Assay of protein c in human plasma: Comparison of amidolytic, coagulation, and immunochemical assays

We studied functional protein C activity, both anticoagulant and amidolytic, as well as protein C antigen in 30 normal subjects, several members of a family with congenital protein C deficiency, 18 patients with severe preeclampsia, 27 patients with coronary heart disease, including 15 patients with myocardial infarction and 12 with angor pectoris, 20 patients on stable oral anticoagulant therapy (thrombotest values: 3–12%) and three patients with disseminated intravascular coagulation. Protein C values measured by the coagulant assay were compared to those obtained with amidolytic and immunochemical assays. In all the groups studied, the activity assays (amidolytic and coagulant) correlated significantly with each other as well as with the immunochemical assay. In patients on oral anticoagulant therapy the coagulant assay gave lower protein C values than amidolytic and immunochemical assays. A good correlation was found between immunological and amidolytic protein C assays (r=0.90, p < 0.001), immunological and coagulant protein C assays (r=0.93, p < 0.001), and amidolytic and coagulant protein C assays (r=0.95, p < 0.001) in all the samples studied without including the protein C values of patients on oral anticoagulant therapy. These results allow us to recommend the functional protein C coagulant assay in patients on stable oral anticoagulant therapy because only this assay evaluates the “in vivo” protein C function in these patients.     

Effects of (pre-)analytical variables on activated protein C resistance determined via a thrombin generation-based assay

The normalized activated protein C sensitivity ratio (nAPC-sr) determined with an assay that quantifies the effect of APC on thrombin formation initiated via the extrinsic coagulation pathway identifies hereditary and acquired defects of the protein C system. We investigated the influence of assay conditions (analytical variables) and plasma handling (pre-analytical variables) on nAPC-sr obtained with this APC resistance test. The effect of the analytical variables (CaCl2, phospholipid and APC concentrations and the concentration and source of tissue factor) was determined in pooled normal plasma. Inhibition of thrombin formation by APC was dependent on the APC concentration and was also affected by the tissue factor, Ca2+ and phospholipid concentrations. Thus, strict standardization of reactant concentrations is required to obtain reproducible nAPC-sr. Three different tissue factor preparations were compared by determining nAPCsr in plasma samples obtained from 90 healthy individuals. nAPC-sr were similar for all three tissue factor preparations although, compared with the noncommercially available tissue factor used in earlier studies, values determined with commercial tissue factor preparations showed larger variation. Pre-analytical variables, investigated in plasma of nine volunteers (3 normal individuals and 6 individuals with an APC-resistant phenotype) were: concentration of anticoagulant (3.2% vs. 3.8% trisodiumcitrate), time before processing of blood (0, 4 and 24 h), centrifugation speed, storage temperature of plasma (-20 degrees C vs. -80 degrees C) and sample thawing. Multiple linear regression analysis showed that only the citrate concentration affected the nAPC-sr, which was higher in samples collected in 3.2% trisodiumcitrate than in samples collected in 3.8% trisodiumcitrate.     

Quantitative determination of human protein C. Evaluation of a "fast" functional assay in comparison to a "traditional" functional and an immunological assay

A fast functional assay for protein C was evaluated and compared with a traditional functional and an enzyme linked immunosorbent assay in parallel for the same plasma samples derived from 43 healthy subjects, 12 patients with severe hepatic dysfunction, and 23 patients under stable oral anticoagulation. By all three test systems significantly lower levels of protein C were obtained in both groups of patients compared with normal subjects (p less than 0.0001). No significant between - assay differences were found in normal subjects and in patients with hepatic dysfunction; by correlation analysis coefficients higher than 0.8 were calculated between the measurements of the three tests. In patients under stable oral anticoagulation, however, the immunologic test yielded higher values than the traditional (p less than 0.05) and, more pronounced, the fast functional assay (p less than 0.0001); no or only borderline significant correlations between the results were found. In these patients protein C levels measured with the traditional functional assay were in the same range as the activity levels of factors II, VII, IX, and X, whereas the fast functional test yielded significantly lower levels. The presented results indicate that very similar protein C levels were obtained with both functional and the immunologic assay except in patients under oral anticoagulation.     

