Coagulation factor XI is a contaminant in intravenous immunoglobulin preparations.

A small number of thromboembolic events, including deep venous thrombosis and myocardial infarction, have been reported in patients receiving IVIG. These events have primarily occurred in patients receiving high-dose IVIG and have been attributed to an increase in blood viscosity. To test the hypothesis that a procoagulant might be present in IgG preparations, twenty-nine samples of intravenous immunoglobulin (IVIG) from eight different manufacturers were assayed for procoagulant activity. Twenty-six of these samples shortened the clotting time of factor XI-deficient plasma. Of these, fourteen samples had factor XI activities greater than 0.001 U/ml of normal pooled plasma. The remaining samples possessed less than 0. 001 U/ml of normal plasma activity. The procoagulant activity in these samples could be inhibited by an anti-factor XI polyclonal antibody, suggesting that the procoagulant activity was factor XI. The procoagulant activity increased in two samples after storage at 4 degrees C for 4 weeks, likely as a result of factor XIa autoactivation. Additionally, activity in some IVIG samples was able to directly activate factor IX, indicating that activated factor XI was present in these samples. Finally, the degree of factor XI(a) contamination in the samples was correlated with the manufacturer, suggesting that variations in the manufacturing process or source plasma affect the level of factor XI in the IVIG product. Because addition of small amounts of factor XIa to plasma can lead to production of significant amounts of thrombin, we suggest that factor XIa present in some IVIG preparations could contribute to the in vivo risk of thrombosis after IVIG therapy.

Deencryption of cellular tissue factor is independent of its cytoplasmic domain.

Tissue factor (TF) is a transmembrane molecule that, when exposed to plasma, is the key initiator of coagulation. Cellular TF activity is normally "encrypted", but treating cells with calcium ionophore (i.e. , ionomycin or A23187) increases ("deencrypts") TF activity without increasing TF mRNA or antigen expression. Deencryption results from both plasma membrane phosphatidylserine (PS)-dependent and -independent mechanisms; however, the nature of the PS-independent component is unclear. Since deencryption has been suggested to result from release of TF dimers on the cell surface, and since TF's cytoplasmic domain binds to actin-binding protein 280 and interacts with the cytoskeleton, we hypothesized that interactions with the cytoskeleton, through the cytoplasmic domain, play a role in mediating encryption/deencryption. We examined TF deencryption and the role of the cytoplasmic domain in the PS-independent component using baby hamster kidney (BHK) cells expressing full length TF (BHK-TF) or TF lacking its cytoplasmic domain (BHK-descyt) (Sorensen et al. (1999) J. Biol. Chem. 274, 21349). Both BHK-TF and BHK-descyt cells exhibited a dose-dependent, 1.5- to 10-fold increase in TF activity upon treatment with calcium ionophore, and this increase in activity was only partially blocked by annexin V. These results indicate that deencryption is not restricted to cells which naturally express TF and that the PS-independent component of deencryption is intact on cells transfected with either full length or truncated TF. Our results clearly indicate that deencryption is not dependent on an intact cytoplasmic domain in transfected BHK cells.