An in vitro analysis of the combination of hemophilia A and factor V(LEIDEN)

The classification of factor VIII deficiency, generally used based on plasma levels of factor VIII, consists of severe (<1% normal factor VIII activity), moderate (1% to 4% factor VIII activity), or mild (5% to 25% factor VIII activity). A recent communication described four individuals bearing identical factor VIII mutations. This resulted in a severe bleeding disorder in two patients who carried a normal factor V gene, whereas the two patients who did not display severe hemophilia were heterozygous for the factor V(LEIDEN) mutation, which leads to the substitution of Arg506 --> Gln mutation in the factor V molecule. Based on the factor VIII level measured using factor VIII-deficient plasma, these two patients were classified as mild/moderate hemophiliacs. We studied the condition of moderate to severe hemophilia A combined with the factor V(LEIDEN) mutation in vitro in a reconstituted model of the tissue factor pathway to thrombin. In the model, thrombin generation was initiated by relipidated tissue factor and factor VIIa in the presence of the coagulation factors X, IX, II, V, and VIII and the inhibitors tissue factor pathway inhibitor, antithrombin-III, and protein C. At 5 pmol/L initiating factor VIIa x tissue factor, a 10-fold higher peak level of thrombin formation (350 nmol/L), was observed in the system in the presence of plasma levels of factor VIII compared with reactions without factor VIII. Significant increase in thrombin formation was observed at factor VIII concentrations less than 42 pmol/L (approximately 6% of the normal factor VIII plasma concentration). In reactions without factor VIII, in which thrombin generation was downregulated by the addition of protein C and thrombomodulin, an increase of thrombin formation was observed with the factor V(LEIDEN) mutation. The level of increase in thrombin generation in the hemophilia A situation was found to be dependent on the factor V(LEIDEN) concentration. When the factor V(LEIDEN) concentration was varied from 50% to 150% of the normal plasma concentration, the increase in thrombin generation ranged from threefold to sevenfold. The data suggested that the analysis of the factor V genotype should be accompanied by a quantitative analysis of the plasma factor V(LEIDEN) level to understand the effect of factor V(LEIDEN) in hemophilia A patients. The presented data support the hypothesis that the factor V(LEIDEN) mutation can increase thrombin formation in severe hemophilia A.     

Differentiation in human amniotic fluid cell cultures: I: Collagen production

Plasma from a patient factor VIII inhibitor was mixed at several low concentrations with fresh normal plasma. The factor VIII deficient plasmas obtained after a short incubation period were used as substrate plasmas in the normal one-stage factor VIII assay method. Results obtained using 0.5-1% of the inhibitor plasma in normal plasma compared favourably with those obtained using normal haemophilia A factor VIII deficient plasma provided that tests were carried out without delay. A single plasma exchange of this patient provided enough antibody to prepare more than 500 litres of factor VIII deficient plasma by simple mixing with fresh normal plasma.     

Recognition of hemophilia A in an elderly patient

Hemophilia A (classic hemophilia) is an hereditary coagulation disorder characterized by the absence, severe deficiency, or defective functioning of plasma coagulation factor VIII. It is inherited in an X-linked recessive manner and occurs almost exclusively in males. The first manifestations of bleeding are usually first noted as a young child since most of the patients with hemophilia A have a profound deficiency of factor VIII (less than 1% of normal value). However, in mild hemophilia (5-25% of normal level of factor VIII) the condition may escape detection with many of the patients developing bleeding only after trauma or surgery. Hemophilia A is the result of a recent genetic mutation in approximately one third of patients, for whom often there is no family history of a bleeding disorder. Here we present an elderly male patient with spontaneous bleeding in an extremity that has coagulation studies consistent with the diagnosis of hemophilia A. Physicians must be aware that mild hemophilia can present in this unusual manner and should consider this possibility in patients that have unexplained bleeding even if there is no clear personal or family history of an hereditary coagulation disorder.     

