Hemolytic anemias are typically regenerative and result from lysis of RBCs in either the intra- or extravascular space. Intravascular hemolysis results in hemoglobinemia and hemoglobinuria, whereas extravascular hemolysis does not. Both types of hemolysis can result in icterus. In dogs, the most common cause of hemolytic anemia is immune mediated (60%–75%), although toxins, RBC trauma, infections, and RBC membrane defects can also cause hemolysis.
Immune-mediated hemolytic anemia (IMHA, see Immune-mediated Hemolytic Anemia (IMHA) and Thrombocytopenia) can be primary or secondary to neoplasia, infectious agents, drugs, or vaccinations. In IMHA, the immune system no longer recognizes RBCs as self and develops antibodies to circulating RBCs, leading to RBC destruction by macrophages and complement. In some cases, antibodies are directed against RBC precursors in the marrow, resulting in nonregenerative anemia. Animals with IMHA are usually icteric, sometimes febrile, and may have splenomegaly. Hematologic hallmarks of IMHA are regenerative anemia, hyperbilirubinemia, spherocytosis, autoagglutination, or a positive Coombs’ test.
Another methodology to evaluate dogs for anti-RBC antibodies is flow cytometry. Flow cytometry allows for detection and quantitation of red cell surface–bound IgG and IgM. Flow cytometry was found to be 88%–100% specific for diagnosing dogs with anti-RBC antibodies. One report suggests using flow cytometry to assess response to treatment for dogs, because there is a decrease in surface anti-RBC antibodies before reticulocytosis or increase in RBC count. Flow cytometry may not be readily available to all veterinary hospitals.
Animals with IMHA can show mild, indolent signs or be in an acute crisis. It is important to tailor treatment to the animal’s signs, including treating any underlying infections. Transfusion with packed RBCs is usually required. The goal of therapy is to stop the destruction of RBCs by treating with immunosuppressive drugs; supportive care is also a priority. Prednisone or prednisolone at a dosage of 1–2 mg/kg, bid, is considered first-line therapy, with azathioprine at 2 mg/kg/day (azathioprine is contraindicated in cats and may be replaced by chlorambucil) or cyclosporine at 5–10 mg/kg/day considered as a possible second agent. In one study, low-dose aspirin at 0.5 mg/kg/day improved survival times in dogs treated with azathioprine and prednisone. The veterinary literature is ambiguous on choice of second agent or when to introduce a second agent. Other immunosuppressive agents that have been used include mycophenolate and leflunomide.
In the acute hemolytic crisis, drugs such as cyclosporine (10 mg/kg/day, initially) or human intravenous immunoglobin (IVIG, 0.5–1.5 g/kg as a single dose) may also have benefit because of rapid onset of action.
Pulmonary thromboembolism is a risk in dogs with IMHA. These dogs are often hypercoagulable, which can be documented with thromboelastography. Dogs documented to be in a hypercoagulable state should be anticoagulated with heparin, which may be used in combination with antiplatelet therapy (aspirin 0.5 mg/kg/day with or without clopidogrel 1–2 mg/kg/day) if the platelet count is >40,000/μL. The dosing range for heparin is wide and variable, and dosage also depends on whether fractionated or unfractionated heparin is used. Heparin therapy can be monitored using activated partial thromboplastin time (APTT) or antifactor Xa concentrations (low-molecular-weight heparin).
Mortality rates for IMHA range from 20%–75%, depending on the severity of clinical signs. Negative prognostic indicators may include a rapid drop in PCV, high bilirubin concentration, moderate to marked leukocytosis (28,000 to >40,000 cells/μL), increased BUN, petechiae, intravascular hemolysis, autoagglutination, disseminated intravascular coagulation, and thromboembolic complications. Moderate to marked leukocytosis has been reported to be associated with tissue necrosis, most likely secondary to tissue hypoxia or thromboembolic disease. Referral to tertiary care facilities may improve survival.