Anticoagulant dysfunction of human Arg352Trp-activated protein C caused by defective factor Va inactivation

The dysfunctional mutant R352W-protein C was found in two patients with venous thrombosis. The mutant R352A-protein C was constructed to define the contribution of charge/size of the residue at 352 on protein C (chymotrypsin numbering 187). Compared with wild type-protein C, R352W-protein C showed no difference in activation by thrombin-thrombomodulin or alpha-thrombin. However, R352W-activated protein C (APC) anticoagulant activity (aPTT assay) was reduced to approximately 65%. Although the catalytic efficiency of R352W-APC towards the oligopeptide substrate S-2366 was unperturbed, factor Va and R506Q-factor Va were not efficiently inactivated by R352W-APC compared with wild type-APC. R352A-APC showed reduced anticoagulant activity and reduced efficiency in factor Va inactivation and in factor VIIIa-inactivation in the presence of protein S. These observations suggest that the dysfunction of R352W-APC in factor Va inactivation may be one of the mechanisms leading to venous thrombosis in affected patients and that R352 plays an important role in the physiological functioning of APC.     

Phospholipid-bound tissue factor modulates both thrombin generation and APC-mediated factor Va inactivation

Hemostasis is initiated by tissue factor (TF) exposed on cellular phospholipid (PL) membranes, leading to thrombin generation. The binding of thrombin to thrombomodulin (TM), activates the protein C pathway, resulting in the inactivation of factors Va and VIIIa by activated protein C (APC) and a negative feedback effect on thrombin generation. A new assay system was developed for simultaneous measurement of thrombin and APC generation in defibrinated plasma induced by large unilamellar PL vesicles complexed with full-length recombinant TF (TF:PL). TF:PL preparations with a low TF concentration induced an initial rate of thrombin generation below 100 nM/min, and resulted in less thrombin formation in the presence of TM than in its absence. In contrast, TF:PL preparations with a high concentration of TF induced a higher rate of thrombin generation, and APC-mediated feedback inhibition did not occur, despite maximal APC generation. We used the same TF:PL surfaces to study factor Va inactivation by APC in a non-plasma reaction system, and found an inverse correlation between TF surface density and the rate of factor Va inactivation. This observation suggests a previously unrecognized hemostatic effect of TF, namely a non-enzymatic surface density-based inhibition of the anticoagulant effect of APC. In this model, high concentrations and surface density of TF exert complementary effects by promoting the regular procoagulant cascade and by inhibiting the protein C pathway, thereby maximizing hemostasis after vascular injury.     

Cell-derived microparticles circulate in healthy humans and support low grade thrombin generation

We determined the numbers, cellular origin and thrombin-generating properties of microparticles in healthy individuals (n = 15). Microparticles, isolated from fresh blood samples and identified by flow cytometry, originated from platelets [237 x 10(6)/L (median; range 116-565)], erythrocytes (28 x 10(6)/L; 13-46), granulocytes (46 x 10(6)/L; 16-94) and endothelial cells (64 x 10(6)/L; 16-136). They bound annexin V, indicating surface exposure of phosphatidylserine, and supported coagulation in vitro. Interestingly, coagulation occurred via tissue factor (TF)-independent pathways, because antibodies against TF or factor (F)VII were ineffective. In contrast, in our in vitro experiments coagulation was partially inhibited by antibodies against FXII (12%, p = 0.006), FXI (36%, p <0.001), FIX (28%, p <0.001) or FVIII (32%, p <0.001). Both the number of annexin V-positive microparticles present in plasma and the thrombin-generating capacity inversely correlated to the plasma concentrations of thrombin-antithrombin complex (r = -0.49, p = 0.072 and r = -0.77, p = 0.001, respectively), but did not correlate to prothrombin fragment F1+2 (r = -0.002, p = 0.99). The inverse correlations between the number of microparticles and their thrombin-forming capacity and the levels of thrombin-antithrombin complex in plasma may indicate that microparticles present in the circulation of healthy individuals have an anticoagulant function by promoting the generation of low amounts of thrombin that activate protein C. We conclude that microparticles in blood from healthy individuals support thrombin generation via TF- and FVII-independent pathways, and which may have an anticoagulant function.     

