Influence of factor VIII/von Willebrand complex on the activated protein C-resistance phenotype and on the risk for venous thromboembolism in heterozygous carriers of the factor V Leiden mutation.

High factor VIII plasma levels have been shown to represent a common increased risk for venous thromboembolism (VTE) and may cause an activated protein C (APC) resistance in the absence of the factor V Leiden mutation, but there are no studies specifically aimed to establish if high factor VIII and von Willebrand factor (vWF) concentrations may influence the APC sensitivity ratio (APC-SR) and increase the risk for VTE in the presence of the factor V Leiden mutation. For this purpose, we performed a retrospective case-control study to investigate the influence of the procoagulant factor VIII (VIII:C) and the antigen of vWF (vWF:Ag) on the normalized APC-SR (n-APC-SR) and on the risk for VTE, in two selected groups of 30 symptomatic (Group I) and 32 asymptomatic (Group II) related heterozygotes for the factor V Leiden mutation. Differences between the two groups (Group I versus Group II) were: n-APC-SR, 0.57+/-0.06 versus 0.63+/-0.08, P = 0.001; factor VIII:C, 1.49+/-0.42 versus 1.13+/-0.28 IU/ml, P<0.001; vWF:Ag, 1.46+/-0.53 versus 1.26+/-0.32 IU/ml, NS. As a whole (Group I + Group II), Pearson correlation coefficients were: n-APC-SR versus factor VIII:C, r = -0.410, P = 0.001; n-APC-SR versus vWF:Ag, r = -0.309, P = 0.01; factor VIII:C versus vWF:Ag, r = +0.640, P<0.0001. The relative risk for VTE in individuals with the factor VIII:C concentration > 1.5 IU/ml was 2.5 (95% confidence interval 1.6-3.9). We concluded that high factor VIII:C levels, probably in the effect of vWF, play a determinant role in worsening the APC-resistance phenotype and represent a common additional risk factor for VTE in heterozygous carriers of the factor V Leiden mutation.     

Heritability of elevated factor VIII antigen levels in factor V Leiden families with thrombophilia

Factor VIII activity (factor VIII:C) and factor VIII antigen (factor VIII:Ag) levels above 150 IU/dl are associated with a five- to sixfold increased risk of venous thrombosis compared with levels < 100 IU/dl. These high levels are present in 25% of patients with a first episode of deep-vein thrombosis and in 11% of healthy controls. von Willebrand factor (VWF) and blood group are important determinants of the factor VIII level in plasma and therefore contribute to thrombotic risk, while factor VIII appears to be the final effector. Previously, we found familial clustering of factor VIII:C levels in women, which remained after adjustment for VWF and blood group. In the present study, we analysed the familial influence on factor VIII:Ag levels exceeding 150 IU/dl in 12 large families with thrombophilia in which high factor VIII:Ag levels contribute to thrombotic risk. As expected, blood group was a main determinant of the plasma factor VIII level: 58 relatives (32%) had factor VIII levels above 150 IU/dl and 50 (86%) of these had blood group non-O. After adjustment for blood group and age, we found an association between factor VIII:Ag levels in sister pairs (0.35, P = 0.003), brother pairs (0.35, P = 0.003), brother-sister pairs (0.35, P < 0.001) and in mother-son pairs (0.45, P = 0.02), but not in father-daughter or father-son pairs. The familial aggregation test was strongly positive for factor VIII:Ag levels (P < 0.001) and remained so after adjustment for the influence of blood group. We conclude that high factor VIII:Ag levels are a highly prevalent risk factor for venous thrombosis and contribute to risk in families with thrombophilia, and that these high levels are likely to be genetically determined by factors other than just blood group.     

Low-density lipoprotein receptor-related protein polymorphisms in patients with elevated factor VIII coagulant activity and venous thrombosis.

