Correction of the coagulation defect in hemophilia A mice through factor VIII expression in skin

To test the hypothesis that factor VIII expressed in the epidermis can correct hemophilia A, we generated transgenic mice in a factor VIII-deficient background that express human factor VIII under control of the involucrin promoter. Mice from 5 transgenic lines had both phenotypic correction and plasma factor VIII activity. In addition to the skin, however, some factor VIII expression was detected in other tissues that have stratified squamous epithelia. To determine whether an exclusively cutaneous source of factor VIII could correct factor VIII deficiency, we grafted skin explants from transgenic mice onto mice that are double knockouts for the factor VIII and RAG-1 genes. Two graft recipients had plasma factor VIII activity of 4% to 20% of normal and improved whole blood clotting compared with factor VIII-deficient mice. Thus, expression of factor VIII from the epidermis can correct hemophilia A mice, thereby supporting the feasibility of cutaneous gene therapy for systemic disease. (Blood. 2000;95:2799-2805)     

Results of secondary prophylaxis in children with severe hemophilia

In this study, 13 children with severe hemophilia were given routine replacement infusions of factor VIII or IX to treat arthropathy. The children who had a mean age of 6.9 years (range 2.0–12.5) at initiation of prophylaxis had experienced an average of 43 acute hemorrhages (range 8–127) in the year prior to prophylaxis, of which a mean of 24 (range 5–46) were into joints. Therapy was begun in five children, using factor VIII concentrate at 20 U/kg three times a week, and one boy received factor IX concentrate 40 U/kg twice a week. This dose schedule was inadequate for three factor VIII-deficient boys and for the one factor IX-deficient boy. Two of three factor VIII-deficient boys responded to an increase to 30 U/kg prior to the 3-day interval. The dose frequency was increased to three times a week for the factor IX-deficient boy, but he continued to bleed and was taken to synovectomy. One of the original five factor VIII-deficient boys plus seven other factor VIII-deficient boys were begun on factor VIII 20 U/kg every other day; 3 boys ceased bleeding. Trough factor VIII levels were measured 24 hr after an infusion in the five boys who continued to bleed. Factor VIII dosage was adjusted to achieve a trough level of >1%; 4 responded to an increase in the dose of factor VIII; 1 had an adequate trough but, due to compliance issues, was taken to synovectomy. Serial clinical and radiographic assessments determined stabilization of joint disease in more than one-half of the boys. No child showed reversal of abnormal radiographic findings. Institution of aggressive factor VIII and IX concentrate in children with established hemophilic arthropathy does not reverse joint disease but may alter the clinical course of hemophilia. Future studies to compare this intervention with primary prophylaxis instituted prior to the onset of recurrent joint hemorrhage are warranted. © 1994 Wiley-Liss, Inc.     

Immunologic status of hemophilia patients treated with cryoprecipitate or lyophilized concentrate

We evaluated 37 patients with moderate or severe hemophilia A and six patients with severe factor IX deficiency for clinical or laboratory evidence of immune abnormalities. Patients were assigned to one of four groups according to the type of clotting factor replacement. Twenty patients had received only cryoprecipitate during the two years preceding the evaluation (group I); 11 additional patients were treated predominantly with cryoprecipitate but had also received up to nine bottles of factor VIII concentrate (group II); six patients received factor VIII concentrate (group III); six patients received factor IX concentrate (group IV). There was no clinical or laboratory evidence of immunodeficiency among the 43 patients. The mean absolute number of Th cells was normal in all patient groups, but the mean absolute number of Ts cells was increased compared with controls, both in patients treated with cryoprecipitate and in patients treated with factor VIII or factor IX concentrate. There was no correlation between the Th/Ts ratio and patient age, alanine aminotransferase level, hepatitis serology, in vitro lymphocyte function, or amount of clotting factor administered. Our observations demonstrate that the volunteer or commercial origin of clotting factor replacement cannot fully explain the alterations in lymphocyte subset distribution previously described in patients with hemophilia A.     