The functional significance of the autolysis loop in protein C and activated protein C

The autolysis loop of activated protein C (APC) is five residues longer than the autolysis loop of other vitamin K-dependent coagulation proteases. To investigate the role of this loop in the zymogenic and anticoagulant properties of the molecule, a protein C mutant was constructed in which the autolysis loop of the protein was replaced with the corresponding loop of factor X. The protein C mutant was activated by thrombin with approximately 5-fold higher rate in the presence of Ca2+. Both kinetics and direct binding studies revealed that the Ca2+ affinity of the mutant has been impaired approximately 3-fold. The result of a factor Va degradation assay revealed that the anticoagulant function of the mutant has been improved 4-5-fold in the absence but not in the presence of protein S. The improvement was due to a better recognition of both the P1-Arg506 and P1-Arg306 cleavage sites by the mutant protease. However, the plasma half-life of the mutant was markedly shortened due to faster inactivation by plasma serpins. These results suggest that the autolysis loop of protein C is critical for the Ca(2+)-dependence of activation by thrombin. Moreover, a longer autolysis loop in APC is not optimal for interaction with factor Va in the absence of protein S, but it contributes to the lack of serpin reactivity and longer half-life of the protease in plasma.     

EVALUATION OF A NEW SCREENING ASSAY PROC® GLOBAL FOR IDENTIFICATION OF DEFECTS IN THE PROTEIN C/PROTEIN S ANTICOAGULANT PATHWAY

In the present study a new assay, ProC® Global, globally estimating the activity of the main plasma components of anticoagulant protein C/protein S pathway, was evaluated with respect to test characteristics and its sensitivity in the detection of deficiency states of protein C and protein S and of increased aPCR. In the ProC® Global assay procedure protein C is activated in patient's plasma by an activator reagent (venom from agkistrodon contortrix). The extent of the prolongation of a sample's aPTT, caused by the activation of protein C, is taken as a measure for its anticoagulant capacity. Ninetyeight patients with one of the above mentioned defects were investigated. Decreased plasma protein C activity and increased aPCR were detected with a sensitivity of 1.0, while only 11 of 14 patients with decreased levels of free protein S antigen showed abnormal results in the ProC® Global assay (sensitivity=0.79). The test can be used in heparinized samples up to 1.0 anti Xa U/ml heparin (UFH and LMWH). When samples from patients on oral anticoagulant treatment are prediluted with factor V deficient plasma the test is sensitive for increased aPCR. © 1997 Elsevier Science Ltd     

A functional assay of protein C in human plasma

A functional assay for protein C in plasma is described in which barium eluates of plasma are incubated with bovine thrombin and rabbit thrombomodulin to activate protein C. The activated protein C solution is added to an activated partial thromboplastin time (APTT) system containing normal plasma and an APTT reagent (Dade ActinR). The prolongation of coagulation time after recalcification in this system is taken as a measure of the anticoagulant activity of protein C. When expressed as per cent of the value in pooled normal plasma, the results obtained by this method in 34 normal controls and in 3 untreated patients with protein C deficiency were very similar to those obtained by radioimmunoassay of protein C. In 2 patients with protein C deficiency and 23 patients without, all on dicoumarol or warfarin treatment, the anticoagulant activity of protein C was less than its antigen concentration. The day to day analytical coefficient of variation (SD/mean) was 12% at the 100% level (n = 12), and 10% at the 25% level (n = 12).     

Impairment of the protein C anticoagulant pathway in a patient with systemic lupus erythematosus, anticardiolipin antibodies and thrombosis

We have identified an inhibitor of the protein C anticoagulant pathway in the plasma of a patient with systemic lupus erythematosus and a history of recurrent deep vein thrombosis, fetal wastage, and seizures. The patient's plasma contained anticardiolipin antibodies as well as a weak lupus anticoagulant. Examination of this patient's plasma revealed normal levels of protein C and protein S antigen, normal levels of functional protein C, as well as essentially normal levels of every blood coagulation factor. In a modified prothrombin time assay, the activated protein C-mediated prolongation of the clotting time observed in normal plasma was not observed in this patient's plasma. Gel permeation chromatography of the patient's plasma revealed that the inhibitory material was a high molecular weight protein that coeluted with the IgM peak. The inhibitor did not appear to circulate as a complex with protein C, since the inhibitor could easily be separated from protein C during fractionation procedures, and did not interfere with the activation of protein C in plasma as assessed by a functional amidolytic assay. Our findings suggest that the recurrent thrombotic episodes observed in this patient may have occurred as a result of the patient's antiphospholipid antibody neutralizing specific phospholipids essential for the full expression of the anticoagulant activity of activated protein C.     

