The phenotypic and genetic assessment of protein C deficiency.

This paper outlines the methods and approaches used for the laboratory detection and investigation of protein C (PC) deficiency. It does not make recommendations as to which patients should have thrombophilia testing performed; this should be done in line with local guidance. Interpretation of PC level is complicated because level varies with age, and many conditions can cause acquired deficiency. Protein C is most usually measured by chromogenic assay as a part of the thrombophilia screen. There exists, however, a very small group of individuals with significant PC deficiency, in whom the chromogenic PC assay is normal. The coagulometric assay of PC is more sensitive to these rare defects, but these assays may lack specificity. Genetic analysis allows definitive diagnosis and may be useful in confirming that deficiency is inherited and not acquired and is particularly valuable in families with severe PC deficiency.

Clinical multicenter evaluation of a new FXa-based Antithrombin assay.

INTRODUCTION: The determination of functional Antithrombin is a central part of thrombophilia screening. In this multicenter study, a new FXa-based method (INNOVANCE® Antithrombin) was evaluated on four different analyzers. METHODS: The INNOVANCE Antithrombin method was evaluated by precision and reference interval studies and by comparing the new method with established methods through parallel measurement of samples from 249 patients and 151 apparently healthy individuals. RESULTS: The INNOVANCE Antithrombin assay demonstrated on all analyzers repeatability coefficients of variation (CVs) ≤ 3.2% and within-device and between-run CVs ≤ 6.9%. The reference intervals of all analyzers are comparable with 2.5th percentiles between 80% and 85% of normal. The INNOVANCE Antithrombin and the FIIa-based Berichrom® AT III (A) methods demonstrated good concordance with correlation coefficients of r = 0.908 or higher. The INNOVANCE Antithrombin method demonstrated furthermore an excellent comparability with the STA® Antithrombin III assay and an acceptable comparability with the Coamatic® LR Antithrombin assay. The patients with congenital deficiency (n = 31) were identified with all assays except for the patients carrying the P41L heparin-binding site mutation, which was only identified with the INNOVANCE Antithrombin and the STA Antithrombin III methods. CONCLUSION: The INNOVANCE Antithrombin assay has high sensitivity for Antithrombin deficiencies and is reliable, precise and suitable for routine clinical use.

The phenotypic and genetic assessment of antithrombin deficiency.

INTRODUCTION: Antithrombin (AT) deficiency is associated with an increased risk of deep vein thrombosis and pulmonary embolism which are major causes of morbidity and death. The incidence of deficiency in healthy populations has been reported to vary from 1/600 to 1/5000, with the variation being due to the different populations studied and detection methods used. When reduced activity levels are identified it is important to measure the AT antigen levels to differentiate type I from type II disorders, as type II defects have varying thrombotic risk. METHODS: Functional AT assays detect the ability of AT to inactivate thrombin or factor Xa, and AT antigen assays detect the quantity of AT in plasma. In functional assays, reducing the incubation time of sample with enzyme/heparin reagent may increase sensitivity to type II defects. An excess of antigen over activity level suggests the presence of functionally defective AT, which can be characterized further by assaying AT in the absence of heparin, electrophoresis to investigate the ability of heparin to bind to AT, and gene sequencing. RESULTS: Many patients with AT deficiency have a type II defect and these defects may not be detected by all routine diagnostic assays. Assays using human thrombin may lack specificity and assays that use factor Xa may fail to detect the common variant, AT Cambridge II, which can be detected by assays using bovine thrombin, especially if activity is compared to antigen by ratio. Factor Xa based assays may be particularly sensitive to certain heparin binding defects, and sensitivity of assays to both heparin binding and reactive site defects can be improved by shortening the incubation time with enzyme. CONCLUSION: uAT activity assays are essential for the detection of AT deficiency because type II defects are relatively common in patients with heritable deficiency. No one functional assay can be assumed to detect all forms of AT deficiency, and assays can sometimes be improved by reducing reaction time of AT with thrombin or factor Xa.

Marked discrepancy between coagulometric protein C activity assays with the pro-thrombotic protein C Asn2Ile substitution.

INTRODUCTION: Protein C (PC) Asn2Ile is a rare pro-thrombotic variant in which loss of anticoagulant function in vivo is likely to result from defective PC binding to the endothelial PC receptor and phospholipid. METHODS: To characterize the consequences of this functional defect on the diagnostic performance of commercial PC activity assays, we performed one antigen, three chromogenic and three coagulometric assays on plasma from a subject who was heterozygous for the PC Asn2Ile substitution. RESULTS: As anticipated, the PC antigen (96.2 IU/dl) and chromogenic PC activity assays (98.4 IU/dl) were insensitive to PC Asn2Ile, which has intact enzymatic activity and is secreted normally. There was a marked reduction in apparent PC activity by STACLOT coagulometric assay (50.4 IU/dl). However, there was only a small reduction in apparent PC activity by CRYOcheck Clot C assay (69.5 IU/dl) and by HemosIL ProClot assay, the PC activity was within the laboratory reference range (91 IU/dl). This discrepancy between coagulometric assays could not be explained by lupus anticoagulant, activated PC resistance or elevated plasma factor VIII activity. CONCLUSION: We demonstrate that coagulometric assays are not equally sensitive to clinically important functional defects of PC and that multiple assays may be required to identify all variants.