Studies on the toxicity and maximum allowable concentration of chloroform

Hemophilia A is caused by the lack of functional blood-clotting factor VIII. We have used retrovirus-mediated gene transfer to generate various cell lines, rodent as well as human, that secrete the human factor VIII protein. To study whether transplantation of genetically modified fibroblasts is a feasible approach for gene therapy of hemophilia A, we implanted the factor VIII-secreting cells into immune-deficient mice. Implantation of factor VIII-secreting primary human skin fibroblasts resulted in long-term persistence of the transplanted cells; cells recovered from the implants up to 2 months post-implantation still had the capacity to secrete factor VIII when regrown in tissue culture. However, we were unable to detect any human factor VIII in plasma samples of the recipient mice. The absence of human factor VIII in the recipients' plasma is shown to be due neither to (epigenetic) inactivation of the retroviral vector in vivo, nor to inability of the stationary cells to secrete factor VIII protein. However, we did note a rapid clearing of the human factor VIII: CAg from plasma upon intravenous injection of plasma-derived human factor VIII in mice (t1/2 < 60 min vs. 10 hr in humans). This phenomenon can fully explain the apparent absence of human factor VIII in the recipients' plasma.     

Kinetics of factor VIII-von Willebrand factor association

The binding of factor VIII to von Willebrand factor (vWF) is essential for the protection of factor VIII against proteolytic degradation in plasma. We have characterized the binding kinetics of human factor VIII with vWF using a centrifugation binding assay. Purified or plasma vWF was immobilized with a monoclonal antibody (MoAb RU1) covalently linked to Sepharose (Pharmacia LKB Biotechnology, Uppsala, Sweden). Factor VIII was incubated with vWF-RU1-Sepharose and unbound factor VIII was separated from bound factor VIII by centrifugation. The amount of bound factor VIII was determined from the decrease of factor VIII activity in the supernatant. Factor VIII binding to vWF-RU1-Sepharose conformed to the Langmuir model for independent binding sites with a Kd of 0.46 +/- 0.12 nmol/L, and a stoichiometry of 1.3 factor VIII molecules per vWF monomer at saturation, suggesting that each vWF subunit contains a binding site for factor VIII. Competition experiments were performed with a recombinant vWF (deltaA2-rvWF), lacking residues 730 to 910 which contain the epitope for MoAB RU1. DeltaA2-rvWF effectively displaced previously bound factor VIII, confirming that factor VIII binding to vWF-RU1-Sepharose was reversible. To determine the association rate constant (k(on)) and the dissociation rate constant (k(off)), factor VIII was incubated with vWF-RU1-Sepharose for various time intervals. The observed association kinetics conformed to a simple bimolecular association reaction with k(on) = 5.9 +/- 1.9 x 10(6) M(-1) s(-1) and k(off) = 1.6 +/- 1.2 x 10(-3) s(-1) (mean +/- SD). Similar values were obtained from the dissociation kinetics measured after dilution of preformed factor VIII-vWF-RU1-Sepharose complexes. Identical rate constants were obtained for factor VIII binding to vWF from normal pooled plasma and to vWF from plasma of patients with hemophilia A. The kinetic parameters in this report allow estimation of the time needed for complex formation in vivo in healthy individuals and in patients with hemophilia A, in which monoclonally purified or recombinant factor VIII associates with endogenous vWF. Using the plasma concentration of vWF (50 nmol/L in monomers) and the obtained values for K(on) and K(off), the time needed to bind 50% of factor VIII is approximately 2 seconds.     

Antibody binding to a peptide but not the whole protein by recognition of the C-terminal carboxy group