Specific and global coagulation assays in the diagnosis of discrepant mild hemophilia A

The activity of the factor VIII coagulation protein can be measured by three methods: a one or two-stage clotting assay and a chromogenic assay. The factor VIII activity of most individuals with mild hemophilia A is the same regardless of which method is employed. However, approximately 30% of patients show marked discrepancies in factor VIII activity measured with the different methods. The objective of this study was to investigate the incidence of assay discrepancy in our center, assess the impact of alternative reagents on factor VIII activity assays and determine the usefulness of global assays of hemostasis in mild hemophilia A. Factor VIII activity was measured in 84 individuals with mild hemophilia A using different reagents. Assay discrepancy was defined as a two-fold or greater difference between the results of the one-stage and two-stage clotting assays. Rotational thromboelastometry and calibrated automated thrombography were performed. Assay discrepancy was observed in 31% of individuals; 12% with lower activity in the two-stage assay and 19% with lower activity in the one-stage assay. The phenotype could not always be predicted from the individual’s genotype. Chromogenic assays were shown to be a suitable alternative to the two-stage clotting assay. Thromboelastometry was found to have poor sensitivity in hemophilia. Calibrated automated thrombography supported the results obtained by the two-stage and chromogenic assays. The current international guidelines do not define the type of assay to be used in the diagnosis of mild hemophilia A and some patients could be misclassified as normal. In our study, 4% of patients would not have been diagnosed on the basis of the one-stage factor VIII assay. Laboratories should use both one stage and chromogenic (or two-stage) assays in the diagnosis of patients with possible hemophilia A.     

Combined deficiency of factor V and factor VIII. A report of another case

Summary A patient with combined factor V and factor VIII deficiency is presented. The bleeding manifestations were: easy bruising, post-traumatic bleeding, bleeding after tooth extractions. The main laboratory feature was a prolonged partial thromboplastin time which was corrected by the addition of adsorbed normal plasma but not by the addition of normal serum, hemophilia A plasma or plasma of another patient with combined factor V and factor VIII deficiency. The thromboplastin generation test was clearly abnormal and was corrected by the addition of adsorbed normal plasma but not by the addition of normal serum. Prothrombin consumption was also defective.Prothrombin time was slightly prolonged too, Thrombin time, platelet and vascular tests were within normal limits and there was no hyperfibrinolysis. Factor VIII was 8% of normal, whereas factor V was 14% of normal. Factor VIII associated antigen was normal. All other clotting factors were within normal limits.The parents of the propositus were consanguineous (first cousins) but had normal factor V and factor VIII activity and normal factor VIII antigen. The same was true for other family members. The hereditary transmission of the condition appears autosomal recessive.This study was supported in part by a grant from the C.N.R. (grant CT. 74.00189.04).     

Routine Tests as Measures of the Total Intrinsic Blood Clotting Potential

The whole blood clotting time (WBCT) determined in silicone-treated tubes was compared with the recalcification time of citrated plasma in silicone tubes (RTST), the partial thromboplastin time (PTT), and the activated partial thromboplastin time (APTT) in a group of dicumarol-treated patients. By linear regression analyses, correlation coefficients of about 0.7 were found when WBCT was compared with RTST and APTT. In a group of 9 patients with only moderately decreased factor II, VII, X activity, the clotting times of the investigated methods exceeded the upper normal limits. In seven of these patients two or more of the tests coincided. Although there were considerable disaggrements among the tests, it is probable that they at least partly measure the same qualities. A quality control study over more than one year showed that the PTT test varied considerably but that the APTT test carried out with the commercial reagent Platelin plus Activator varied remarkably little. To test the total clotting potential of plasma in routine laboratory work, APTT seems to be the test of choice.     

A female hemophilia A combined with hereditary coagulation factor XII deficiency: a case report.

A 2-year-old Japanese girl with easy bruising and arthropathy was demonstrated to have severe hemophilia A (Factor VIII activity: less than 0.01 U/ml). She had normal 46XX karyotype. Her brother also had hemophilia A, and her mother and grandmother seem to be hemophiliac carriers. Additionally, activated partial thromboplastin time (APTT) of the patient was disproportionately prolonged and there were reduced levels of coagulation factor XII in the patients and members of the maternal trait which are compatible with heterozygous factor XII deficiency. Her father had both normal factor VIII and factor XII levels. Southern blotting analysis of genomic DNA from the propositus and family members with factor VIII and factor XII DNA probes revealed no gross alterations. This patient represents a female hemophilia A combined with heterozygous factor XII deficiency. Nonrandom inactivation of a normal X-chromosome (extreme lyonization) may be the basis for the expression of hemophilia A in this female patient.     