The effect of tissue factor concentration on calibrated automated thrombography in the presence of inhibitor bypass agents.

Thrombin generation has been suggested as a method to monitor treatment with factor eight inhibitor bypassing activity (FEIBA) or recombinant FVIIa (rFVIIa). The sensitivity of the assay for individual coagulation factors is dependent on the tissue factor (TF) concentration. An inverse relation between the rFVIIa concentration needed to shorten the clotting time and TF concentration has been shown but the data on thrombin generation are inconsistent. Information on TF concentration in measurements with FEIBA is limited. We studied the influence of TF concentration (1 and 5 pM) on thrombin generation through spiking experiments with rFVIIa and/or FEIBA in the plasma of severe haemophilia A patients and after four and three treatment episodes, respectively, using the calibrated automated thrombin generation assay (CAT) in platelet poor plasma. Spiking with FEIBA showed a linear relation with the endogenous thrombin potential (ETP)/peak at 1 pM but substrate depletion at 5 pM. Spiking with rFVIIa showed a near linear dose-response relation with the ETP/peak at 1 pm but only a shortening of the initiation phase at 5 pM. Similar effects were present in post-treatment samples. FEIBA acted synergistically with rFVIIa. This suggest a role for CAT in monitoring inhibitor bypass treatment but low TF concentrations are required to avoid substrate depletion with FEIBA and to demonstrate the effect of rFVIIa.

Evaluation of a new venom-based clotting assay of protein C.

Congenital protein C deficiency significantly increases the risk of venous thromboembolism, a serious and potentially lethal condition. Protein C levels can be determined by chromogenic, clotting and antigenic assays, each type of assay has differences in specificity and sensitivity to protein C deficiency. In principle, clotting-based assays of protein C are preferred over chromogenic assays, as they can detect some rare mutations that are missed by the chromogenic assay, however, clotting-based assays may be prone to inaccuracy because of poor specificity. We have evaluated a new venom-based clotting assay of protein C, and optimized it for use on Sysmex CA-1500 analyser. The assay was linear from 0 to 130 U/dl, a normal plasma demonstrated good inter-assay precision, with a coefficient of variation of 4.8%. The assay compared well with antigenic- and venom-based chromogenic protein C assay in normal individuals, subjects with lupus anticoagulant, and subjects with FV Leiden. Median protein C levels by clotting, chromogenic and antigen for the three subject groups were 108 U/dl, 108 IU/dl and 109 IU/dl for normal subjects, 94 U/dl, 106 IU/dl and 103 IU/dl for subjects with lupus anticoagulant, and 102 U/dl, 104 IU/dl and 100 IU/dl for subjects heterozygous for FV Leiden. Comparing levels of clotting protein C with protein C antigen by ratio (clotting/antigen), the three groups showed small differences that did not quite reach statistical significance, (mean ratios ranged from 0.95 to 1.01, anovaP = 0.0561), the lowest ratio was with the lupus anticoagulant group. Comparing clotting assay with chromogenic assay by ratio (clotting/chromogenic), the three groups did show a statistically significant difference (P = 0.0033) which was due to a difference in mean ratios between normal and lupus anticoagulant groups (ratios 1.00 and 0.91, respectively, P < 0.01). There was no statistical difference in any of the groups when comparing chromogenic protein C with protein C antigen (mean ratios ranged from 1.02 to 1.05, P = 0.3925). In a normal sample, the clotting-based protein C level was unaffected by increasing FVIII level by up to 1000 IU/dl, using intermediate purity FVIII concentrate. The new assay is considered to be a suitable assay for the routine diagnosis of protein C deficiency.

An overview of methods for detection of factor V Leiden and the prothrombin G20210A mutations.

Venous thromboembolism, represented by deep venous thrombosis and pulmonary embolism, is a common disease with high mortality and morbidity. Within the last 25 years, risk factors for venous thromboembolism have been linked to mutations in the genes of the coagulation/anticoagulation system. Factor V Leiden and the prothrombin G20210A mutations are the most prevalent inherited risk factors predisposing to venous thromboembolism in the Western world. Tests to detect these mutations are carried out when investigating a personal or family history of venous thromboembolism. At the present, there are several different methods available for the detection of these mutations in the laboratory. The choice of the method will depend on many variables. This article is aimed at reviewing the available methods for the detection of factor V Leiden and prothrombin G20210A mutations, their principle, applicability, advantages and disadvantages of use.