Neonatal isoerythrolysis (NI) is an immune-mediated hemolytic disease seen in newborn horses, mules, cattle, pigs, cats, and rarely dogs. NI is caused by ingestion of maternal colostrum containing antibodies to one of the neonate’s blood group antigens. The maternal antibodies develop to specific foreign blood group antigens during previous pregnancies, unmatched transfusions, and from Babesia and Anaplasma vaccinations in cattle. Cats are unique in that blood type B cats have naturally occurring anti-A antibodies without prior exposure, and their kittens that are type A develop hemolysis after nursing. In horses, the antigens usually involved are A, C, and Q; NI is most commonly seen in Thoroughbreds and mules. Neonates with NI are normal at birth but develop severe hemolytic anemia within 2–3 days and become weak and icteric. Diagnosis is confirmed by screening maternal serum, plasma, or colostrum against the paternal or neonatal RBCs. Treatment consists of stopping any colostrum while giving supportive care with transfusions. If necessary, neonates can be transfused with triple-washed maternal RBCs. NI can be avoided by withholding maternal colostrum and giving colostrum from a maternal source free of the antibodies. The newborn’s RBCs can be mixed with maternal serum to look for agglutination before the newborn is allowed to receive maternal colostrum.
Microangiopathic hemolysis is caused by RBC damage secondary to turbulent flow through abnormal vessels. In dogs, it can be seen secondary to severe heartworm infection, vascular tumors (hemangiosarcoma), splenic torsions, and disseminated intravascular coagulation; in other species, causes include hemolytic uremic syndrome in calves, equine infectious anemia, African swine fever, and chronic classical swine fever. Schistocytes are common in blood smears from these animals. Treatment involves correction of the underlying disease process.
Hypophosphatemia (see Hypophosphatemia) causes postparturient hemoglobinuria and hemolysis in cattle, sheep, and goats. It can occur 2–6 wk after parturition. Hypophosphatemia with secondary hemolysis is seen in dogs and cats secondary to diabetes mellitus, hepatic lipidosis, and refeeding syndrome. Treatment with either oral or IV phosphorus is indicated, depending on the degree of hypophosphatemia. Cattle that drink too much water (water intoxication) are at risk of developing hemolysis secondary to hypotonic plasma. This is seen in calves 2–10 mo old and causes respiratory distress and hemoglobinuria. Clinical signs can progress to convulsions and coma. Hemolytic anemia, hyponatremia and hypochloremia, decreased serum osmolality, and low urine specific gravity in a calf would support the diagnosis of water intoxication. Treatment consists of hypertonic fluids (2.5% saline) and diuretics (eg, mannitol).
Toxins and drugs can cause anemia by many mechanisms. Those implicated most frequently in animals and their pathogenic mechanisms are listed (see Table: Toxic Causes of Anemia).
Many infectious agents—bacterial, viral, rickettsial, and protozoal—can cause anemia by direct damage to RBCs, leading to hemolysis, or by direct effects on precursors in the bone marrow (see Table: Infectious Causes of Anemia).
Several heritable RBC disorders cause anemia. Pyruvate kinase deficiencies are seen in Basenjis, Beagles, West Highland White Terriers, Cairn Terriers, and other breeds, as well as Abyssinian and Somali cats. Phosphofructokinase deficiency occurs in English Springer Spaniels. Deficiencies in these enzymes lead to shortened RBC life span and regenerative anemia. In dogs with phosphofructokinase deficiency, the hemolytic crises are set off by alkalosis secondary to excessive excitement or exercise. If such situations are minimized, these dogs may have a normal life expectancy. There is no treatment for pyruvate kinase deficiency, and affected dogs will have a shortened life span due to myelofibrosis and osteosclerosis of the bone marrow. Affected cats will have chronic intermittent hemolytic anemia, which is sometimes helped by splenectomy and steroids. Unlike dogs, cats have not been reported to develop osteosclerosis. A hereditary hemoglobinopathy, porphyria (see Congenital Erythropoietic Porphyria), leads to build-up of porphyrins in the body and has been described in cattle, cats, and pigs. It is most prevalent in Holstein cattle and can lead to a hemolytic crisis. Affected calves fail to thrive and are photosensitive. Diagnosis is made by finding increased levels of porphyrins in bone marrow, urine, or plasma. Teeth of affected animals fluoresce under ultraviolet light.