Assessment of Actin FS and Actin FSL sensitivity to specific clotting factor deficiencies

We present a two centre study designed to assess the sensitivity of Actin FS and Actin FSL to deficiencies of factor VIII, IX, XI or XII. The study was undertaken at two centres to avoid bias due to the investigations being undertaken on one analyser. Samples from patients with a factor VIII (n = 36, F VIII = < 1.0–50 iu/dl), factor IX (n = 22, F IX = 2–48 iu/dl), factor XI (n = 23, F XI = 5–50 u/dl) or a factor XII (n = 18, F XII = 1–50 u/dl) deficient state were studied. Activated partial thromboplastin times (APTT) were determined using two batches of Actin FS and of Actin FSL; comparison of APTT results between centres was facilitated by the conversion of clotting times to ratios (test ÷geometric mean normal clotting time). APTT ratios were considered to be elevated if greater than two standard deviations above the mean normal. The factor deficient status of each sample was verified by assaying all samples for factors VIII, IX, XI and XII. Clotting factor assays were performed on a Sysmex CA-1000^? fitted with research software, which permitted the auto-dilution and testing of three serial dilution of both a reference preparation and each patient's sample. Assay results were calculated using parallel-line Bioassay principles. This procedure allowed for variation in clotting times due to the effect of temporal drift of any of the reagents within the assay system. Actin FS and Actin FSL demonstrate acceptable sensitivity to factor VIII deficiency, however, both reagents failed to detect a large proportion of factor XI (17.4% and 30.4% of samples, respectively) and factor XII (66.7% and 72.2%, respectively) deficiencies. The detection rate with Actin FSL for factor IX deficiency was also poor (36.4% not detected). As factor IX and XI deficiencies are both associated with haemorrhagic disorders, the inability of these reagents to detect such abnormalities gave cause for concern.     

Factor VIII: structure and function in blood clotting

Factor VIII (antihemophilic factor) is the protein that is deficient or defective in patients with classical hemophilia and Von Willebrand syndrome. Factor VIII in plasma is thought to be associated in a complex with the highest molecular weight multimers of another glycoprotein, Von Willebrand protein. Highly purified human factor VIII appears to have an Mr of between 200,000 and 300,000 and to consist of several polypeptide chains. The concentration of factor VIII in plasma is around 100-200 ng/ml, equivalent to around 1 nM. The purified proteins retain one or more of the known properties of factor VIII, including the acceleration of factor IXa-mediated activation of factor X, ability to be activated by thrombin and factor Xa, inactivation by activated protein C, and by human antibodies to factor VIII. Among the known clotting factors, factors VIII and V are exceptional in not possessing enzymatic activity. Factors IXa and VIII and X appear to form a functional complex, all of which need to be present and active simultaneously for optimal activation of factor X. The mechanism by which factor VIII promotes activation of factor X by factor IXa is not known, but the major effect is to increase the rate of the reaction. Following treatment of factor VIII with thrombin, a new and smaller polypeptide Mr around 70,000 +/- 5,000 is produced. Factors IXa and Xa also have been reported to activate factor VIII. It is not known whether limited proteolytic cleavage is required absolutely for the expression of factor VIII activity or if it only increases an activity already expressed by the uncleaved protein. Factor VIII is inactivated by thrombin and by activated protein C. Thus, factor VIII can be modulated by at least four of the serine proteases in the clotting system. A major goal for future research is to increase our understanding of the role in blood clotting played by factor VIII, and to apply this information to clinical problems which result from inherited abnormalities of factor VIII.     

Acquired hemophilia A with sigmoid colon cancer: successful treatment with rituximab followed by sigmoidectomy

Acquired hemophilia A is a rare and potentially fatal condition of coagulopathy caused by autoantibodies against clotting factor VIII (factor VIII inhibitor). We report a case of a 63-year-old woman, who presented with a sudden onset of severe hemorrhagic tendency with exclusively prolonged activated partial thromboplastin time (APTT). She was diagnosed with acquired hemophilia A due to a decrease in factor VIII activity and a high titer of factor VIII inhibitor. Hemorrhage was well controlled by recombinant activated factor VII. Although the level of factor VIII inhibitor did not decline with prednisolone and cyclophosphamide, it became undetectable with rituximab. In parallel with controlling hemorrhage, malignancy, which may cause acquired hemophilia A, was searched for and sigmoid colon cancer was found. After the eradication of factor VIII inhibitor, surgical resection was performed uneventfully. Thereafter, acquired hemophilia A has been in complete remission without any additional therapy. The present case suggests the efficacy of rituximab for refractory acquired hemophilia A and the importance of the identification of underlying diseases that can cause acquired hemophilia A.     

