Monocyte tissue factor response is decreased in patients with hyperlipidemia

Monocytes are potent regulators of blood coagulation through the expression of tissue factor (TF) on stimulation and of tissue factor pathway inhibitor (TFPI), a selective inhibitor of TF pathway. As hyperlipidemia can modify some monocyte functions, we compared the TF and TFPI expression by circulating monocytes and the plasma TFPI levels between 65 healthy normolipemic controls and 38 nontreated hyperlipemic patients. TF and TFPI relationships with plasma lipoproteins are also examined. TF and TFPI expression were evaluated in peripheral mononuclear cells after isolation from blood by density gradient centrifugation and after short culture with or without lipopolysaccharide (LPS). TF and TFPI activity and antigen were measured in mononuclear cell lysates using amidolytic assay and enzyme-linked immunosorbent assay, respectively. TFPI activity and antigen were measured in plasma using the same methods. Plasma factor VII (FVII) activity and antigen were also determined. LPS-stimulated monocyte TF activity and antigen were lower in hyperlipidemic patients than in controls (0.0001相似文献   

Tissue factor pathway inhibitor (TFPI) levels in the plasma and urine of children with meningococcal disease

Tissue factor pathway inhibitor (TFPI) is a potent inhibitor of the TF-dependent coagulation system. In meningococcal disease, up-regulation of tissue factor expression on blood monocytes and possibly on endothelial cells has the potential to trigger the activation of the TF-dependent pathway of coagulation. Intravascular coagulation is considered to be a major pathogenic factor in meningococcal disease. We postulated that imbalance between TF expression and TFPI concentration might lead to uncontrolled coagulation in meningococcal disease. The aim of this study was to assess the levels of total TFPI in the plasma of patients with meningococcal disease and assess whether increased leaking of the TFPI was occurring. TFPI antigen levels and activity were measured in the plasma of 54 patients with meningococcal disease, and 13 healthy control children. TFPI antigen level were also determined in the urines of 14 of the 54 and 9 healthy control children. Plasma TFPI activity was reduced in the meningococcal diseased patients (mean of 0.503 +/- 0.341 U/ml; control, 1.010 +/- 0.199 U/ml: p <0.0001), as was the TFPI antigen levels (mean of 54.85 +/- 35.05 ng/ml; Control, 94.51 +/- 11.44 ng/ml; p <0.0001). In contrast, TFPI antigen levels were increased in the urine of these patients when compared to the levels found in the urine of the healthy control children (mean of 12.96 +/- 5.392 ng/mmol creatinine; Control, 0.239 +/- 0.191 ng/mmol creatinine; p <0.035). A lack of correlation between TFPI-activity and TFPI-antigen plasma levels was observed (r = 0.002, p = 0.85). This data is consistent with the hypothesis that in meningococcal disease there is increased inactivation of plasma TFPI by the up regulation of tissue factor expression but in addition increased clearance of TFPI in urine is occurring.     

Discrepancy between tissue factor activity and tissue factor expression in endotoxin-induced monocytes is associated with apoptosis and necrosis

Tissue factor (TF), the main initiator of blood coagulation, contributes to the manifestation of disseminated intravascular coagulation following septic shock in meningococcal infection. Since a direct relationship between disease severity and lipopolysaccharide (LPS) concentration in the circulation has been shown, we hypothesized that the procoagulant and cytotoxic effects of endotoxin also in vitro were related to its concentration. In vitro studies, however, have frequently used much higher LPS concentrations than those observed in clinical samples. Using elutriation-purified human monocytes, we observed that LPS up to 1000 ng/ml exerted a concentration-dependent increase in TF activity (tenase activity, fibrin formation in plasma). Although there was a dose-dependent increase in TF activity, there was not a concomitant increase in TF expression at LPS concentrations above 1 ng/ml (flow cytometry, Western blotting, TF mRNA). Flow cytometry revealed that this discrepancy between TF activity and TF expression at endotoxin concentrations above 1 ng/ml, coincided with an LPS dose-dependent increase in cell surface phosphatidylserine (PS), considered to promote coagulation. The increased PS expression was associated with an increased number of 7-AAD-positive cells indicating cell death. We conclude that enhancement of monocyte procoagulant activity in vitro by high concentrations of LPS may result from increased PS exposure due to apoptosis and necrosis. Therefore, the LPS concentrations used to examine monocyte procoagulant activity in vitro, should be carefully chosen.     