Factor V and protein S are cofactors of activated protein C (APC) which accelerate APC-mediated factor VIII inactivation. The effects of factor V and protein S were quantitated in a reaction system in which plasma factor VIII was inactivated by APC and the loss of factor VIII activity was monitored in a factor X-activating system in which a chromogenic substrate was used to probe factor Xa formation. Factor V increased the rate of APC-mediated factor VIII inactivation in a dose-dependent manner in representative plasma samples with protein S or factor V deficiency, abnormal factor V (heterozygous or homozygous for factor VR506Q), or a combination of heterozygous protein S deficiency and heterozygous factor VR506Q. This effect was much less pronounced in the plasma samples with a decreased protein S level, but the impaired response in these plasmas was corrected by addition of protein S, indicating that both factor V and protein S are required for optimal inactivation of factor VIII by APC. The effects of factor V and protein S were also studied in a reaction system with purified proteins. APC-catalysed factor VIII inactivation was enhanced 3.7-fold in the presence of 1.1 nM factor V and 1.5-fold in the presence of 2.4 nM protein S. When both 1.1 nM factor V and 2.4 nM protein were present the rate enhancement was 11-fold. Factor V is a more potent cofactor than protein S, as can be concluded from the fact that 0.04 nM factor V gave the same stimulation as 2.4 nM protein S. Protein S lost its cofactor function after complexation with C4b binding protein, which indicates that it is free protein S that acts as a cofactor. To investigate the effect of the R506Q mutation in factor V on APC-mediated factor VIII inactivation, factor V was purified from the plasma of patients homozygous for factor VR506Q. In the absence of protein S, factor VR506Q did not enhance factor VIII inactivation by APC, but in the presence of 2.4 nM protein S a slight enhancement was observed. The APC cofactor activity of factor V was lost when factor V was activated with thrombin or with the factor V activator from Russell's viper venom. These data indicate that optimal inactivation of factor VIII by APC requires the presence of an intact factor V molecule and free protein S.     

A human alloantibody interferes with binding of factor IXa to the factor VIII light chain

Inhibitory antibodies directed against factor VIII develop in a substantial number of patients with hemophilia A as a consequence of factor VIII replacement therapy. These antibodies usually recognize discrete epitopes within the A2 and/or the C2 domains of factor VIII. Here, we have characterized the antibodies present in the plasma of a patient affected by severe hemophilia A. The antibodies reacted readily with the metabolically labeled factor VIII light chain and fragments thereof when analyzed by immunoprecipitation. The inhibitory activity could be neutralized by the complete light chain, whereas only slight neutralization occurred with a fragment comprising the isolated C2 domain. Binding of the majority of antibodies to in vitro synthesized factor VIII fragments was dependent on the presence of amino acid residues Gln1778-Met1823, a region known to contain a factor IXa binding site. Functional characterization showed that purified IgG from the patient's serum inhibited binding of factor IXa to immobilized factor VIII light chain in a dose-dependent manner. These data indicate that human alloantibodies may inhibit factor VIII activity by interfering with factor IXa-factor VIIIa complex assembly.     

Detection of hemophilia carriers during pregnancy

The accuracy of hemophilia A carrier detection during pregnancy has been determined using combined measurement of VIII:CAg and VIIIR:Ag. These immunoassays detect determinants that are sufficiently stable in plasma that the assays could be done on frozen samples that had been obtained when women were seen for antenatal diagnosis studies (carrier women) or for routine prenatal care (controls). A linear discriminant was calculated that best separated the data for 32 normal women and 25 obligate carriers of the hemophilia gene. Twenty-three of 25 carriers (92%) and all 32 control women were correctly identified in this analysis. The overall classification accuracy (55/57, 96%) is comparable to that obtained by VIII:C and VIIIR:Ag measurements using freshly drawn blood samples in nonpregnant individuals. This study demonstrates that hemophilia A carriers can be detected during pregnancy with sufficient accuracy that the information may be used for genetic counseling.     

Removal of heparin and protamine from plasma

A simple chromatographic technique for rapid adsorption of heparin and protamine from plasma samples is described, allowing accurate interpretation of coagulation screening tests and specific clotting factor assays. With the use of columns of ECTEOLA-cellulose, up to 300 U. of heparin could be completely adsorbed from a 1 ml. plasma sample. When citrated nonheparinized plasma was passed over the ECTEOLA-cellulose columns, the thrombin, prothrombin, and partial thromboplastin times were unaffected. Levels of fibrinogen, prothrombin, and factors V, VII, VIII, IX, and XI average within 90 per cent of control, nonchromatographed samples. When heparinized plasma samples (0.1 and 1.0 U. per milliliter) were passed over columns, heparin was completely removed and the results of the screening tests and the specific factor assays were the same as for the chromatographed nonheparinized samples. In addition, heparinized samples with decreased factor VIII activity maintained their pretreatment factor VII activities after heparin removal. Blood samples containing heparin were obtained from two patients during open-heart surgery. Following heparin adsorption on ECTEOLA-cellulose columns, factor VIII activity levels remained above 60 per cent during cardiopulmonary by-pass. The presence of protamine sulfate in plasma samples prolonged the prothrombin and partial thromboplastin times while slightly shortening the thrombin time. The protamine effect persisted after ECTEOLA-cellulose, but could be removed by a similar column of carboxymethyl-cellulose. The latter resin had no effect on screening tests or on assays of factors VIII or IX activity. The combination of the two resins was then used to remove the separate inhibitory effects from heparinized plasma samples to which protamine had been added.     