Elevated factor VIII coagulant activity (FVIII:C) levels (>150 IU/dl) represent a prevalent independent risk factor for venous thromboembolism (VTE). Low-density lipoprotein receptor-related protein (LRP) is involved in factor VIII clearance in vivo, and elevated FVIII:C was a feature of the LRP knockout mouse model. Three coding polymorphisms of LRP1 (exon 3, C766T; exon 14, A217V; and exon 39, D2080N), together with an insertion/deletion polymorphism within the first intron of lipoprotein receptor-associated protein (LRPAP1), have been identified. In addition, LRP1 2080D was recently reported to be associated with increased plasma FVIII:C levels in normal individuals. In this study, we investigated the role of these four polymorphisms in patients with objectively confirmed VTE and elevated FVIII:C levels. In our control group, genotype distributions were consistent with previous reports. Neither the allele frequencies nor genotype distributions at LRP1 A217V, LRP1 D2080N and LRPAP1 intron 1 were significantly different between the elevated FVIII:C and control groups. In contrast to previous reports, we found no effect of LRP1 D2080N genotype on plasma FVIII:C levels in normal individuals. More importantly, prevalence of the LRP1 2080D allele was not increased in the group of patients with high FVIII:C and VTE. We conclude that LRP1 and LRPAP1 polymorphisms are not responsible for high FVIII:C levels in patients with VTE.     

DDAVP challenge tests in boys with mild/moderate haemophilia A

Desmopressin (DDAVP) increases plasma factor VIII coagulant activity (FVIII:C) levels in patients with mild/moderate haemophilia A. In some subjects, FVIII can be increased to haemostatic levels, thereby avoiding use of factor VIII concentrates. We reviewed our hospital's experience with 62 boys with FVIII:C levels 0.01-0.3 IU/ml who had a DDAVP challenge test (i.v. 0.3 microg/kg) following diagnosis. A therapeutic response was defined as a 1 h post-FVIII:C increase at least twofold over baseline and > 0.3 IU/ml. Of the total group, 29 (47%) boys responded to DDAVP, all of them with mild haemophilia (baseline FVIII:C > or = 0.05 IU/ml), yielding a response rate of 57% in this subgroup. Boys who responded to DDAVP had higher baseline FVIII:C levels (mean +/- SEM, 0.17 +/- 0.01 vs 0.10 +/- 0.01 IU/ml, P < 0.01) and were older (5.2 +/- 0.8 vs 3 +/- 0.4 years, P = 0.02) than those who failed to do so. The association between DDAVP response and age, however, remains unclear: seven boys who failed the initial challenge test responded to re-challenge after a mean of 6.3 years (median 4.9, range 0.5-12.5), increasing the response rate in boys with mild haemophilia to 71%. Age and FVIII:C association with DDAVP response are both important in boys with mild/moderate haemophilia A. Absence of response to DDAVP should therefore be confirmed by later re-challenge.     

Biological and genetic factors influencing plasma factor VIII levels in a healthy family population: results from the Stanislas cohort

The mechanisms underlying the variability of factor VIII (FVIII) levels are still poorly understood. The only receptor of FVIII identified so far is the lipoprotein receptor-related protein (LRP), which is thought to be involved in FVIII degradation. We aimed to characterize biological and genetic factors related to FVIII variability, focusing on coding polymorphisms of the LRP gene and polymorphisms potentially detected by molecular screening of the LRP-binding domains of the FVIII gene. Plasma FVIII coagulant activity (FVIII:C) and von Willebrand factor (VWF:Ag) antigen levels were measured in a sample of 100 healthy nuclear families (200 parents and 224 offspring). The ABO blood group and the three coding polymorphisms of the LRP gene (A217V, D2080N and C766T) were genotyped. Lipids and anthropometric factors poorly contributed to the variability of FVIII:C (<5%). A strong effect of ABO blood groups on FVIII:C levels was observed that remained significant after adjustment for VWF:Ag levels (P = 0.02). These two factors explained more than 50% of FVIII:C variability. After adjustment for VWF:Ag and ABO blood groups, a residual resemblance for FVIII:C persisted between biological relatives (rho = 0.13 +/- 0.06 between parents and offspring, rho = 0.24 +/- 0.09 between siblings) compatible with an additional genetic influence. The N allele of the LRP/D2080N polymorphism was associated with decreased levels of FVIII:C (90.4 +/- 8.7 vs. 102.2 +/- 3.5 IU/dl, P = 0.03) and VWF:Ag levels (109.1 +/- 11.2 vs. 125.4 +/- 4.4 IU/dl, P = 0.02). No polymorphism was detected in the LRP-binding domains of the FVIII gene. This study reinforces the hypothesis of a genetic influence of FVIII levels beyond the influence of VWF:Ag and ABO blood groups. The D2080N polymorphism of the LRP gene weakly contributed to the variability of FVIII:C levels in this healthy population.     