Hemostatic markers with bolus versus prolonged heparin after carotid artery stenting

BACKGROUND: The evolving technique of carotid stenting (CS) requires optimal antithrombotic strategies to reduce periinterventional thromboembolic risk. In animal models of balloon injury, tissue factor (TF) was shown to be the major procoagulant of the atherosclerotic plaque mediating prolonged procoagulant activity. METHODS: We analyzed TF and TF-dependent hemostatic markers before and 2, 6 and 24 h after CS with two antithrombotic drug regimens. Group A (n=20) received prolonged unfractionated heparin (UFH) for 18-20 h starting at intervention next to aspirin and thienopyridine. In group B (n=16), single bolus UFH was administered next to combined antiplatelet therapy. Natural anticoagulants were determined at baseline. RESULTS: Patients with symptomatic and asymptomatic cerebrovascular disease did not differ in plasma TF levels. Furthermore, no statistically significant difference for TF, TFPI/Xa-complex and prothrombin fragment F1.2 was observed between bolus and prolonged heparin treatment. No significant change was found in time course for these parameters. Two patients (5.5%; one in each treatment group) suffered periinterventional minor stroke associated with increased levels of F1.2 and TFPI/Xa-complex. Both were resistant to activated protein C (APC ratio<1.9) due to heterozygous factor V Leiden mutation. CONCLUSIONS: No significant activation of the TF pathway was seen with both antithrombotic regimens suggesting that single bolus UFH combined with antiplatelet therapy is generally sufficient to control TF-dependent procoagulant activity after CS. However, patients with resistance to activated protein C may be at increased periinterventional stroke risk.     

Tissue factor pathway inhibitor on circulating microparticles in acute myocardial infarction

In acute myocardial infarction (AMI), increased Tissue Factor (TF) expression on circulating monocytes and microparticles (MP) may contribute to thrombotic events. Because surfacebound Tissue Factor Pathway Inhibitor-1 (TFPI) inhibits TF activity on monocytes and endothelial cells decreased TFPI expression may reinforce the procoagulant activity of circulating MP. Aim of the study was to analyze TFPI expression and TF activity after stenting and thrombolysis inAMI. Thirty-nine patients of a randomized study comparing intravenous thrombolysis (n=19) and stenting (n=20) were included. Before and after therapy blood samples for analysis of MPs, TF antigen and activity, prothrombin fragment F1+2 and D-dimer were obtained. TFPI expression on TF positive MPs was decreased after thrombolysis but not after stenting. In contrast, TF plasma levels and TF positive MP remained unchanged in both treatment groups. After thrombolysis increased D-dimer and F1+2 plasma concentrations indicated activation of fibrinolysis and coagulation. Significance of MPTFPI for inhibition of TF activity was measured using inhibitory TFPI antibodies. Membrane-associated TFPI inhibited TF activity on circulating MPs. After thrombolysis inhibition of TF activity by TFPI was decreased as compared to stenting. Correlation of circulating TF with F1+2 only after thrombolysis, suggests a role for TF-induced activation of coagulation after thrombolysis. Enhanced TF activity on circulating MPs in AMI is inhibited by endogenous surface-boundTFPI. After thrombolysis but not after stenting MPTFPI is degraded and may induce thrombin generation due to unopposed tissue factor activity. Anti-TF therapies during thrombolysis may reduce thrombin generation in AMI.     

Acute release of tissue factor pathway inhibitor after in vivo thrombin generation in baboons

Tissue factor pathway inhibitor (TFPI), the major downregulator of the procoagulant activity of tissue factor (TF), is synthesised by endothelial cells (EC) and acutely released in vitro after thrombin stimulation. Expression of TF on EC and subsequent thrombin generation occurs in vivo during sepsis or malignancy, inducing disseminated intravascular coagulation (DIC). The present study investigates the changes in plasma TFPI in relation to markers of in vivo thrombin generation induced by injection of factor Xa (FXa)/phospholipids in baboons at dosages leading to partial (48%) or complete fibrinogen depletion. The plasma concentrations of thrombin-antithrombin III (TAT) and fibrinopeptide A (FpA), as markers of in vivo generation of thrombin, were strongly enhanced after injection of FXa/phospholipids. TFPI levels, whether measured as antigen or activity, increased significantly in both treatment groups within few minutes, and were dependent on the dose of FXa/phospholipids. Significant positive correlations between plasma levels of TFPI and of TAT or FpA were observed. Altogether, our results indicate that experimentally induced in vivo generation of thrombin causes the acute release of TFPI, high-lighting a possible novel function of thrombin in downregulation of the coagulation process, potentially relevant for the outcome of DIC.     