Multicenter evaluation of a chromogenic substrate method for photometric determination of prothrombin time

A multicenter study of a chromogenic substrate method for photometric determination of prothrombin time was conducted in order to evaluate its clinical application. Seven laboratories participated in the study using a total of 742 plasma samples from 417 patients on oral anticoagulant therapy, 261 healthy subjects and 64 patients with different diseases especially of the liver as well as 30 patients with hereditary deficiency of coagulation factors II, V, VII, X. The chromogenic PT method was compared to a standardized coagulometric PT assay which uses the same sensitive human placenta thromboplastin calibrated against international reference preparations. A high correlation of the prothrombin ratio values of the chromogenic and the coagulometric assay was obtained in 402 plasma samples (r = 0.940; y = 1.02x - 0.1). The study showed that the chromogenic PT reagent is sensitive to deficiency of the coagulation factors of the extrinsic pathway but not affected by heparin up to 1 IU/ml because of the heparin antagonist added. The precision (coefficient of variation) of the photometric method ranged between 0.6 and 3% (intraassay CV) and between 1.4 and 5.8 (interassay CV). The International Sensitivity Index (ISI) obtained for the used lot was 1.09. The therapeutical range in percentage activity for patients in a stable phase of an anticoagulant therapy was found to be from 15 to 27 percent of normal. The results of the clinical evaluation proved the good comparability of the new chromogenic PT test with coagulometric methods, its high factor sensitivity, good reproducibility and easy performance.     

A simple method for determination of the factor VII-phospholipid complex using Normotest

We report here a highly significant positive correlation observed when the factor VII-phospholipid complex (the phospholipase-C sensitive component of factor VII) in plasma was tested in a specific factor VII system and in Normotest (p less than 0.0001). The Normotest system, which is sensitive to variations in coagulation activity within the normal range, was not influenced by phospholipase C when the enzyme was added immediately before the start of the coagulation assay. Normotest is well suited for determination of the factor VII-phospholipid complex in plasma.     

A new method for the estimation of protein C by ELISA

A new solid phase enzyme-linked immunosorbent assay (ELISA) was developed for the quantitation of human protein C antigen. Anti-protein C F(ab′)2 fragments were adsorbed to polystyrene plates. The binding of serial dilutions of control or test plasma, containing protein C, was detected by incubation with peroxidase-labeled anti-protein C-IgG followed by the addition of hydrogen peroxyde and 0-phenylenediamine. This ELISA is specific, sensitive (detection limit : 0.02 %) and accurate (variation coefficient : 3 to 10 %). When results are compared to those obtained by the Laurell technique (electroimmunodiffusion, EID), the correlation coefficient is 0.95 in all tested plasmas.

Protein C antigen was measured by ELISA and EID in plasma from 40 controls, 14 patients with congenital protein C deficiency, 15 patients with liver cirrhosis and 40 dicoumarol-treated cases. In normal plasma, protein C ranged from 70 to 126 %. In congenital deficiency, protein C was between 35 and 58 % in 13 cases and 9 % in one of them. In patients with liver cirrhosis and dicoumarol-treated cases, levels of protein C antigen were compared to those of other vitamin K dependent factors, i.e. Factors II and IX measured by EID and Factor X assayed by EID and ELISA. In liver cirrhosis, the amount of protein C was significantly lower than that of Factors II, IX and X. In short-term and long-term dicouma-rol-treated patients, the highest correlation (r = 0.72) was observed between protein C and Factor X levels. In the plasma of patients undergoing oral anticoagulant therapy, protein C decreased more rapidly than Factors X or II and migrated in presence of calcium as a double peak, one with a normal mobility and one more anodal corresponding to the non carboxylated form of protein C.     

Factor VIII lability, protein C and other vitamin K-dependent proteins

The stability of factor VIII was studied in plasmas from patients on long-term warfarin therapy. The percent residual factor VIII activity (F.VIII:C) after incubation at 37 degrees C for 4 hr was higher in warfarinized patients than in normal subjects; 76.9 +/- 10.8% (mean +/- SD) of the initial F.VIII:C in the patients versus 61.6 +/- 5.8% in normal subjects (p less than 0.001). On the whole, neither protein C nor vitamin K-dependent coagulation factors except factor VII activity (F.VII:C) correlated with the residual F.VIII:C. There was a negative and weak correlation between the residual F.VIII:C at 4 hr and either the initial F.VIII:C or F.VII:C. Another experiment using protein C depleted plasma showed a relatively enhanced stability of F.VIII:C in the protein C deficiency. These results indicate that factor VIII is more stable in warfarinized plasma, and that protein C and vitamin K-dependent coagulation factors are not the sole, main factor responsible for such a phenomenon.     

