Variability in the cleavage of exosome-associated transferrin receptor questions the utility of clinically useful soluble transferrin receptor assays for dogs, cats, and horses.

Whole transferrin receptor (TfR) is present in reticulocyte exosomes. Soluble transferrin receptor (sTfR) is cleaved from whole TfR in human plasma, with the remnant cytoplasmic domain (cTfR) remaining membrane associated. In humans, sTfR is a biomarker that can detect iron deficiency in the presence of inflammatory disease. This condition is still a diagnostic dilemma in veterinary species. We aimed to (1) confirm the presence of exosomes and exosome-associated TfR in the serum of dogs, cats, and horses; and (2) to assess and compare the proportion of cTfR to total (cTfR + whole) in exosomal membranes of healthy and diseased dogs and cats and in healthy horses to indirectly predict their anticipated levels of circulating sTfR. We used discarded serum and whole blood samples from canine and feline patients, separated into healthy and diseased groups based on the health status of each patient, and healthy equine participants from a previous study. Ultracentrifugation, followed in some experiments by OptiPrep discontinuous density gradient fractionation, was used to isolate exosomes. Exosomes and associated TfR were identified using TEM and Western blot for TfR, respectively. Densitometry tracings of Western blots of serum exosomes were used to measure the proportion of cTfR to total TfR. Extracellular vesicles compatible with exosomes were successfully isolated and expressed TfR. The proportion of cTfR in dogs was greater than 50%, indicating that a majority of the whole TfR was cleaved to produce sTfR (and remnant cTfR). There was significant interindividual variation and no significant difference between healthy and diseased animals. The proportion of cTfR in cats was very low at 11%, indicating that very little sTfR was likely produced. There was a small yet significant difference between healthy and diseased cats. Healthy horses do not appear to cleave exosome-associated TfR. Diagnosis of iron deficiency in the presence of inflammatory disease remains a challenge in veterinary medicine. Our results indicate that TfR is poorly or unpredictably cleaved in veterinary species, revealing that there are species differences in exosomal TfR handling. These data suggest that development of an assay for the detection and quantification of sTfR in the species investigated may not be warranted.

Thromboelastographic evidence of inhibition of fibrinolysis after ε-aminocaproic acid administration in a dog with suspected acute traumatic coagulopathy.

OBJECTIVE: To describe the thromboelastographic changes in fibrinolysis with ε-aminocaproic acid treatment in a dog with suspected acute traumatic coagulopathy. CASE SUMMARY: A 9-year-old female spayed Airedale Terrier was presented with multiple injuries consistent with motor vehicle trauma. After surgical repair of a diaphragmatic hernia and minor laceration of the right cranial lung lobe, the dog continued to produce copious volumes of hemorrhagic fluid from the thoracic cavity despite multiple plasma transfusions, autotransfusions, and failure to locate a definitive source of bleeding during 2 separate surgeries. ε-Aminocaproic acid treatment was initiated and was associated with rapid clinical improvement and diminished fibrinolysis based on a modified plasma-based thromboelastogram. NEW OR UNIQUE INFORMATION PROVIDED: This report describes thromboelastographic evidence of inhibition of fibrinolysis after ε-aminocaproic acid administration in a dog with suspected acute traumatic coagulopathy. Thromboelastrography may be useful in monitoring therapy with antifibrinolytic drugs.