Do antiphospholipid antibodies interfere with tissue factor pathway inhibitor?

This study was conducted to investigate whether antiphospholipid antibodies (APA) can interfere with the phospholipid-dependent inhibition of coagulation exerted by tissue factor pathway inhibitor (TFPI). Eleven patients with APA and eleven healthy controls matched for age and gender were enrolled. Blood samples were drawn before and 5 minutes after an intravenous injection of unfractionated heparin 5000 IE, which is known to cause TFPI release in healthy individuals. The preheparin samples showed significantly higher TFPI free antigen levels in the APA positive patients than in the controls (21.7 vs. 14.2 ng/ml, p = 0.03). TFPI activity as measured in a chromogenic substrate assay also was higher in patients, but this difference was not statistically significant (1.13 vs. 1.01 U/ml, p = 0.2). The TFPI levels showed a considerable rise in both patients and controls after heparin injection. In both assays, the postheparin levels were significantly higher in patients than in controls (TFPI antigen: 179 vs. 153 ng/ml, p = 0.05; TFPI activity: 3.26 vs. 2.51 U/ml, p = 0.03). A modified diluted prothrombin time assay (dPT) was used to measure TFPI anticoagulant activity. In this assay, samples from the patients with the strongest effect of lupus anticoagulants (LAs) on preheparin coagulation times showed little or no increase after heparin injection. This result may reflect an inhibition of TFPI anticoagulant activity by strong LAs. In conclusion, we have found that patients with APA have higher TFPI amidolytic activity/antigen level both before and after heparin stimulation of TFPI release. These observations do not explain the higher thrombotic risk in these patients but may reflect an upregulated tissue factor activity, which has been demonstrated in these patients. TFPI anticoagulant activity, however, as measured in a dPT assay, may be inhibited by strong LAs.     

A simplified and low-cost one-stage chromogenic assay for tissue factor dependent procoagulant activity of endothelial cells

We developed a sensitive tissue factor (TF) chromogenic assay on a limited number of endothelial cells (EC), performed in microtiter plates, and which uses normal pooled human plasma instead of purified concentrates as a source of coagulation factors. Primary cultures of human umbilical vein EC (HUVEC), both unstimulated and stimulated by lipopolysaccharide (LPS), were incubated with 50 μl of diluted normal human plasma (NHP) and 50 μl of Factor Xa-specific chromogenic substrate (CBS 31–39, Stago, France). Hirudin was added at 4 U/ml to the plasma/CBS 31–39 mixture to inhibit thrombin generation. Optical densities were read at 405 nm and corresponding amounts of generated factor Xa were expressed in mU Xa/well using a standard curve established with purified human Factor Xa. The following parameters were then defined: the number of EC to plate (10⁴ EC/well of a 96-well plate), the plasma-test dilution (1:20), the concentration of CBS 31–39 (0.50 mM) and the incubation time of reagents with EC (2 hours). The procoagulant activity (PCA) measured was only dependent on TF since it was no longer detectable either when FVII-deficient plasma was tested instead of normal human plasma or when PCA assays were performed in the presence of a blocking anti-human TF monoclonal antibody. This method allowed detection of a TF-dependent PCA on as few as 1000 EC per well. In addition, TF expression equal to 50% of maximal values was measured with LPS concentrations as low as 1 ng/ml, supporting the high sensitivity of the assay.     

Whole blood tissue factor procoagulant activity remains detectable during severe aplasia following bone marrow and peripheral blood stem cell transplantation

Using a novel whole blood assay, we recently demonstrated that tissue factor procoagulant activity (TF PCA) is present in normal individuals. Preliminary experiments suggested that this activity is localized in the mononuclear cell fraction. Postulating that whole blood TF PCA would therefore be undetectable when monocytes and neutrophils are absent from peripheral blood, we assayed TF PCA during the peri-transplant period in 15 consecutive patients undergoing allogeneic (n = 12) or autologous (n = 3) bone marrow transplantation (BMT) or peripheral blood stem cell transplantation (PBSCT). Baseline (pre-transplant) mean TF PCA was higher in patients compared to normal controls (P <0.005). Unexpectedly, although TF PCA during the period of profound aplasia was significantly reduced compared to baseline (p <0.05), fully 55% of the initial activity remained detectable. During the engraftment phase, TF PCA returned to pre-transplant levels, with a linear correlation between monocyte counts and TF PCA (r = 0.63). In contrast to normal whole blood, incubation of aplastic samples with E. Coli lipopolysaccharide ex vivo failed to induce TF PCA. Throughout the period of study--but especially during the aplastic phase--the absolute number of circulating endothelial cells (CECs) that were TF antigen-positive was increased compared to normals (P <0.001). However, removal of these cells from whole blood samples failed to significantly diminish total TF PCA indicating that CECs alone could not account for the detectable TF PCA during aplasia. We conclude that neither circulating mature myelo-monocytic cells nor endothelial cells can account for all the functionally intact TF in peripheral blood. Further studies are needed to identify the other source(s) of TF PCA.     