Prophylactic replacement therapy in hemophilia. A case report (author's transl)

In a six year old boy with severe hemophilia prophylactic substitution of factor VIII was started in 1973 in order to prevent early invalidity due to series of bleeding in the right anklejoint. A substitution of factor VIII over 8 months with 21 resp. 30 U/kg body-weight did not lead to a significant improvement. But since the factor VIII in a dosage of 18 U/kg body-weight is given three times a week no bleeding occurred during the treatment time of 14 months and also the ability to walk improved to an excellent degree.--So far no signs of hepatitis or an factor-VIII-antibody could be detected.--Some results from the prophylactic treatment of severe hemophilia and Christmas disease are cited from the literature.     

Genetic induction of immune tolerance to human clotting factor VIII in a mouse model for hemophilia A

Patients with severe coagulation factor VIII deficiency require frequent infusions of human factor VIII (hFVIII) concentrates to treat life-threatening hemorrhages. Because these patients are immunologically hFVIII-naive, a significant treatment complication is the development of inhibitors or circulating alloantibodies against hFVIII, which bind the replaced glycoprotein, increase its plasma clearance, and inhibit its activity, preventing subsequent treatments from having a therapeutic effect. A genetic approach toward the induction of immunologic unresponsiveness to hFVIII has the conceptual advantage of a long-term, stable elimination of undesired immune responses against hFVIII. Here, we report that in a factor VIII (FVIII)-deficient mouse model for severe hemophilia A, genetic modification of donor bone marrow cells with a retroviral vector encoding hFVIII, and transplant to hemophiliac mouse recipients, results in the induction of immune tolerance to FVIII in 50% of treated animals after immunization with hFVIII, despite the fact that hFVIII protein or activity is undetectable. In tolerized animals, the titers of anti-hFVIII binding antibodies and of hFVIII inhibitor antibodies were significantly reduced, and there was evidence for hFVIII unresponsiveness in CD4(+) T cells. Importantly, the plasma clearance of hFVIII was significantly decreased in tolerized animals and was not significantly different from that seen in a FVIII-naive hemophiliac mouse. This model system will prove useful for the evaluation of genetic therapies for hFVIII immunomodulation and bring genetic therapies for hFVIII tolerance closer to clinical application for patients with hemophilia A.     

Blood coagulation in hemophilia A and hemophilia C

Tissue factor (TF)-induced coagulation was compared in contact pathway suppressed human blood from normal, factor VIII-deficient, and factor XI-deficient donors. The progress of the reaction was analyzed in quenched samples by immunoassay and immunoblotting for fibrinopeptide A (FPA), thrombin-antithrombin (TAT), factor V activation, and osteonectin. In hemophilia A blood (factor VIII:C <1%) treated with 25 pmol/L TF, clotting was significantly delayed versus normal, whereas replacement with recombinant factor VIII (1 U/mL) restored the clot time near normal values. Fibrinopeptide A release was slower over the course of the experiment than in normal blood or hemophilic blood with factor VIII replaced, but significant release was observed by the end of the experiment. Factor V activation was significantly impaired, with both the heavy and light chains presenting more slowly than in the normal or replacement cases. Differences in platelet activation (osteonectin release) between normal and factor VIII-deficient blood were small, with the midpoint of the profiles observed within 1 minute of each other. Thrombin generation during the propagation phase (subsequent to clotting) was greatly impaired in factor VIII deficiency, being depressed to less than 1/29 (<1.9 nmol TAT/L/min) the rate in normal blood (55 nmol TAT/L/min). Replacement with recombinant factor VIII normalized the rate of TAT generation. Thus, coagulation in hemophilia A blood at 25 pmol/L TF is impaired, with significantly slower thrombin generation than normal during the propagation phase; this reduced thrombin appears to affect FPA production and factor V activation more profoundly than platelet activation. At the same level of TF in factor XI-deficient blood (XI:C <2%), only minor differences in clotting or product formation (FPA, osteonectin, and factor Va) were observed. Using reduced levels of initiator (5 pmol/L TF), the reaction was more strongly influenced by factor XI deficiency. Clot formation was delayed from 11.1 to 15.7 minutes, which shortened to 9.7 minutes with factor XI replacement. The maximum thrombin generation rate observed ( approximately 37 nmol TAT/L/min) was approximately one third that for normal (110 nmol/L TAT/min) or with factor XI replacement (119 nmol TAT/L/min). FPA release, factor V activation, and release of platelet osteonectin were slower in factor XI-deficient blood than in normal blood. The data demonstrate that factor XI deficiency results in significantly delayed clot formation only at sufficiently low TF concentrations. However, even at these low TF concentrations, significant thrombin is generated in the propagation phase after formation of the initial clot in hemophilia C blood.     

