3.2.1. Prominent spherocytosis

Spherocytes should be used as a diagnostic criterion only in dogs because feline erythrocytes do not consistently display central pallor. Interpreting spherocytes after blood transfusion should be done cautiously, because stored blood products may contain high proportions of spherocytes23 and spherocytes have been documented in human patients with hemolytic transfusion reactions.24, 25 Spherocytosis should be assessed in the monolayer of a well‐made blood smear, because spherocyte‐like artifacts arise toward the feathered edge and in thick areas.26 In anemic animals, spherocytes should be confirmed in the deeper monolayer to avoid artifacts in thin areas. Spherocytosis also can induce increased osmotic fragility,27, 28 but because osmotic fragility testing is influenced by other factors (eg, hyperlipidemia,27 erythrocyte age29), the panel does not advocate its routine use in the diagnosis of IMHA.

Reported causes of non‐immune‐mediated spherocytes, or morphologically similar pyknocytes, should be eliminated, including oxidative damage (eg, zinc30, 31 and acetaminophen32), envenomation,33, 34, 35, 36, 37 hypersplenism (eg, hepatosplenic lymphoma),38 pyruvate kinase deficiency,39 disorders associated with erythrocyte fragmentation (eg, endocarditis,40 microangiopathic hemolytic disorders including hemangiosarcoma,41 or hemolytic uremic syndrome),42 and dyserythropoiesis.43 Hereditary spectrin deficiency also potentially may give rise to spherocytes if smears are made from blood stored >24hours.44 The percentage of spherocytes on blood smears from human patients with mutations causing hereditary spherocytosis is variable, but can be high.45 A literature search for canine hereditary spherocytosis did not identify any cases with marked spherocytosis.

In a single study, ≥5 spherocytes/×100 oil immersion field yielded 63% sensitivity (95% confidence interval [CI], 39%‐84%) (when 95% CIs were not provided by the authors, the online MedCalc Diagnostic test evaluation calculator [https://www.medcalc.org/calc/diagnostic_test.php] was used to calculate them) and 95% specificity (95% CI, 76%‐100%) for IMHA in dogs,27 compared with 74% sensitivity (95% CI, 49%‐91%) and 81% specificity (95% CI, 59%‐95%)^c for ≥3/×100 oil immersion field.27 A threshold of ≥5 spherocytes/×100 oil immersion field therefore could be considered supportive of a diagnosis of IMHA, but 3‐4 spherocytes/×100 oil immersion field also may be consistent with IMHA provided no other cause of spherocytosis is identified. These thresholds are similar to the criteria for 1+ spherocytosis in a proposed semiquantitative grading system.46 Where spherocyte numbers are low (versus their typical abundance in extravascular IMHA), variability among fields could be an issue: calculating mean count over several fields (eg, 10) could help establish the true extent of spherocytosis. For enrollment of cases in IMHA research, only high‐quality blood smears should be used, and given the pitfalls of spherocyte recognition, examination of the smears by a board‐certified clinical pathologist is advantageous.

4.2.1. Piroplasms

Seventeen studies documented 103 cases of IMHA in Babesia‐infected dogs.57, 93, 94, 95, 96, 99, 102, 103, 104, 111, 120, 122, 128, 134, 141, 147, 151 The IME values for Babesia species as a whole ranged from 0.00 to 6.99, with a median of 4.55. Fifty‐three percent (10/19) of the IME values demonstrated an intermediate or high level of evidence that Babesia causes IMHA. For 3 additional studies, the number of dogs with Babesia and IMHA could not be determined.105, 125, 136

There is a high level of evidence that immune‐mediated destruction of erythrocytes contributes to anemia in dogs infected with B. gibsoni. Immune‐mediated hemolytic anemia was documented in 69 dogs in 9 studies,93, 94, 95, 96, 99, 102, 103, 111, 151 with an additional study (in which the number of infected dogs with IMHA could not be determined) providing useful mechanistic insight.125 The median IME value was 5.32, ranging from 2.54 to 6.99. For this Babesia species, 88% (8/9) of the studies showed intermediate (4) or high (4) IME values. Four were studies of dogs experimentally infected with B. gibsoni, yielding a median IME value of 6.41 and range of 6.08‐6.99.94, 95, 96, 99 Natural infection with B. gibsoni occurs most commonly in fighting breeds.102, 125 However, mixed breed dogs used in experimental studies also develop IMHA, suggesting that the immune‐mediated pathogenesis is largely driven by the parasite.99