Plasma tissue factor antigen in localized prostate cancer: distribution, clinical significance and correlation with haemostatic activation markers

Tissue factor (TF) is involved in cancer growth and metastasis, and haemostatic abnormalities are found in most patients with advanced malignancies, including prostate cancer (PC). Because anti-haemostatic agents are increasingly screened for their potential to prolong survival in tumor patients, a detailed characterization of haemostatic markers in selected cancer subtypes and clinical stages is warranted. In this study, we measured preoperative plasma TF antigen in a large cohort of patients with localized PC and correlated its levels with markers of coagulation and platelet activation, prostate-specific antigen (PSA), and histopathological findings to explore its potential as a prognostic marker in this tumor entity. Out of 140 patients, 19% and 23% had plasma TF antigen levels of <40 pg/ml (low-TF) and >200 pg/ml (high-TF), respectively, which was substantially higher than in 42 healthy male controls. Patients also had low-grade systemic coagulation activation as evidenced by elevated D-dimer, F1 + 2, and PAP plasma levels. Furthermore, similar to sP-selectin and sCD40L antigen, flow cytometric analysis of platelet-derived microparticles in plasma revealed significantly increased numbers in high-TF as compared to low-TF patients and controls. Whereas elevated D-dimer was associated with larger and less differentiated tumors, preoperative plasma TF antigen levels (median [IQR]) were higher in patients with (161 pg/ml [100-236]) than in those without recurrent PC (105 pg/ml [52-182]), as indicated by a serum PSA of >0.1 ng/ml during ambulatory follow-up. In patients with localized PC, preoperative plasma TF antigen levels correlate with platelet activation in vivo and may indicate an increased risk for recurrent disease.     

Relevance of tissue factor and tissue factor pathway inhibitor for hypercoagulable state in the lungs of patients with idiopathic pulmonary fibrosis

We investigated the role of tissue factor (TF) and tissue factor pathway inhibitor (TFPI) in the lungs of patients with idiopathic pulmonary fibrosis (IPF). Bronchoalveolar lavage (BAL) fluid was obtained from 22 patients with IPF, and the levels of TF and TFPI antigen were measured by ELISA. The TF and TFPI levels in BAL fluid supernatant were significantly higher in IPF patients than in normal controls. In addition, both levels were significantly higher in advanced cases than in nonadvanced cases. There was a significant correlation between the TF and TFPI levels. Localization of TF and TFPI antigens was investigated by immunohistochemical staining. Both antigens were mainly localized in hyperplastic cuboidal epithelial cells, suggesting that the widespread distribution of these cells contributed to the increase of TF and TFPI antigen levels in the lungs of IPF patients. To assess whether TF activity is counterbalanced by TFPI in the lungs of IPF patients, we examined procoagulant activity and TF activity. It was found, however, that both procoagulant and TF activities were significantly higher in the BAL fluid supernatant of IPF patients than in that of normal controls, which suggested that TFPI was actually increased, but the increase was insufficient to counterbalance TF, leading to the development of a hypercoagulable state in the lungs of IPF patients.     

Monocyte IL-10 produced in response to lipopolysaccharide modulates thrombin generation by inhibiting tissue factor expression and release of active tissue factor-bound microparticles

