibodies. After the first day of life, the intestine achieves what is called closure and no more such absorption takes place. Any proteins that enter the GI tract are broken down as nutrients.

The type B mother cat is giving a great big dose of anti-A antibodies right into her kittens with her colostrum and the babies are absorbing it into their bodies. The antibodies destroy the kittens’ developing red blood cells; they get pale, perhaps even jaundiced. They get weaker and weaker and then they die, poisoned by their own mother’s milk.

Prevention and Saving the Litter

As with human Rh disease, the first step in prevention is awareness. If you are going to breed purebred cats, have their blood types tested before they are bred. This can be done at the veterinarian’s office with a test kit and can often be done while you wait. Ideally, a type B mother cat would only be bred to a type B tomcat.

So what do we do about the kittens already on the way? The key to survival is to keep the kittens from drinking their mother’s colostrum. As soon as they are born, they must be removed from the mother cat and either nursed by another mother cat or bottle-fed (see Orphan Kitten Care for full instructions). They can be returned to their real mother after her colostrum production is over. This ought to be 12-18 hours but keep them away for a full day just to be sure. Regular mother’s milk produced after this time is not a hazard as the antibodies will be digested by the babies. During that first 24-hour period, the kittens may nurse on a Type A mother cat or can be bottled or tube fed.

As for the immunity lost by giving up colostrum, there is a next best thing: a plasma transfusion. Feline plasma of the correct blood type can be given to the kittens by injection. This blood product will contain many protective antibodies and none of the harmful ones. It is not as good as type matched colostrum, but is fairly available in most animal blood banks.

Blood Typing

Feline blood typing can be performed by most animal hospitals. If a litter of kittens is planned, see your veterinarian about at least typing the mother cat so that you can plan ahead for complications. Neonatal isoerythrolysis is a preventable syndrome but only if it is anticipated.

tags;  feline neonatal isoerythrolysis, blood group, red blood cells, blood types, type b blood, blood group, feline immunodeficiency virus, feline panleukopenia, stem cells, neurological disease, infectious diseases, mps vi, mdbk cells, platelet-rich plasma, feline neonatal isoerythrolysis,

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