Evaluation of adjuvants that enhance the effectiveness of antisense oligodeoxynucleotides

In this paper we present a new method for the detection of resistance to activated protein C (APC) that is based on direct measurement of the effect of APC on the cofactor activity of plasma factor Va. The factor V present in a diluted plasma sample was activated with thrombin and its sensitivity towards APC was subsequently determined by incubation with phospholipids and APC. The loss of factor Va cofactor activity was quantified in a prothrombinase system containing purified prothrombin, factor Xa and phospholipid vesicles and using a chromogenic assay for quantitation of thrombin formation. The reaction conditions were optimized in order to distinguish normal, heterozygous and homozygous APC-resistant plasmas. Maximal differences in the response of these plasmas towards APC were observed when factor Va was inactivated by APC in the absence of protein S and when the cofactor activity of factor Va was determined at a low factor Xa concentration (0.3 nM). Addition of 0.2 nM APC and 20 microM phospholipid vesicles to a 1000-fold diluted sample of thrombin-activated normal plasma resulted in loss of more than 85% of the cofactor activity factor Va within 6 min. Under the same conditions, APC inactivated approximately 60% and approximately 20% of the factor Va present in plasma samples from APC-resistant individuals that were heterozygous or homozygous for the mutation Arg506-->Gln in factor V, respectively. Discrimination between the plasma samples from normal and heterozygous and homozygous APC-resistant individuals was facilitated by introduction of the so-called APC-sensitivity ratio (APC-sr). The APC-sr was defined as the ratio of the factor Va cofactor activities determined in thrombin-activated plasma samples after 6 min incubation with or without 0.2 nM APC and was multiplied by 100 to obtain integers (APC-sr = ?factor Va+APC square root of factor Va-APC? x 100). Clear differences were observed between the APC-sr of plasmas from normal healthy volunteers (APC-sr: 8-20, n = 33) and from individuals that were heterozygous (APC-sr: 35-50, n = 17) or homozygous APC resistant (APC-sr: 82-88, n = 7). There was no mutual overlap between the APC-sr of normal plasmas and plasmas from heterozygous or homozygous APC resistant individuals (p < 0.0001). In all cases our test gave the same result at the DNA-based assay. Since the test is performed on a highly diluted plasma sample there is no interference by conditions that affect APC resistance tests that are based on clotting time determinations (e.g. coagulation factor deficiencies, oral anticoagulation, heparin treatment, the presence of lupus anticoagulants, pregnancy or the use of oral contraceptives). Furthermore, we show that part of the factor Va assay can be performed on an autoanalyzer which increases the number of plasma samples that can be handled simultaneously.     

Activated platelet aggregates in thrombotic thromboctyopenic purpura: decrease with plasma infusions and normalization in remission

Circulating activated platelet aggregates (aPA) were assayed by flow cytometry employing mAb alpha-CD62p in eight patients with thrombotic thrombocytopenic purpura (TTP). Elevation of aPA was observed in all patients in active stages of TTP; aPA normalized in remission. Plasma infusions with plasmapheresis decreased aPA in responding patients. The rise and fall of aPA preceded relapses and improvements, respectively. These changes were seen prior to the traditional indicators, LDH, haematocrit, and platelet count. Incubation of plasma from TTP patients with normal whole blood induced formation of aPA; this effect was significantly greater than that of plasmas from ITP patient controls (P < 0.01), suggesting the presence of an aPA-promoting factor in TTP plasma. Parallel experiments using a platelet aggregometer failed to detect effect of TTP plasma on normal blood. In summary, aPA appear to be a marker of disease activity, rising with relapse, falling with plasma therapy, and normalizing in remission. The flow cytometric assay of aPA is more sensitive than aggregometry in detecting the putative aPA-promoting factor in TTP.     