Enzyme-linked immunosorbent assay of human factor VII based upon a monoclonal antibody that recognizes the native conformation of the protein.

An enzyme-linked immunoassay (ELISA) was developed for measuring human factor VII antigen using two monoclonal antibodies, one of them reacting only with fully carboxylated factor VII. This assay permits to measure factor VII antigen in concentrations ranging from 0.78 to 100 ng/ml, with within- and between-assay coefficients of variation of less than 7%. In 53 normal subjects, 32 patients with liver cirrhosis, 21 pregnant women and 53 patients on oral anticoagulant therapy the plasma levels of FVII antigen were very similar to those of factor VII coagulant activity measured with a bioassay. The ELISA also gave very similar values of factor VII antigen in plasma and in serum, and in plasma before and after exposure to cold, indicating that the assay is not affected by factor VII activation. In five of 8 patients with severe congenital deficiency of factor VII values of factor VII antigen were higher than those of factor VII activity. The close concordance of factor VII values obtained by ELISA and bioassay in the majority of plasmas, including those from patients on oral anticoagulant therapy, indicates that the assay measures native factor VII and can perhaps replace the bioassay systems in clinical conditions associated with normal or high levels of factor VII.     

AN IMPROVED TEST TO IDENTIFY aPC-RESISTANT FACTOR V-LEIDEN

A functional clotting assay was recently reported to detect the factor V-Leiden mutation (R506Q) in patients receiving oral anticoagulants and in patients with Lupus Anticoagulant inhibitor. The original assay (Dahlback) to detect resistance to activated protein C (aPC-resistance) frequently gave unreliable findings in these patients. The change in the method is the use of bovine thromboplastin in a PT-derived assay, with a 1:10 sample dilution. In these conditions a reference normal plasma gives a prolongation of more than 35 seconds, while samples with a heterozygous or homozygous mutation give a prolongation respectively of 10–18 seconds or less 2 seconds. The test is easily automated and quickly performed on ACL/3000, and the reproducibility is good. © 1997 Elsevier Science Ltd     

Evaluation of coagulometric assays in the assessment of protein C anticoagulant activity; variable sensitivity of commercial APTT reagents to the cofactor effect of protein S

In vivo expression of protein C activity is dependent on the availability of the activated protein C (APC) cofactor protein S. In the clinical laboratory, measurement of protein C anticoagulant activity is mostly performed in modified APTT assays. We have evaluated 13 commercial APTT reagents for their sensitivity to the cofactor effect of protein S by comparing APC-dependent clotting time prolongations in normal plasma and in protein S depleted plasma. In normal plasma, the sensitivities of the APTT reagents to the anticoagulant effect of APC were markedly different and correlated with the sensitivity of reagents to factor V and VIII. Reagents containing soy phosphatides appeared more sensitive than reagents containing phospholipid of animal origin. Analysis of dose-response curves obtained in normal plasma distinguished one group of reagents showing clotting time prolongations linearly related to the APC concentrations, a second group showing a log-linear relationship and a third group showing a log-log relationship. In protein S depleted plasma, sensitivity of APTT reagents to APC was in general proportional to that observed in normal plasma. However, for some reagents dose-response curves were qualitatively different in normal and in protein S depleted plasma. With all the APTT reagents, APC-dependent clotting time prolongations corresponding to 30-80% of APC anticoagulant activity observed in normal plasma, were observed in protein S depleted plasma. At variance, in a modified Xa one-stage clotting assay, negligible clotting time prolongations were observed in protein S depleted plasma, indicating that over 90% of the APC anticoagulant activity was protein S dependent in this assay system. Dilution of a relative insensitive APTT reagent effectively increased its sensitivity to the cofactor effect of protein S, suggesting that different phospholipid content and/or composition might be responsible for the different sensitivity of APTT reagents to protein S. These results question the validity of APTT based assays for the identification of qualitative protein C abnormalities with defective interaction with protein S.     