Bleeding prophylaxis for major surgery in patients with type 2 von Willebrand disease with an intermediate purity factor VIII-von Willebrand factor concentrate (Haemate-P).

The parameters to diagnose von Willebrand disease (vWD) include factor VIII coagulant activity (FVIII:C), von Willebrand factor antigen (vWF:Ag), von Willebrand factor ristocetin cofactor activity (vWF:RCo), and von Willebrand factor collagen binding activity (vWF:CB). Type 2 vWD is associated with a moderate bleeding diathesis due to low levels of vWF:RCo and vWF:CB as compared with near normal or normal values for FVIII:C and vWF:Ag. As the factor VIII/von Willebrand factor (vWF) concentrate, Haemate-P, is featured by a vWF:RCo/FVIII:C ratio of about 2.2, the recommended loading dose of 50 U/kg FVIII:C followed by 25 U/kg FVIII:C every 12 h for several days for bleeding prophylaxis in type 2 vWD patients undergoing major surgery demonstrated a predicted significant over-treatment reaching vWF:RCo levels above 2 U/ml. Therefore, we restricted Haemate-P substitution for major surgery to one loading dose of 40-50 U/kg FVIII:C (88-110 U/kg vWF:RCo) followed by 15-20 U/kg FVIII:C (33-44 U/kg vWF:RCo) every 12 h for several days and evaluated this strategy in a prospective pharmacokinetic and efficacy study for bleeding prophylaxis in five type 2 vWD patients. Pre-treatment and peak levels (1 h after Haemate-P loading dose) rose from 0.43-0.66 to 1.5-2.5 U/ml for FVIII:C, from 0.23-0.45 to 1.5-2.5 U/ml for vWF:Ag, from 0.10-< 0.20 to 1.5-2.5 U/ml for vWF:RCo, and from < 0.05-0.10 to 1.0-2.0 U/ml for vWF:CB. Mean in vivo recoveries per transfused IU FVIII:C/kg body weight were 3.2% for FVIII:C, 3.9% for vWF:RCo, and 2.8% for vWF:CB. Mean in vivo recoveries per transfused IU vWF:RCo/kg were 1.45% for FVIII:C, 1.7% for vWF:RCo and 1.25% for vWF:CB. The biological half-life times after transfused Haemate-P were about 12 h for both vWF:RCo and vWF:CB. Based on these pharmacokinetic data, we propose to adapt the loading dose factor VIII/vWF concentrate (Haemate-P) to 60-80 U/kg vWF:RCo followed by 30-40 U/kg vWF:RCo every 12 h for no longer than several days (less than 1 week) for bleeding prophylaxis during major surgery or trauma, and to one loading dose of 40-60 U/kg vWF:RCo for minor surgery, trauma or mucotaneous bleedings in patients with type 2 vWD unresponsive to DDAVP.     

Simplified immunoradiometric assay for factor VIII coagulant antigen

A simplified, non-competitive, solid phase immunoradiometric assay has been developed for the quantitation of factor VIII coagulant antigen (VIII:CAg)--the antigenic counterpart of FVIII coagulant activity (VIII:C). Both homologous and heterologous antibodies to human factor VIII (FVIII) were used in this assay. Initially, FVIII in a test sample was attached to immobilized, human IgG obtained from a polytransfused haemophilia A patient with a high titre antibody to VIII:C. The bound FVIII was then detected using rabbit 125I-IgG specific for human FVIII. The concentration of VIII:CAg correlated well with VIII:C levels in the plasma from normal donors (r = 0.84, n - 15). Homozygote von Willebrand's disease patients had undetectable levels of VIII:CAg in their plasma. Patients with severe haemophilia A (VIII:C less than 0.01 u/ml) could be divided into groups on the basis of the VIII:CAg levels, i.e. those having undetectable VIII:CAg and other with measurable VIII:CAg. VIII:CAg detected in normal serum was less than 0.002 u/ml. In this assay the use of human antibody to FVIII is considerably decreased compared to other methods for VIII:CAg, and the time-consuming steps to immunopurify human anti-FVIII antibody are eliminated.     

