warfarin and Factor-X-Deficiency

A rabbit model was developed to examine the effect of sodium warfarin on peripheral blood monocyte tissue factor (MTF) activity. After three days of treatment with sodium warfarin, MTF expression was significantly impaired (p less than 0.003). Vitamin K reversed this inhibition despite continued treatment with warfarin. Animals resistant to warfarin did not become anticoagulated and failed to demonstrate inhibition of MTF expression. Cells grown in plasma from warfarin-treated animals expressed reduced amounts of MTF activity, while cells grown in normal rabbit plasma demonstrated procoagulant activity in assays using both normal and factor VII-deficient substrate plasmas. These studies suggest that normal factor VII binds to monocytes during the culture period. Moreover, a plasma component in warfarin-treated animals, possibly abnormal factor VII, may bind to monocytes and block expression of MTF activity. This may represent another mechanism for warfarin-mediated inhibition of cell-mediated coagulation reactions in vivo.

Topics: Animals; Cell Adhesion; Cell Survival; Cells, Cultured; Culture Media; Factor VII Deficiency; Factor X Deficiency; Female; Granulocytes; Humans; Kinetics; Monocytes; Prothrombin Time; Rabbits; Warfarin

Two siblings with m ild hemorrhagic symptoms had combined functional deficiencies of vitamin K-dependent clotting factors. Prothrombin (0.18-0.20 U/ml) and Stuart factor (Factor X, 0.18-0.20 U/ml) and Stuart factor (Factor X, 0.18-0.20 U/ml) were most severely affected. Antigenic amounts of affected coagulation factors were normal and normal generation of thrombin activity occurred in the patients' plasmas after treatment with nonophysiologic activators that do not require calcium for prothrombin activation. Hepatobilary disease, malabsorptive disorders, and plasma warfarin were not present. Both parents had normal levels of all coagulation factors. The patients' plasmas contained prothrombin that reacted both with antibody directed against des-gamma-carboxyprothrombin and native prothrombin. Crossed immunoelectrophoresis of patients' plasmas and studies of partially purified patient prothrombin suggested the presence of a relatively homogeneous species of dysfunctional prothrombin, distinct from the heterologous species found in the plasma of warfarin-treated persons. These studies are most consistent with a posttranslational defect in hepatic carboxylation of vitamin K-dependent factors. This kindred uniquely possesses an autosomal recessive disorder of vitamin K-dependent factor formation that causes production of an apparently homogeneous species of dysfunctional prothrombin; the functional deficiencies in clotting factors are totally corrected by oral or parenteral administration of vitamin K1.

Topics: Adolescent; Adult; Binding Sites; Calcium; Factor X Deficiency; Female; Hemophilia B; Humans; Hypoprothrombinemias; Immunoelectrophoresis, Two-Dimensional; Male; Partial Thromboplastin Time; Prothrombin; Prothrombin Time; Vitamin K Deficiency; Warfarin

Human Factor X was isolated from Cohn fraction III and characterized by polyacrylamide gel electrophoresis, amino acid composition, and isoelectric focusing. Two molecular forms with biological activity were observed at isoelectric points of 4.8 and 5.0. Antisera generated to Factor X was monospecific and used to establish an equilibrium competitive inhibition radioimmunoassay. This assay was specific for human Factor X and did not cross-react with human prothrombin or bovine Factor X within the sensitivity range of 6-300 ng Factor X antigen/ml. The mean concentration of Factor X based on the antigen was 11.9 mug/ml, whereas concentration values based on coagulant activity was 7.8 mug/ml. This 30% difference in measurement appears to result from the presence of a subpopulation of Factor X molecules devoid of coagulant activity. The radioimmunoassay was used to qualitatively and quantitatively compare purified Factor X to plasmic Factor X obtained from normal, warfarintreated, acquired Factor X-deficient, and congenitaldeficient patients. In all but one case, the Factor X present in these plasmas was immunochemically identical to the purified Factor X and permitted precise quantitation of these abnormal Factor X molecules. Factor X procoagulant activity was analyzed relative to Factor X antigen and the specific activities were used to characterize normal and abnormal Factor X molecules. Reduced Factor X activity in plasmas from warfarin-treated and acquired Factor X-deficient patients was attributed to both decreases in Factor X antigen and decreased function of the Factor X molecules. Congenitally deficient patients, in general, showed a reduction in Factor X antigen in parallel with Factor X procoagulant activities resulting from comparable decreases in specific biological activity of the molecules.

Topics: Amino Acids; Blood Coagulation Disorders; Electrophoresis, Polyacrylamide Gel; Epitopes; Factor X; Factor X Deficiency; Humans; Hypoprothrombinemias; Isoelectric Focusing; Radioimmunoassay; Warfarin

Activated partial thromboplastin times (APTT's) performed with a semi-automated electrical-conductivity type of clot timer on plasmas from patients with hepatic disease and intravascular coagulation, and on warfarin or heparin therapy, were significantly lower than when done on the same plasmas with either a manual optical method or an automated optical-endpoint instrument. Results of APTT's done on normal plasmas by the three methods were not significantly different. Substitution of different activator-phospholipid reagents resulted in some variability in results, but these differences were less than those between the different done with both the electrical clot timer and the automated optical instrument on prepared plasmas containing 5.0 or 1.0% of factor II, V, VIII, IX, OR X revealed shorter times with the electrical clot timer only in the case of factor II- and factor V-deficient plasmas. APTT's done on normal plasmas to which 0.1 or 0.3 units per ml. of heparin had been added vitro also were shorter with the electrical clot itmer than the automatic optical instrument. Prothrombin times done on normal and abnormal control plasmas and on a series of plasmas from patients on warfarin therapy showed no significant difference between the two methods.

Topics: Autoanalysis; Blood Chemical Analysis; Blood Coagulation Tests; Erythrocyte Aggregation; Factor V Deficiency; Factor X Deficiency; Hemophilia A; Hemophilia B; Heparin; Hydrogen-Ion Concentration; Hypoprothrombinemias; Liver Diseases; Optics and Photonics; Phospholipids; Prothrombin Time; Thromboplastin; Time Factors; Warfarin