Lipopolysaccharide (LPS)-stimulated monocytes are known to have a procoagulant effect. This property is currently explained by the fact that monocytes, in response to LPS, can express tissue factor (TF) and undergo a process of membrane microvesiculation. Interleukin-10 (IL-10) has been shown to downregulate TF expression and inhibit procoagulant activity (PCA). In order to further characterize the inhibitory effect of IL-10 on LPS-induced PCA, we used the integrated system of analysis of kinetics of thrombin generation in normal plasma (thrombinography). For this, we developed an original method of elutriation allowing to obtain a highly purified monocyte preparation, under endotoxin-free conditions. Thrombin generation was measured using a highly sensitive and specific fluorogenic method which we adapted to inhibit the contact factor pathway. Results show that recombinant human IL-10 decreased the kinetics of thrombin generation in a dose-dependent manner. Furthermore, the inhibition of endogenous IL-10 released by monocytes in response to LPS is associated with an increase in the kinetics of thrombin generation. We demonstrated that this effect was a consequence of the up-regulation of TF expression and TF-bound microparticle release. In conclusion, we report that IL-10 can regulate thrombin generation in conditions close to physiology as allowed by thrombinography, and that endogenous IL-10 regulates TF expression and release of active TF-bound microparticles by a negative feed back loop through IL-10 receptor alpha.     

Increased risk of gestational vascular complications in women with low free tissue factor pathway inhibitor plasma levels out of pregnancy

Tissue factor pathway inhibitor (TFPI) plays a crucial role in haemostasis by regulating TF-induced initiation of coagulation. Since it is expressed by endothelial and trophoblastic cells, TFPI is of particular importance at the placental level and might be involved in the occurrence of gestational vascular complications (GVC). In the present study, we investigated plasma free TFPI antigen in four groups of women: healthy non-pregnant women without history of pregnancy complications; women at the beginning (<12 weeks) and women during the third trimester of a normal pregnancy; women with late pregnancy complications (pre-eclampsia / HELLP syndrome, intra-uterine fetal death, fetal growth retardation) at the time of obstetrical event and/or at distance from pregnancy. In normal pregnancy, TFPI increased between first trimester and delivery (median 5.0 ng/ml vs. 7.1 ng/ml; p<0.0001) but remained lower than in non-pregnant controls (median 8.2 ng/ml; p<0.0001). In patients, when measured concomitantly to the obstetrical event, TFPI showed no difference with normal late pregnancy levels. In contrast, at distance from pregnancy, in the absence of any hormonal influence, TFPI was significantly lower than in non-pregnant controls (median 5.9 vs. 8.2ng/ml, p < 0.0001). After categorisation into quartiles, an inverse dose-effect relationship was demonstrated between TFPI categories recorded apart from pregnancy and GVC risk, with a crude odds ratio of 43.5 (95% confidence interval 8.2-230) for patients with TFPI values in the lowest quartile (< 5.7 ng/ml). In conclusion, low free TFPI at distance from pregnancy appears to be a strong indicator of GVC risk.     

Discordant expression of tissue factor antigen and procoagulant activity on human monocytes activated with LPS and low dose cycloheximide.

The mechanisms underlying the superinduction of procoagulant activity by cycloheximide (CHX) on LPS-activated human monocytes have been investigated. Tissue factor (TF) activity of intact, viable cells was quantitated with a plasma recalcification assay and assays using chromogenic substrates specific for thrombin and factor Xa (FXa). TF antigen was measured simultaneously by immunocytochemical staining and immunoblotting with an anti-TF monoclonal antibody (MAb). Peripheral blood mononuclear cells (PBMC) activated with LPS in the presence of low dose CHX expressed more TF activity (approx. 100% increase) than cells activated with LPS alone. However, TF antigen levels were decreased approximately 70% by CHX. This discordant relationship was due primarily to differences in rates of activation of factor X (FX); LPS/CHX-treated PBMC activated nearly twice as much FX as LPS-treated cells (2.19 +/- 0.37 versus 1.10 +/- 0.21 ng FXa/10(6) PBMC/min, respectively). These studies indicate that TF cofactor activity on LPS/CHX-treated monocytes was approximately 7 times greater than that present on LPS-treated cells. Increased TF functional activity may be due to CHX-induced alterations in the type and content of phospholipids (PL) in the cell membrane. Results showed that exogenous mixed PL markedly increased TF activity on LPS-activated monocytes, but not on LPS/CHX-activated cells, without increasing TF antigen levels or altering cell viability. Membrane alterations may occur on monocytes in certain pathological or iatrogenic conditions resulting in a highly active form of TF in vivo.     