Incidence of factor VIII inhibitors in severe haemophilia: the importance of patient age

The potential effect of age at the start of replacement therapy on the development of factor VIII (FVIII) inhibitors was assessed in 62 severe (FVIII < 2 IU/dl) haemophilia A patients who started FVIII therapy at one of two haemophilia centres. Inhibitors were tested on an annual basis. Persistent or high-titre inhibitors were detected in 15 patients (24%). Kaplan-Meier cumulative incidence at 3 years from first FVIII exposure was 41% (95% CI 22-67%) in patients starting therapy before the age of 6 months, 29% (95% CI 13-57%) in patients starting therapy between 6 and 12 months of age, and 12% (95% CI 4-34%) in those starting therapy beyond 1 year of age (P = 0.03). By multivariate analysis, the influence of age was shown to be independent of other variables, including calendar year at the onset of therapy and baseline FVIII plasma levels. In conclusion, patient age at initial treatment appears to influence inhibitor formation. If confirmed, this finding would have a major impact on the management of haemophilia.     

Marked elevation of thrombin generation in patients with elevated FVIII:C and venous thromboembolism

Elevated plasma factor VIII coagulant activity (FVIII:C, > 150 IU/dl) is a risk factor for venous thromboembolism (VTE). We hypothesized that increased FVIII:C may exert a prothrombotic effect by increasing basal thrombin generation. To test this hypothesis we have measured prothrombin fragment 1 + 2 (F1 + 2) and thrombin-antithrombin complex (TAT) in three groups: (i) patients with objectively confirmed VTE and elevated FVIII:C; (ii) patients with VTE and no detectable thrombophilia; and (iii) healthy age- and sex-matched control subjects. In the group of patients with elevated FVIII:C, TAT and F1 + 2 levels were increased in 85% and 78% of individuals respectively. This frequency of coagulation activation is dramatically higher than that reported for other recognized constitutional thrombophilias. In the group of patients with VTE but no proven thrombophilia, increased thrombin generation was present in 30% of individuals. Basal thrombin generation was significantly higher in patients with elevated FVIII:C compared with individuals with VTE but no documented thrombophilia (median TAT = 8.65 microg/l versus 2.95 microg/l, median F1 + 2 = 1.5 nmol/l versus 0.87 nmol/l; P < 0.0001, P < 0.001). Overall FVIII:C levels were strongly correlated with levels of thrombin generation (r= 0.5, P < 0001). The clinical significance of such markedly increased F1 + 2 and TAT levels in patients with high FVIII:C levels remains unclear.     

In vitro kinetics of factor VIII activity in patients with mild haemophilia A and a discrepancy between one-stage and two-stage factor VIII assay results

In some mild haemophilia A patients (discrepant haemophilia), factor VIII coagulant activity (FVIII:C) levels, by one-stage assay are more than double than those by two-stage assay. This may be due to the longer incubation times (10-12 min) in the two-stage assay. This study aimed to determine the time course of the activation phase of the two-stage assay, using both classical coagulation and chromogenic detection methods. In both systems, for equivalent patients (equivalent FVIII:C levels by one-stage and two-stage assays, n = 6, all different mutations), similar FVIII:C results were obtained with short- or long-incubation times. In contrast, plasma from discrepant patients (n = 8, five different mutations) showed higher FVIII:C at shorter incubation times than after longer incubation times. In the chromogenic assay, FVIII:C levels were higher after incubation for 2 min (23-56%, mean 41%) than after 10 min (19-41%, mean 29%). In the classical coagulation assay, FVIII:C levels were higher at shorter incubation times (21-64%, mean 37%) than with the longer incubation times usually used (13-29%, mean 23%). These time-course experiments have verified that the longer incubation time used in the two-stage assay is at least partly responsible for the lower FVIII:C measured by that assay in discrepant haemophilia.     