Plasma lipoproteins, hemostasis and thrombosis

Regulation of hemostasis and thrombosis involves numerous plasma factors that contribute to procoagulant and anticoagulant pathways. Lipid-containing surfaces provide sites where both procoagulant and anticoagulant enzymes, cofactors and substrates are assembled to express their activities. Plasma and lipoproteins can contribute to either procoagulant or anticoagulant reactions. Procoagulant lipids/lipoproteins include triglyceride-rich particles in plasma and oxidized low density lipoprotein (LDL) which can accelerate activation of prothrombin, factor X and factor VII. Potentially anticoagulant lipids and lipoproteins, each of which enhances inactivation of factor Va by activated protein C, include phosphatidylethanolamine, cardiolipin, the neutral glycosphingolipids glucosylceramide and Gb3 ceramide (CD77), and high density lipoprotein (HDL). Remarkably, treatment of hyperlipidemia with statins not only lowers lipids but also provides antithrombotic effects whose mechanisms remain to be clarified. We hypothesize that procoagulant and anticoagulant lipids and lipoproteins in plasma may contribute to a Yin-Yang balance that helps influence the up-regulation and down-regulation of thrombin generation.     

Protein C in acute stroke

The plasma concentrations of protein C, an anticoagulant protein, and fibrinopeptide A were measured in 37 patients with acute hemispheric stroke and in age-matched controls with nonvascular neurologic diseases. In 11 stroke patients who died within 15 days after the onset (nonsurvivors) protein C antigen concentration on admission was lower than in the control group (p less than 0.005), with a mean value of 63% of the concentrations found in the 26 survivors (p less than 0.001). The difference in protein C concentrations was not associated with different prothrombin time ratios and serum albumin concentration in survivors and nonsurvivors of stroke and was independent of the size of the cerebral lesion. Increased fibrinopeptide A concentration on admission was found in all stroke patients (p less than 0.001), but it was higher in nonsurvivors than in survivors (p less than 0.01), suggesting that lower protein C concentrations in nonsurvivors might be due to increased thrombin-dependent protein C activation. In survivors, protein C concentration was slightly but significantly higher than in controls (p less than 0.05) and was unchanged 2 months after stroke, a time when fibrinopeptide A concentrations had returned to normal. These results show that protein C is involved in the hemostatic derangement caused by stroke and provide a rationale for clinical trials evaluating the therapeutic supplementation with protein C of patients with acute ischemic stroke.     

The Factor V (Leiden) test: evaluation of an assay based on dilute Russell Viper Venom Time for the detection of the Factor V Leiden mutation

In the present study a new clotting assay for the detection of an increased resistance of coagulation factor V against degradation by activated protein C (Factor V Leiden mutation, FVLM) was evaluated. The Factor V (Leiden) Test (Gradipore, North Ryde NSW, Australia) is based on the dilute Russell Viper Venom Time (DRVVT), which is prolonged when the plasma sample is preincubated with dilute whole Agkistrodon contortrix contortrix venom for activation of protein C (PC). In contrast to the DRVVT based global assay, Protein C Pathway Test (Gradipore, North Ryde NSW, Australia) this new assay is expected to be more specific for FVLM because of optimized amounts of the venom. The test result is expressed as the ratio between the DRVVT with and without addition of the venom. The following precision values were found: intraassay coefficient of variation (CV): 5.53% (n=20) in the normal range, 4.30% (n=20) in the pathological range; interassay CV: 6.90% (n=10) and 7.64% (n=10), respectively. A normal range (5th to 95th percentile) of 2.12 to 3.08 was calculated from 50 healthy controls. A ratio below 2.12 was found in all samples from patients with FVLM (n=21), in 9 of 12 patients with PC, in 0 of 6 with protein S (PS), and in 0 of 4 with antithrombin (AT) deficiency. There was, however, a good discrimination between carriers of the FVLM (highest ratio 1.44) and patients deficient in PC (lowest ratio 1.59), in particular when samples were prediluted with factor V deficient plasma FVDP (1.16 vs. 1.96, respectively). Predilution of samples with FVDP caused a clear discrimination between controls and patients deficient in PC, PS, AT, and FVLM-positive individuals and also in patients on oral anticoagulant treatment. Our data show that the Factor V (Leiden) Test discriminates well between carriers of the FVLM and healthy controls or patients deficient in PC, PS, and AT. Individuals presenting values between the lower cutoff of controls and the range in which FVLM-positive individuals are found are highly suspicious for protein C deficiency.