Chromogenic factor VIII activity assay

Factor VIII (FVIII) may be measured by three different methodologies in the clinical laboratory: one‐stage clotting assay, two‐stage clotting assay, and chromogenic assay. These assays differ in ease of use, variety of reagents available, sensitivity to mild hemophilia A, and interference from lupus anticoagulants. This review will outline the methodology for each of the FVIII activity assays, with a discussion of assay interferences and variability. In some cases, chromogenic FVIII activity assays may be preferable to clot‐based assays, and these clinical situations will be reviewed as well. Am. J. Hematol. 89:781–784, 2014. © 2014 Wiley Periodicals, Inc.     

Coagulation disorders and inhibitors of coagulation in children from Mansoura,Egypt

Disorders of coagulation in children often prove challenging to the medical care team. The aims of this study were to assess the spectrum and prevalence of coagulation disorders among children attending Mansoura University Children Hospital (MUCH), Mansoura, Egypt. A total of 105 pediatric patients were referred to MUCH. They were divided into two groups: congenital coagulation disorders (75 cases, age 45.36 ± 48.59 months), and acquired coagulation disorders (30 cases, age 56.13 ± 61.61 months). All patients were subjected to thorough history taking including the nature of bleeding, family, past history, mode of inheritance, and detailed physical findings. Hemostatic tests included: platelet count, bleeding time (BT), prothrombin time (PT), activated partial thromboplastin time (APTT), thrombin time (TT). Specific tests in the congenital group include assay of coagulation factors according to each disorder, Von Willebrand factor assay, ristocetin aggregation test, APTT mixing study for detection of inhibitors in complicated hemophilia cases, F VIII C to VWAg ratio with cut off 0.7 for detection of carriers in some hemophilia A families. Congenital disorders constituted 71.4% of the studied cases vs. 28.6% for acquired disorders. Hemophilia A (42.85%), hemophilia B (14.28%) and liver diseases (14.28%) represented the majority of the studied cases. Mild and moderate cases of hemophilia A and B are more frequent than severe cases in both types. Male sex is more frequent than female in the congenital group (94.7 vs. 5.3%, P < 0.001). Direct correlation existed between factor level assay and severity of hemophilia (r = 0.73, P = 0.006). Three mothers and one sister were identified as carrier out of four families. Anti-clotting factors inhibitor was detected in 18.2% of patients with hemophilia A and in 9.1% with hemophilia B. In conclusion, our study found that hemophilias are the most prevalent congenital coagulation disorders among children. Attention must be given for detection of hemophilia carriers and inhibitors of clotting factors.     

Pattern of factor VIII inhibitors in patients with hemophilia A in the north east of Iran

This survey was conducted to evaluate coagulation factor VIII:C inhibitors among 102 hemophilia A patients from different cities of Khorasan province in north east of Iran in order to identify and characterize the pattern of inhibitor formation in these patients population. For this purpose, we randomly obtained plasma samples of 102 hemophilia A patients (44 patients with severe, 28 patients with intermediate and 30 patients with mild hemophilia A) and studied them using two tests: the APTT mix and Bethesda test were performed. In the whole group 20 patients (19.6%) factor VIII inhibitors were detected. These were in 11 patients with severe, five patients with intermediate and four patients with mild hemophilia A. None of patients with hemophilia A had previously been studied for the presence of an inhibitor, so there was no existing history of inhibitor evaluation.     