High plasma concentration of factor VIII coagulant is also a risk factor for venous thromboembolism in the elderly

BACKGROUND AND OBJECTIVES: A high level of coagulant factor VIII is a well known risk factor for venous thromboembolism, but most studies have enrolled patients under 70 years old. This study aimed to test the hypothesis that an association also exists in the elderly. DESIGN AND METHODS: This hospital-based case-referent study took place at the Department of Internal Medicine and Chest Diseases, University Hospital, Brest, France. We enrolled 161 patients with a first episode of venous thrombosis and 239 subjects, referred for a clinical suspicion of venous thromboembolism which was subsequently ruled out. Factor VIII coagulant activity and plasma fibrinogen concentration were measured. RESULTS: High factor VIII coagulant activity was significantly associated with venous thromboembolism, irrespective of the age group. Patients over 70 years with factor VIII coagulant activity above 225% had a 2.4-fold increased risk of venous thromboembolism compared to those patients with levels below 130% (age- and fibrinogen-adjusted odds ratio: 2.6, 95% CI 1.1 to 6.1). INTERPRETATION AND CONCLUSIONS: Our results show that high levels of factor VIII coagulant, a determinant of venous thrombosis in adulthood, is also a risk factor in the elderly.     

Intermittent injections vs. continuous infusion of factor VIII in haemophilia patients undergoing major surgery

Continuous infusion (CI) of factor VIII (FVIII) has been proved to be a safe alternative to intermittent bolus injections (BI) in haemophilia A. Most reports on CI suggest a considerable saving in FVIII compared with historical controls treated with BI, but some recent reports failed to demonstrate such an effect. The present study prospectively compared safety, efficacy and factor requirements in 43 major surgical procedures performed in severe haemophilia A patients who were treated with either BI (18 operations) or CI (25 operations). The aim was to maintain factor VIII levels above the same minimum levels. Improved safety of CI over BI was observed, despite a bias in favour of the BI group (all underwent unilateral operations, compared with 24% of the CI group who underwent bilateral operations). Higher nadir levels were found in the CI group (0.44 +/- 0.06 vs. 0.31 +/- 0.09 IU/ml; P < 0.01) with a lower incidence of dangerous drops below 0.3 IU/ml (8% vs. 44% of patients respectively; P < 0.01), and a lower drop in haemoglobin (Hb) (1.56 +/- 1.21 vs. 3.01 +/- 2.13 g/dl; P < 0.05) and blood transfusion requirements (12% vs. 39%; P < 0.01). Major bleeding complications developed in three out of 18 patients (17%) in the BI group and none of the CI group (P = 0.06). The FVIII dosage was lower by 36% in the CI group (467 +/- 104 vs. 733 +/- 126 IU/kg; P < 0.01). Had the trough factor levels been maintained at the target levels, a greater difference of 72% would probably have been observed.     

The factor V HR2 haplotype and the risk of venous thrombosis: a meta-analysis

Background and Objectives: A complex haplotype of factor V gene (FV HR2) has been recently reported. FVHR2 possesses decreased co-factor activity to APC in the degradation of FVIIIa, and an increased ratio of the more procoagulant isoform FV1 compared to FV2. Contrasting results on whether the haplotype induces a significant risk of venous thromboembolism (VTE) have been reported. Design and Methods: It has been surmised that FVHR2 enhances the risk of VTE carried by FV Leiden. We carried out a meta-analysis of the reported studies on the role of HR2 haplotype in inducing a risk of VTE and the influence of the polymorphism on the risk carried by patients with FV Leiden. Results: Eight studies were analyzed for the estimation of the risk of VTE. A total of 338 out of 2,696 cases (12.5%; range 7.8 to 18.5%) and 885 out of 7,710 controls (11.5%; range 8.1 to 12.1%) were HR2 positive. The odds ratio for VTE associated with HR2 haplotype was not statistically significant (OR 1.15; 95% C.I. 0.98-1.36). The OR for the association between FV Leiden and FV HR2 and the risk of VTE in cases and controls was largely heterogeneous as to OR and 95% C.I. and no statistical significant difference was observed. Interpretation and Conclusions: The data from the present meta-analysis suggests that FVHR2 could be a very mild prothrombotic factor. The association of FV Leiden and HR2 haplotype seems not to increase significantly the risk of VTE carried by isolated heterozygosity for FV Leiden. However, well-designed clinical studies are needed to clarify this issue definitely.     

