Measurement of activated factor IX in factor IX concentrates: correlation with in vivo thrombogenicity.

Current in vitro tests for thrombogenicity of FIX concentrates used for prothrombin complex concentrates (PCCs), are of little value when applied to high purity FIX (HP FIXs). In the present study, we have developed a chromogenic assay for activated FIX (FIXa) and evaluated its ability to predict in vivo thrombogenic potential of HP FIXs in a modified Wessler stasis model. Among the HP FIXs, only 1 out of 7 products had no detectable FIXa; this product also showed no in vivo thrombogenicity. In the other 6 products, FIXa content ranged from 0.15-1.2 U/1000 in FIX, and all showed some evidence of in vivo thrombogenicity, with mean thrombus scores ranging from 0.25-4. There was a significant positive correlation (r = 0.55, p < 0.02) between FIXa levels and in vivo thrombogenicity of HP FIXs. NAPTT data were not significantly correlated with the in vivo results and the TFCT also showed no direct correlation with the mean thrombus score. These results indicate that HP FIXs may still carry a small residual thrombotic risk and measurement of FIXa content of these products may be a better predictor of thrombogenicity than the current in vitro tests.

Identification of transforming growth factor-beta as a contaminant in factor VIII concentrates: a possible link with immunosuppressive effects in hemophiliacs.

In previous studies, we have shown that some, but not all low-, intermediate-, and high-purity factor VIII concentrates inhibit interleukin-2 (IL-2) secretion from phytohemagglutinin (PHA)-stimulated T lymphocytes. We now present evidence that this inhibitory action of concentrates is, at least in part, due to contamination with transforming growth factor-beta (TGF-beta). Originally identified in platelets, TGF-beta is a 25-kD homodimer that has been shown to be a natural and potent inhibitor of many immunologic responses. Using a specific bioassay, we have measured TGF-beta in various factor VIII concentrates. While some concentrates contained substantial amounts of the cytokine, there was a wide variation in concentrations of TGF-beta in different products. These levels correlated with the degree of inhibition of IL-2 secretion from T cells exhibited by each product (P = .0001). Noninhibitory concentrates contained no detectable TGF-beta. Addition of a specific TGF-beta 1 antibody reversed the inhibitory effect of some concentrates on IL-2 secretion by PHA-stimulated Jurkat T cells and interleukin-5 (IL-5)-induced proliferation of an erythroleukemic cell line. These findings suggest that TGF-beta contamination is a major contributory factor to the inhibitory activity of some factor VIII concentrates on cytokine secretion or activity, and may partially explain the reported immunosuppressive effects in recipients of these blood products.

Evaluation of factor VIII deficient plasmas.

Immunodepleted plasmas from Organon Teknika, Dade, Stago, Diagen and the Scottish National Blood Transfusion Service (SNBTS), and haemophilic plasma from Immuno were compared by several laboratories with haemophilic plasma from local donors as substrates in one-stage factor VIII assays. Five clinical plasma samples and four concentrates were assayed against British Standard plasma and International Standard concentrate. Potencies of all plasma samples were not significantly different from those with local haemophilic plasma for Immuno, Organon Teknika, Stago and SNBTS substrates. Dade differed from haemophilic on one sample and Diagen on three. Buffer blank times and slopes of standard lines were similar with all substrates. A positive drift between the beginning and end of the assay was found with the Immuno substrate and a negative drift with the Organon Teknika substrate. In the concentrate study results for all substrate plasmas were not significantly different from haemophilic on the intermediate purity and conventional high purity products. On the monoclonal and recombinant products, there was a tendency for the immunodepleted substrates to give lower potencies than the haemophilic, and significant differences were found with Dade and Stago on the monoclonal concentrate, and with Dade, Stago and Diagen on the recombinant concentrate. Overall, this study indicates that most commercially available substrate plasmas are suitable as replacements for locally collected haemophilic plasma in one-stage assays of clinical samples, and of intermediate purity and conventional high purity concentrates. For assays of very high purity concentrates (monoclonal and recombinant), haemophilic plasma is preferable as some immunodepleted plasmas give low results.

The behaviour of different factor VIII concentrates in a chromogenic factor X-activating system.

A chromogenic factor Xa generation method has been developed for comparing the co-factor activity of factor VIII concentrates at physiological factor VIII concentrations (1 iu/ml). In the presence of thrombin all concentrates gave similar rapid rates of factor Xa generation, but in the absence of thrombin there were major differences between the rates of Xa generation between different products. High purity products, particularly those prepared by monoclonal antibody purification from plasma and recombinant sources, gave more rapid Xa generation than most intermediate-purity products. There was a very strong correlation between the rate of Xa generation and the difference in factor VIII potency by one-stage and two-stage assays. These results suggest the possible presence of small amounts of activated factor VIII in some concentrates, but differences in von Willebrand factor content could also contribute towards the different rates of factor Xa generation observed.

Mechanisms of inhibition of T cell IL-2 secretion by factor VIII concentrates.

We have continued our previous study of the inhibitory effects of factor VIII concentrates on IL-2 secretion by T cells. Experiments with an extended range of products confirm our previous conclusion that some but not all low, intermediate and high purity concentrates possess inhibitory activity on IL-2 secretion. The inhibition occurs almost immediately after addition of factor VIII concentrate and it was not possible to adsorb inhibitory activity with activated or non-activated cells; this suggests that the mechanism of inhibition involves interference with early T cell activation events rather than simple blocking of cell surface components by inhibitory molecules. The inhibitory components were shown to reside in different molecular weight fractions of concentrates. A strongly inhibitory component of approximately 200 kD and a minor species of approximately 60 kD were identified in strongly inhibitory concentrates. Some products contained a dialysable inhibitory substance which is most likely a salt as it was also present in some formulation buffers. The proportions of the inhibitory components varied widely between products. We have found that the pattern of inhibition using in vitro systems reflects that observed using a mouse in vivo antigen challenge method. In addition we have shown that the previously reported concentrate mediated inhibition of lectin induced low affinity IL-2 receptor (CD25) is mainly a consequence of diminished IL-2 secretion rather than a 'direct' effect on CD25 expression. Considering the wide variation between products of the same purity group, caution should be exercised in drawing conclusions concerning the immunosuppressive effects of a particular type of concentrate in haemophilia patients from study with only one product from that group.