Comparison of bedside and hospital laboratory coagulation studies during and after coronary intervention

The activated clotting time is routinely used to monitor anticoagulation during coronary intervention, whereas the hospital laboratory APTT guides pre- and postprocedure heparin therapy. An optimal coagulation test for patients undergoing percutaneous revascularization would provide a rapid and accurate assessment of anticoagulation throughout a broad range of heparin therapy. We studied the relationships of the bedside whole blood APTT, ACT, and the laboratory APTT in 166 patients undergoing coronary intervation. The whole blood APTT correlated closely with the laboratory APTT (range 18-80 sec) (r = .75), whereas the ACT and laboratory APTT had only a fair correlation (r = .42). Also, the whole blood APTT demonstrated a strong correlation with the ACT throughout the range of heparin therapy for intervention (r = .81). The diagnostic accuracy of the whole blood APTT, based on the receiver operating characteristic curve, was significantly better than that for the ACT in determining the anticoagulation status. The whole blood APTT obtained by bedside monitoring provides a rapid and accurate assessment of anticoagulation throughout the range of heparin dosing associated with coronary intervention. In situations in which an adequate assessment of residual anticoagulation is necessary, the whole blood APTT is superior to the ACT and probably should be the method of choice. © 1995 Wiley-Liss, Inc.     

Prevention and treatment of factor VIII inhibitors in murine hemophilia A

Inhibitory antibody formation is a major complication of factor VIII replacement therapy in patients with hemophilia A. To better understand the pathogenesis of this immunologic reaction, we evaluated the role of T-cell costimulatory signals for antifactor VIII antibody formation in a murine model of hemophilia A. Repeated intravenous injections of factor VIII in these factor VIII-deficient mice induced an antifactor VIII inhibitor antibody response. This response was shown to be T-cell dependent by its absence in hemophilic mice also deficient for the T-cell costimulatory ligand B7-2. In separate experiments, injection of murine CTLA4-Ig completely blocked the primary response to factor VIII in hemophilic mice with intact B7 function. This reagent also prevented or diminished further increases in antifactor VIII when given to hemophilic mice with low antifactor VIII antibody titers. These studies suggest that strategies targeting the B7-CD28 pathway are potential therapies to prevent and treat inhibitory antifactor VIII antibodies. Moreover, because the development of antibodies to replaced proteins may limit the success of many human gene therapy approaches, our results may be broadly applicable. (Blood. 2000;95:1324-1329)     

The Pennsylvania hemophilia program 1973-1978

In Pennsylvania, the prevalence of hemophilia is one per 10,000 males. Factor VIII deficiency is five times more frequent than Factor IX deficiency, and 34% of the patients have no relatives affected with the disease. The mean age is 23 years old, and 50% of the patients are less than 20 years old. Approximately one-third of the patients with Factor VIII deficiency and one fourth of the patients with Factor IX deficiency have levels of < 0.01 μ/ml. By clinical criteria, 55% of those with Factor VIII deficiency are severe compared to 45% of those with Factor IX deficiency. Factor VIII-deficient patients are treated an average of 18 times per year compared to ten times per year for patients with Factor IX deficiency. Hemarthroses account for 70% of the hemorrhages treated and for 40% of the concentrate usage. Home therapy patients use an average of 45,950 Factor VIII units per year at a cost of $4,170 per patient and their use accounts for 60% of the total Factor VIII usage of 1.7 million units. Less than five days per patient per year are lost from school or work because of bleeding, and patients are hospitalized for bleeding an average of only two to three days per patient per year. Adverse immediate reactions to therapy are infrequent. Five percent of patients have persistence of the hepatitis B virus, and 7.5% have inhibitors. The mortality rate is 0.04% per year, with half of the deaths being hemophilia-related.     

Development of a simple chromogenic factor VIII assay for clinical use

The aim of this study was the development of a simple chromogenic factor VIII assay for practical clinical use. The criteria that the assay fulfils are: (1) The method is so sensitive that even 1% factor VIII in human plasma is easily detected. (2) The method is linear in the amount of factor VIII from 0 to 200% in plasma. (3) The pipetting scheme is very simple; two reagents are prepared, reagent 1 (factor IXa, thrombin, Ca2+ and phospholipids) and reagent 2 (factor X). Then we pipet at t = 0 s, 100 microliters diluted plasma + 100 microliters reagent 1 in a reaction tube; at t = 30 s, 100 microliters reagent 2 in the same tube and at t = 90 s, 200 microliters of the reaction mixture in a cuvette with 700 microliters EDTA buffer (stop buffer) and the formed factor Xa is measured with a chromogenic substrate. (4) The reaction components are stable during at least a whole working day. Factor VIII was measured in an assay using bovine clotting factors, so one avoids the risk of viral infections, which one might catch by working with clotting factors isolated from human plasma.     