Clinical efficacy of highly purified, doubly virus-inactivated factor VIII/von Willebrand factor concentrate (Fanhdi®) in the treatment of von Willebrand disease: a retrospective clinical study

The goal of therapy in patients with von Willebrand disease (vWD) is to correct the dual defect of primary haemostasis and intrinsic coagulation reflected by low levels of von Willebrand factor (vWF) and factor VIII coagulant activity (FVIII:C). Factor VIII/von Willebrand factor (FVIII/vWF) concentrates are currently the treatment of choice in vWD patients unresponsive to desmopressin (DDAVP). However, only few studies on their clinical use are available so far. The main objective of this study was to retrospectively evaluate the clinical efficacy of a highly purified, doubly virus-inactivated FVIII/vWF concentrate with a high content of FVIII/vWF (Fanhdi). Twenty-two patients with congenital vWD have been treated from 1999 to 2001 at eight specialized centres belonging to the Italian Association of Hemophilia Centers (AICE). Ten males and 12 females, median age 28.5 years, range 5-70 years) had type 3 vWD (six cases), DDAVP-unresponsive type 1 (nine cases) and type 2B (seven cases). The study drug was given to stop or prevent 12 bleeding episodes or to prevent excessive bleeding during 14 surgical or invasive procedures. Overall, replacement therapy with the concentrate showed an excellent to good clinical efficacy in 92% of bleeding episodes and in 93% of surgical procedures. No adverse events occurred during 1,601 infusions, accounting for a total of 304,500 IU of FVIII:C administered. These results confirm the efficacy and safety of this concentrate in the management of bleeding episodes and in the prevention of excessive bleeding during major and minor surgery.     

Beta-adrenergic receptor polymorphisms in patients with elevated factor VIII levels with venous thrombosis

Beta-blockers significantly reduce elevated factor VIII (FVIII) levels in patients with venous thromboembolism (VTE). To determine whether beta-adrenergic receptors are important in the aetiology of high FVIII levels, we investigated four coding polymorphisms of the beta1- and beta2-receptor genes in 64 patients with high FVIII and VTE and 100 healthy controls. Genotypic and allelic frequencies were not significantly different between the patient and control groups. However, a significant dosage effect of the beta2 E27 allele on plasma FVIII coagulant activity levels was observed in normal group O individuals.     

Intranasal DDAVP induced increases in plasma von Willebrand factor alter the pharmacokinetics of high-purity factor VIII concentrates in severe haemophilia A patients