Molecular genetics of coagulation factor VIII gene and hemophilia A

This review summarizes the structure of human coagulation factor VIII gene and its deduced protein sequence and the molecular etiology of hemophilia A in man. The gross DNA rearrangements including the common inversions of factor VIII (which account for about 45% of severe hemophilia A patients), and the point mutations are discussed. The functional consequences of certain missense mutations are illustrated.     

Surgery in hemophilia A patients with factor VIII inhibitor: 10-year experience

Patients with hemophilia A and circulating anticoagulant (factor VIII inhibitor) present a difficult, even unsolvable problem, particularly if they require surgical treatment and the inhibitor titer is high. During the 1986-1995 period 29 surgical procedures on inhibitor hemophilia A patients were performed in our center. Each of the cases had an individual character, and all demanded special clinical treatment. Based on this experience we present the possibilities of hemostasis maintenance during the perioperative period with high doses of human or porcine factor VIII, aPCC, plasmapheresis, and extracorporeal antibody adsorption to protein A-Sepharose. In some patients hemostasis maintenance requires combined treatment. To induce immunotolerance in patients with inhibitor is the gold standard treatment because it is then possible to achieve proper hemostasis after factor VIII infusion. Various methods of immunotolerance induction have been discussed and compared with our experience with immunotolerance induction in 11 patients with small factor VIII doses (25 IU/kg twice a week) and the modified Malm? protocol in 15 patients.     

Evaluation of a modified APTT-based method for determination of APC resistance in plasma from patients on heparin or oral anticoagulant therapy

An APTT-based kit method (Coatest APC Resistance), modified by predilution 1+4 of sample plasma in a plasma diluent containing a heparin antagonist (V-DEF plasma), has been evaluated on plasmas from patients treated with unfractionated (n = 110) or either of three different low molecular heparins (n=44), or with oral anticoagulants (n=147). Irrespective of treatment, no difference was observed in the APC response as compared to untreated individuals (n=62), and a complete discrimination was obtained between individuals with a normal factor V genotype and those carrying the FV:Q506 mutation. Furthermore, in contrast to the original, APTT-based kit method, where anticoagulant therapy results in a prolongation of the APTT, the modified kit provided APTT values within the normal range for orally anticoagulated (INR< or =6) and for all heparin treated (< or =1 IU/mL) patients except for one with a suspected presence of phospholipid antibodies. Due to the predilution in V-DEF plasma, contamination with platelets up to 1.5 x 10(4)/microL had a negligible effect on analysis of frozen plasmas regarding their classification as normal or abnormal. Analyses of fresh plasmas show no influence at platelet counts up to 6x10(4)/microL. Consequently, negligible differences in APC ratios were obtained between fresh and frozen plasmas. In conclusion, the modified kit method is applicable to plasmas from anticoagulated patients as well as from untreated individuals, allowing a safe assignment regarding the presence or absence of the FV:Q506 genotype.     