Thrombin generation in haemophilia A patients with mutations causing factor VIII assay discrepancy

Summary. Up to 40% of patients with mild haemophilia A have a discrepancy whereby factor VIII (FVIII) measurements by a two‐stage chromogenic assay (FVIII:C_CH) are disproportionately reduced compared with the FVIII one‐stage clotting value (FVIII:C). Which assay best reflects the coagulation potential and clinical phenotype in this patient group is of clinical significance, yet remains unclear. We have assessed the global coagulant ability of haemophilia patients with FVIII assay discrepancy using calibrated automated thrombography (CAT). A total of 18 patients with mutations Arg531His/Cys or Arg698Trp causing FVIII discrepancy were investigated, together with 12 haemophilia patients with concordant FVIII values and 15 normal controls. Factor VIII levels in all patients and controls were measured using both one‐stage clotting assay and two‐stage chromogenic assay. Thrombin generation was assessed in platelet‐poor plasma by CAT using a low tissue factor concentration (1 pm ). FVIII:C_CH values were below normal in all patients, and in the discrepant group were between 1.5‐ and 8‐fold lower than FVIII:C values. CAT parameters were affected in all haemophilia patients. The endogenous thrombin potential (ETP) was reduced to 58–67% of the mean normal value (1301 nm min^?1), whereas peak thrombin was further reduced to 27–30% of the mean normal value (178 nm ) in both discrepant and concordant patient groups. Analysis of the discrepant patient group showed the most significant correlation between the one‐stage FVIII:C assay and ETP (r² = 0.44) and peak thrombin parameters (r² = 0.27).     

Measurement of factor VIII procoagulant antigen in normal subjects and in hemophilia A patients by an immunoradiometric assay and by an enzyme-linked immunosorbent assay

Factor VIII coagulant antigen (FVIII:Ag) and FVIII coagulant activity (FVIII:C) were measured in 102 healthy individuals, in 5 hemophilia A carriers and in 21 hemophilia A patients before and after infusion of heat-treated high-purity FVIII concentrates. Factor VIII:Ag was determined by a solid-phase micro enzyme-linked immunosorbent assay (ELISA) using monoclonal antibodies and by a conventional solid-phase immunoradiometric assay (IRMA). Factor VIII:C was assessed using a one-stage assay. The micro ELISA was decidedly more precise than the IRMA. There was a close correlation between the results obtained by the three assays in the plasma of healthy subjects and in hemophilia A carriers. After transfusion of FVIII concentrates to hemophilia A patients, the FVIII:Ag recoveries were significantly lower than the FVIII:C recoveries and the biological half-life of FVIII:Ag was significantly shorter than for FVIII:C. The calculated half-life of FVIII:C was longer than in any previous study.     

Alteration in the laboratory profile of a lupus anticoagulant in a patient with non‐Hodgkin's lymphoma

We describe a patient with non‐Hodgkin's lymphoma who developed a lupus anticoagulant (LA) detectable by activated partial thromboplastin time (APTT), dilute Russell's viper venom time (DRVVT) and kaolin clotting time (KCT). IgM anticardiolipin antibodies (ACA) were elevated. At a later admission, and following treatment for the lymphoma, routine coagulation screening showed an elevated prothrombin time (PT) without correction in mixing tests using a recombinant thromboplastin. Routine APTT was below the reference range and ACA levels were normal. Raw data for one‐stage factor assays demonstrated the presence of an inhibitor. Analysis for LA was undertaken by DRVVT, KCT, activated seven lupus anticoagulant assay, Taipan snake venom time, platelet neutralisation procedures (PNP), Ecarin time and PT using rabbit brain thromboplastin. The results revealed a LA capable of prolonging the clotting times of the PNPs and PT using recombinant thromboplastin, but that was corrected using Ecarin venom, modified PNP and brain thromboplastin. The antibody also demonstrated the lupus anticoagulant co‐factor effect. The factor VIII : C was markedly raised which may have masked the LA in the APTT. The changing laboratory profile over time demonstrates the effects of LA heterogeneity and variations in sensitivity and specificity of assays for the detection of antiphospholipid antibodies.