Because native circulating factor VIII (FVIII) is maximally stabilized when it is bound to von Willebrand factor (vWf), increased plasma vWf levels may enhance the infused FVIII concentrate intravascular survival and efficacy in severe haemophiliacs. To assess whether the kinetic characteristics and recovery of high purity, plasma-derived (Monoclate-P, Centeon) and recombinant (Bioclate , Centeon) FVIII concentrates are enhanced by increased plasma vWf concentrations, we compared the pharmacokinetic response to a bolus of FVIII infused alone with the response to a bolus infused 2 h after the intranasal delivery of 300 microg of desmopressin acetate (DDAVP) High Concentration Nasal Spray (Stimate, Centeon) in 10 adult severe haemophiliacs. FVIII activity was determined using a one-stage clotting assay on cryopreserved plasma specimens obtained at baseline and at 14 distinct time points (0.25-48 h) following the FVIII infusions. Ristocetin co-factor activity (RCoFA) and vWf antigen levels were assayed at baseline and 2 h after Stimate. FVIII kinetic parameters were calculated using standard, noncompartmental kinetic methods. Statistical analysis was performed using a paired t-test with 95% confidence limits. The mean rises in RCoFA (0.65+/-0.44 IU mL(-1)) and vWf antigen (0.19+/-0.07 IU mL-1) induced by Stimate were significant (P<0.01 and P<0.0001, respectively). The mean increases in the volume of distribution at steady state (Vss) (13.2+/-9.3 dL) and mean residence time (MRT) (4.4+/-3.9 h) between the FVIII-only arm and the FVIII plus Stimate arm were highly significant (P = 0.0015 and P = 0. 0059, respectively). The mean differences in recovery, area under the curve (AUC), half-life, and clearance (Cl) were not significantly altered. Subgroup analysis revealed statistically significant increases in Vss and MRT (P = 0.025 and P = 0.012, respectively) following the administration of intranasal DDAVP in the Monoclate-P cohort, but not in the Bioclate group. These data suggest that even modest pharmacologically induced increases in plasma vWf can favourably affect the kinetics of high-purity, plasma-derived FVIII concentrates in severe haemophiliacs.     

Correlation between von Willebrand factor antigen,von Willebrand factor ristocetin cofactor activity and factor VIII activity in plasma

Background The laboratory diagnosis of von Willebrand Factor (VWF) deficiencies includes qualitative and quantitative measurements of VWF and clotting factor VIII (FVIII). Since the FVIII activity is frequently normal in patients with mild type 1 or 2 von Willebrand disease (VWD), there is controversy whether FVIII testing should accompany VWF Antigen (VWF:Ag) assay. Methods The aim of this study was to explore the correlation between VWF:Ag, VWF ristocetin cofactor activity (VWF:RCo) and FVIII in 213 consecutive patients undergoing screening for VWD. Results Forty-six patients were identified with VWF:Ag levels lower than the diagnostic threshold (54 IU/dl). A significant correlation was observed between VWF:Ag and VWF:RCo (r = 0.892; p < 0.001), VWF:Ag and FVIII (r = 0.834; p < 0.001), VWF:RCo and FVIII (r = 0.758; p < 0.001). Receiver operating characteristic curve analysis of the VWF:Ag assay revealed an area under the curve of 0.978 and 0.957 for detecting life-threatening values of FVIII (<30 IU/dl) and VWF:RCo (<40 IU/dl), respectively. The negative and positive predictive values at the VWF:Ag threshold value of 54 IU/dl were 100% and 33% for detecting life-threatening FVIII deficiencies, 94% and 80% for identifying abnormal values of VWF:RCo. Conclusions Due to the excellent correlation between VWF:Ag and FVIII and to the diagnostic efficiency of VWF:Ag for identifying abnormal FVIII levels in patients with VWF deficiency, routine measurement of FVIII may not be necessary in the initial screening of patients with suspected VWD. However, the limited negative predictive value of VWF:Ag for identifying type 2 VWD does not allow to eliminate VWF:RCo or VWF:FVIIIB assays from the diagnostic workout.     

Corn trypsin inhibitor in fluorogenic thrombin-generation measurements is only necessary at low tissue factor concentrations and influences the relationship between factor VIII coagulant activity and thrombogram parameters.