Prophylactic use of factor VIII: an economic evaluation

BACKGROUND: Since the introduction of exogenous factor VIII therapy, several studies have explored the clinical benefits of prophylactic use of factor VIII. Little research, though, has focused on the economic aspects of this regimen. We conducted a cost analysis using data from the Orthopedic Outcomes Study, a prospective, cross-national study of the clinical outcomes associated with different patterns of factor VIII utilization to examine the health care costs incurred and expenditures averted in patients receiving on-demand versus prophylactic use of factor VIII in hemophilia. METHODS AND ANALYSIS: 831 patients with severe hemophilia aged 1 to 31 years, from 19 centers around the world were included in the cost analysis. Patients were categorized into three groups according to the number of weeks during the study years in which they received prophylactic regimens of factor VIII. For each subject, we estimated the costs of hospitalization, surgery, days lost from school or work, and factor VIII utilization. Costs were then stratified by age and by joint score to assess confounding, and a multivariate model developed to determine the relationship between use of factor VIII prophylaxis and total costs, while controlling for potential confounders. RESULTS: Patients who received factor VIII episodically incurred substantially greater disability-related costs (days lost from school or work, days hospitalized due to hemophilia, surgery) than patients who received factor VIII prophylactically for some or all of the study period. For all treatment regimens, most disability-related costs were accounted for by hospitalization for hemophilia-related conditions. The cost of factor VIII itself was substantial in all treatment categories but was highest among patients who received year-round prophylaxis, exceeding the savings resulting from reduced disability and other health care expenditures. CONCLUSIONS: Reductions in non-factor health care costs and disability associated with prophylactic use of factor VIII in hemophilia were substantial and helped somewhat to offset the much higher costs of this regimen. For certain subgroups, frequent episodic treatment may be more expensive than full-time prophylaxis. However, because of the very high cost of year-round prophylactic use of factor VIII, total health care expenditures were highest among patients receiving this therapeutic regimen. However, because prophylaxis clearly offers important clinical benefits, this approach may be warranted on medical rather than economic grounds.     

The natural history of the immune response to exogenous factor VIII in severe haemophilia A

The development of inhibitory antibodies to factor VIII (fVIII) in severe haemophilia A patients is a serious therapeutic complication. Using a highly sensitive immunoprecipitation (IP) assay which measures all anti-fVIII antibodies, we have tested severe haemophilic plasmas from two clinical studies. Inhibitor titres in the range of 0.4 to 1 Bethesda units/ml (BU/ml) could not be verified by IP as being due to an immune response to fVIII in 35% of plasmas tested. Low fVIII recoveries were likewise correlated with the presence of antibodies in 29% of plasmas tested. However, 16% of plasmas without inhibitor titres had immune responses as measured by IP. The rapidity of antibody appearance did not allow their effective detection by IP before development of inhibitor titres. These results suggest that the IP assay can provide a valuable confirmation of anti-fVIII antibody production when the Bethesda assay is low or negative and where clinical observations suggest their presence, but they cannot be used reliably to detect early immune responses.     

Phenotype and genotype expression in pseudohomozygous factor VLEIDEN : the need for phenotype analysis

The presence of a DNA mutation is frequently used to define a disease or a risk state. Because DNA typing has become easy and convenient in contrast to protein characterization, it is generally assumed that a mutation if present (or not) at the DNA level will be also present (or not) in the corresponding protein. However, discrepancies between phenotype and genotype can occur. A point mutation in the coagulation factor V gene (G1691-->A, resulting in an Arg506-->Gln amino acid substitution in the factor V molecule [factor VLEIDEN], leading to activated protein C resistance) is the most common genetic risk factor for familial thrombophilia. A pseudohomozygous factor VLEIDEN phenotype would occur if a heterozygous individual for factor VLEIDEN also did not express the "normal" (non-Leiden) factor V allele. However, to date, no data have been available to confirm the presence of only the factor VLEIDEN form in the plasma of these individuals. Platelet mRNA from 2 presumed pseudohomozygous patients and their family members was isolated, the amplified partial cDNAs were sequenced or restricted, and the allelic bands were quantified. Both patients were found to be heterozygous for the G1691-->A substitution at both the DNA and mRNA levels. The presence of either the normal or mutated form of factor V in the patients' plasmas was investigated using a monoclonal antibody to factor V that recognizes an epitope located between residues 307 and 506 of the factor Va heavy chain. No normal factor V could be detected in the plasmas of the 2 propositi. The present data demonstrate absence of a correlation between genotype at position 1691 (at the DNA and mRNA levels) and the corresponding phenotype data found in the plasmas of patients with pseudohomozygous factor VLEIDEN. Overall, these data suggest the existence of heterogeneous genetic "lesions," which interfere with factor V expression, processing, secretion, and/or stability. Because the presence of the factor VLEIDEN molecule in plasma is directly related to pathology, identification and quantification of the circulating forms of factor V in plasma may be required for the diagnosis of individuals with activated protein C resistance.