Local tissue factor pathway inhibitor release in the human forearm

Nineteen healthy men received unilateral brachial artery infusions of either unfractioned heparin (0.3-100 IU/min), saline or the endothelium-dependent vasodilators substance P (2-8 pmol/min) and bradykinin (100-1000 pmol/min), and the endothelium-independent vasodilator sodium nitroprusside (2-8 micro g/min). Heparin caused a dose-dependent increase in plasma TFPI concentrations in both arms (ANOVA, p <0.0001). Estimated net forearm TFPI release was 7 +/- 16, 29 +/- 20 and 138 +/- 72 ng/100 mL tissue/min during 10, 30 and 100 IU/min of heparin respectively (ANOVA, p <0.0001). Compared to the systemic circulation, the forearm sensitivity to heparin induced TFPI release was 3.6-fold lower (166 +/- 67 ng/IU vs. 596 +/- 252 ng/IU: t-test, p = 0.004). Substance P, bradykinin and sodium nitroprusside all caused substantial dose-dependent increases in blood flow (ANOVA, p <0.001 for all) without affecting plasma TFPI concentrations. There are important regional differences in endothelial TFPI release, with the forearm circulation being relatively insensitive to heparin.     

Circulating monocytes mirror the imbalance in TF and TFPI expression in carotid atherosclerotic plaques with lipid-rich and calcified morphology

Background

Thrombogenicity of atherosclerotic plaque largely depends on plaque morphology and their content of tissue factor (TF) and tissue factor pathway inhibitor (TFPI). The relationship between morphological composition of plaque (lipid-rich or calcified) and expression of TF and TFPI in circulating blood monocytes and within the plaques is not characterized.

Objective

To investigate whether lipid-rich (echolucent) or calcified (echogenic) morphology of carotid atherosclerotic plaques is associated with differences in TF and TFPI expression in circulating blood monocytes and within carotid atherosclerotic plaques.

Methods

We studied levels of monocyte TF and TFPI mRNA and protein expression and association with traditional risk factors for atherosclerosis in asymptomatic subjects with echolucent (n = 20) or echogenic (n = 20) carotid plaques, or controls without carotid atherosclerosis (n = 20) determined by ultrasonography. Sections of calcified or lipid-rich carotid plaques obtained from symptomatic patients were assessed for TF and TFPI antigen expression.

Results

TF and TFPI surface presentation, surface TF/TFPI ratio, and TF activity were higher in monocytes obtained from subjects with echolucent than with echogenic plaques or controls without carotid atherosclerosis. Multiple regression analyses revealed inverse association between serum apoA1 and monocyte surface TF antigen expression (p = 0.007), and positive association between serum apoB and monocyte surface TFPI expression (p = 0.028). Sections from lipid-rich carotid plaques contained 2.5-fold more TF and 1.5-fold more TFPI antigens relative to calcified lesions, also yielding a higher TF/TFPI ratio.

Conclusions

Our findings indicate that circulating monocytes of asymptomatic individuals with echolucent lipid-rich carotid atherosclerosis express an imbalance between TF and TFPI expression cohering with changes found within advanced carotid atherosclerotic plaques obtained from symptomatic patients.     

A new sensitive chromogenic substrate assay of tissue factor pathway inhibitor type 1

The present assay is a modification of our previously published two-stage chromogenic substrate assay of tissue factor pathway inhibitor type-1 (TFPI) activity [1]. In the first stage, the reaction mixture was made with factor VIIa (FVIIa) molecules in excess of tissue factor (TF) binding sites and contained diluted plasma, recombinant FVIIa (10 nM), recombinant TF (1/400 vol/vol), bovine factor Xa (1,1 nM), I-2882(R) (100 microg/ml), and CaCl(2) (10 mM). The fibrin polymerisation inhibitor I-2882(R) was added to the reaction mixture to prevent formation of cross-linked fibrin. In the second stage, residual TF/FVIIa catalytic activity was measured by the addition of a substrate mixture that contained bovine factor X and a chromogenic substrate (S-2222(R)). Standard curves were constructed using serial dilutions (0-1%) of pooled normal plasma. The dose-response relationship for serial dilutions of plasma was linear. The intra-assay coefficient of variations (CVs) for pre- and postheparin plasma samples (i.e., normal and high TFPI levels) were 1.7% and 9.9%, respectively; the inter-assay CVs were 10.0% and 19. 7%, respectively. The effect of variation in antithrombin activity on the assay was approximately 5%. The present assay correlated fairly well with our previously published assay (r=0.82, n=100) and with a commercial TFPI activity assay (Actichrome(R) TFPI Activity Assay, American Diagnostica, Greenwich, CT, USA; r=0.90, n=100), as well as with an antigen assay for TFPI total antigen (Imubind(R), American Diagnostica; r=0,96, n=100). Altman and Bland plots revealed that our previous assay underestimated TFPI activity at high TFPI levels (i.e., postheparin TFPI samples) compared with the other methods.