The fluorogenic calibrated automated thrombin-generation assay is influenced by contact pathway activation in platelet-rich and platelet-poor plasma. This influence lessens with increasing tissue factor (TF) concentrations and is inhibited by corn trypsin inhibitor (CTI). CTI is expensive and at what TF concentration its influence becomes irrelevant is unclear. Spiking of factor VIII (FVIII)-depleted plasma with FVIII, in samples without CTI, shows a plateau of thrombin generation at low normal FVIII levels. Given the association with thrombosis at high levels, a continuing increase in thrombin generation would be expected. We studied the effect of CTI on this relation by spiking experiments up to 4.8 IU/ml at 1 pmol/l TF and compared the influence of CTI at 1 and 5 pmol/l in platelet-poor plasma. CTI significantly influences thrombin generation in platelet-poor plasma at 1 pmol/l TF (difference of means for endogenous thrombin potential of 232.5 nmol/l per min, P<0.0001) and peak of 48 nmol/l (P<0.0001)) but not at 5 pmol/l. Spiking experiments without CTI confirm the hyperbolic relation between FVIII coagulant activity (FVIII:C) and endogenous thrombin potential with a plateau at 0.70-1.40 IU/ml. With CTI, a near-linear response up to 1.0 IU/ml was found with a plateau at 2.4-4.8 IU/ml. For peak thrombin, no plateau was reached with CTI. The present study confirms and extends previous data on CTI and the relationship between FVIII:C and thrombin generation. CTI is not necessary at 5 pmol/l TF, and thrombin generation remains dependent on FVIII:C up to 4.8 IU/ml at 1 pmol/l with CTI. Higher levels than previously thought may be needed to normalize thrombin generation.     

Comorbidities associated with higher von Willebrand factor (VWF) levels may explain the age‐related increase of VWF in von Willebrand disease

Some comorbidities, such as hypertension, are associated with higher von Willebrand factor (VWF) levels in the general population. No studies have been conducted to assess this association in patients with von Willebrand disease (VWD). Therefore, we studied this association in patients with type 1 (n = 333) and type 2 (n = 203) VWD from the ‘WiN” study. VWF antigen (VWF:Ag) was higher in type 1 VWD patients with hypertension [difference: 0·23 iu/ml, 95% confidence interval (CI): 0·11–0·35], diabetes mellitus (0·11 iu/ml, 95% CI: −0·02 to 0·23), cancer (0·14 iu/ml, 95% CI: 0·03–0·25) and thyroid dysfunction (0·14 iu/ml, 95% CI: 0·03–0·26) than in patients without these comorbidities (all corrected for age, sex and blood group). Similar results were observed for VWF collagen binding capacity (VWF:CB), VWF activity as measured by the VWF monoclonal antibody assay (VWF:Ab) and factor VIII (FVIII) coagulant activity (FVIII:C). In type 1 VWD, age was associated with higher VWF:Ag (0·03 iu/ml; 95% CI: 0·01–0·04), VWF:CB (0·02 iu/ml; 95% CI: 0·00–0·04), VWF:Ab (0·04 iu/ml; 95% CI: 0·02–0·06) and FVIII:C (0·03 iu/ml; 95% CI: 0·01–0·06) per decade increase. After adjustment for relevant comorbidities, these associations were no longer significant. Despite the higher VWF and FVIII levels, type 1 VWD patients with comorbidities had more bleeding episodes, particularly during surgery. There was no association between comorbidities and VWF/FVIII levels or bleeding phenotype in type 2 VWD patients. In conclusion, comorbidities are associated with higher VWF and FVIII levels in type 1 VWD and may explain the age‐related increase of VWF and FVIII levels.     

Localization of a factor VIII-inhibiting antibody epitope to a region between residues 338 and 362 of factor VIII heavy chain.

We have used a recombinant DNA epitope library to localize the binding region of a factor VIII (FVIII) monoclonal antibody that neutralizes coagulant activity. The antibody, C5, has previously been described and has been shown to have a FVIII neutralizing potency of 1488 Bethesda units per mg of purified immunoglobulin. A recombinant DNA epitope library was constructed from short, random FVIII cDNA fragments and immunologically screened with C5 to identify bacteriophage expressing the antigenic determinant. The isolation and characterization of immunoreactive bacteriophage restricted the C5 epitope to the overlapping or shared DNA sequence of nine different clones and corresponded to amino acid residues 338-362 of the mature FVIII peptide. The defined epitope is between the proposed activated protein C cleavage site (Arg-336) and thrombin cleavage site (Arg-372) on the amino-terminal 90-kDa FVIII heavy-chain subunit. The identification of the epitope of an inhibiting anti-FVIII antibody between two critical cleavage sites suggests that this amino acid sequence plays a role in regulating FVIII coagulant activity.