Whether other species of Babesia cause IMHA in dogs remains unclear. One study documented IMHA in 2 chronically infected splenectomized mixed breed dogs experimentally infected with what was thought to be B. gibsoni, but later characterized as Babesia conradae,147 yielding an IME value of 6.25. Five studies documented 13 cases of IMHA in dogs infected with Babesia canis, with a median IME value of 3.20 and range of 0‐4.32.57, 104, 111, 128, 134 Babesia vogeli was documented in 2 studies of 5 dogs with IMHA, with IME values of 5.73 and 4.14. Five cases of IMHA were documented in a study of Babesia rossi‐infected dogs, although the authors presumed a Babesia species based on cytological examination of blood smears and geographic locale.120 The IME value was 2.56. In an additional study, the Babesia species was not specified, but again was likely to be B. rossi.122 Nine dogs with IMHA were documented in that study, with an IME value of 2.70. Thus, the evidence for large Babesia species causing IMHA is lower than that for B. gibsoni, attributed in part to the fact that most studies were not designed to determine if an association between IMHA and infection existed. Nevertheless, differences also may exist in pathogenicity among Babesia species that influence the risk of IMHA. For example, 1 study found that the majority of anemic B. vogeli‐infected dogs had IgM and IgG bound to erythrocytes, but these antibodies were not detected in dogs infected with B. canis.57 In this study, eccentrocytosis, suggesting oxidative damage, was more common in B. canis‐infected dogs. The IME value for B. canis in this study was 0, whereas it was 5.73 for B. vogeli.57

The mechanism of immune‐mediated erythrocyte destruction during B. gibsoni infection has been explored. Because Babesia species infect erythrocytes, antibodies appropriately targeting the organisms could result in “immune‐mediated” erythrocyte destruction without targeting self‐antigen. However, antibodies produced during infection also appear to target erythrocyte membranes. Oxidative injury may play a role in anti‐erythrocyte antibody formation.96 Activated macrophages cause oxidative damage to uninfected as well as infected erythrocytes during B. gibsoni infection, a factor that may contribute to the severity of IMHA in some dogs.96 In addition to oxidative damage, sialic acid residue removal is required to expose epitopes that are targeted by antibody.94 Interestingly, anti‐erythrocyte antibodies that developed in dogs experimentally infected with B. gibsoni did not attach to undamaged red blood cells in dogs that had recovered from clinical infection.93 Furthermore, in vitro studies have shown that Babesia‐induced antibody reactivity against erythrocytes is higher for aged and oxidized than for fresh erythrocytes.95 Taken together, these data suggest that ongoing damage to the red cell membrane and increased exposure of epitopes that are usually “hidden” facilitates immune‐mediated erythrocyte destruction. Once infection is controlled, the drive for immune‐mediated destruction stops.

Like Babesia species, Rangelia and Theileria species are protozoan parasites that infect erythrocytes in dogs. A study of dogs experimentally infected with Rangelia vitelli demonstrated that a regenerative anemia suspicious for IMHA developed in infected dogs.149 Treatment of infection resolved the anemia without immunosuppression. A retrospective case series of dogs naturally infected with Theileria spp. developed IMHA.137 Dogs were treated with combined immunosuppression and imidocarb dipropionate. The authors reported resolution of hematological abnormalities during an unspecified study period. The IME values could not be calculated, because the total number of dogs with IMHA could not be discerned.

9.2.1. Consensus Summary Statement

Dogs with IMHA should be screened for infection with Babesia spp. using combined testing with serology and polymerase chain reaction (PCR). Repeat testing by means of PCR should be performed in all dogs originally testing negative but with a high risk of infection based on breed or exposure risk. The sensitivity of PCR and serological testing may vary depending on the laboratory and test design. Infection with other piroplasms, including Rangelia and Theileria species, should be eliminated in endemic areas. Because D. immitis infection is associated with anemia and positive Coombs' test results, all dogs should be screened for D. immitis in endemic areas or when travel to such areas has occurred. Further study to determine how and if other vector‐borne disease agents cause IMHA is required before definitive screening recommendations can be made for additional organisms. However, screening for additional vector‐borne pathogens, in particular Anaplasma spp., Bartonella spp., Ehrlichia spp., and, in endemic areas, Leishmania spp., should be strongly considered. Potential foci of other infections identified during initial screening should be further investigated at the discretion of the attending clinician.

9.3.1. Consensus Summary Statement

Polymerase chain reaction testing for B. felis should be performed in cats from endemic areas and in those with suggestive clinical signs. Serological testing was not available at the time of writing, but combined testing would be optimal based on studies of Babesia species infecting dogs. Polymerase chain reaction testing for M. haemofelis should be performed in all cats with IMHA. Further studies are needed to determine whether infection with other hemotropic Mycoplasma species is associated with IMHA in immunosuppressed or coinfected cats. Testing for all 3 species is preferred when possible. All sick cats should be tested for FeLV and FIV infection, according to American Association of Feline Practitioners retrovirus management guidelines (https://www.catvets.com/guidelines/practice-guidelines/retrovirus-management-guidelines), screening all cats with IMHA for FeLV using antigen ELISA. Proviral FeLV DNA quantitative PCR testing may be helpful as a confirmatory test. Routine testing for feline coronavirus and non‐hemotropic Mycoplasma spp. in cats with IMHA is not recommended, but appropriate diagnostic tests should be considered in cats with compatible clinical signs.