An evaluation of screening tests for defects in the protein C pathway: commercial kits lack sensitivity and specificity.

A comparative evaluation of four commercial coagulation test kits for screening the protein C pathway kits was performed at two centres. The tests were Acticlot V-OUT (V-OUT), the PCA test (PCA), the GradiThrom PCP test (PCP) and ProC Global (ProC). Reference ranges were established in 40 normal subjects and, with the exception of V-OUT and ProC, significant differences were observed between males and females. Consequently, sex-specific normal cut-off values (fifth percentile) were used that led to greatly improved sensitivity when compared with the manufacturers' recommended cut-off values. Plasma from patients with factor V Leiden (n = 23), congenital protein S deficiency (n = 19), congenital protein C deficiency (n = 11), lupus anticoagulant (n = 17) and thrombophilia with no demonstrable protein C pathway defect (n = 20) were tested. All kits showed 100% sensitivity to factor V Leiden, but sensitivity was variable for protein C deficiency (27-73%), and poor for protein S deficiency (29-35%). The lupus anticoagulant affected all kits to some degree, with 29-35% giving values below the fifth percentile of normal, whereas all kits gave 1/20 unexpected abnormal results in the thrombophilia group, with the same sample accounting for the abnormal results in three of the four kits. Overall sensitivity and specificity, respectively, for defects in the protein C pathway were: V-OUT, 60 and 91%; PCA, 70 and 86%; PCP 75 and 94%; and ProC, 66 and 88%. We conclude that all four kits lack the sensitivity and specificity required for routine laboratory screening for defects in the protein C pathway and cannot replace assays for the individual proteins of this system.

The gap between: being and knowing in Zen Buddhism and psychoanalysis.

The author discusses various relationships derived from the image of gap, precipice, and abyss with specific emphasis on interacting dynamics between being and knowing as explicated in the Zen Buddhist teachings of Hui-neng and in the psychoanalytic writings of Wilfred Bion. While of significant value to psychoanalysis, it is argued that symbolic meanings can occlude the actuality of the analysand's or of the spiritual seeker's affective experiencing, particularly concerning the human tendency to concretize experiential states engendered through meditation and/or the psychoanalytic encounter. The author draws from Matte-Blanco's explication of symmetrical and asymmetrical perceptual modalities to discuss the fluid nature of spiritual experiencing, paradoxical coexistence of ultimate and relative realities and reciprocal dynamics and identities between states of experiencing that might otherwise appear opposed. The primacy of experiencing for both disciplines, particularly concerning the experiencing subject's momentary state of consciousness, forms a central theme for both Zen and psychoanalysis. Brief clinical vignettes support and illuminate the author's points.

Clinical outcomes of point-of-care testing in the interventional radiology and invasive cardiology setting.

BACKGROUND: Point-of-care testing (POCT) can provide rapid test results, but its impact on patient care is not well documented. We investigated the ability of POCT to decrease inpatient and outpatient waiting times for cardiovascular procedures. METHODS: We prospectively studied, over a 7-month period, 216 patients requiring diagnostic laboratory testing for coagulation (prothrombin time/activated partial thromboplastin time) and/or renal function (urea nitrogen, creatinine, sodium, and potassium) before elective invasive cardiac and radiologic procedures. Overall patient management and workflow were examined in the initial phase. In phase 2, we implemented POCT but utilized central laboratory results for patient management. In phase 3, therapeutic decisions were based on POCT results. The final phase, phase 4, sought to optimize workflow around the availability of POCT. Patient wait and timing of phlebotomy, availability of laboratory results, and therapeutic action were monitored. Split sampling allowed comparability of POCT and central laboratory results throughout the study. RESULTS: In phase 1, 44% of central laboratory results were not available before the scheduled time for procedure (n = 135). Mean waiting times (arrival to procedure) were 188 +/- 54 min for patients who needed renal testing (phase 2; n = 14) and 171 +/- 76 min for those needing coagulation testing (n = 24). For patients needing renal testing, POCT decreased patient wait times (phases 3 and 4 combined, 141 +/- 52 min; n = 18; P = 0.02). For patients needing coagulation testing, wait times improved only when systematic changes were made in workflow (phase 4, 109 +/- 41 min; n = 12; P = 0.01). CONCLUSIONS: Although POCT has the potential to provide beneficial patient outcomes, merely moving testing from a central laboratory to the medical unit does not guarantee improved outcomes. Systematic changes in patient management may be required.

Genetic analysis, phenotypic diagnosis, and risk of venous thrombosis in families with inherited deficiencies of protein S.

Protein S deficiency is a recognized risk factor for venous thrombosis. Of all the inherited thrombophilic conditions, it remains the most difficult to diagnose because of phenotypic variability, which can lead to inconclusive results. We have overcome this problem by studying a cohort of patients from a single center where the diagnosis was confirmed at the genetic level. Twenty-eight index patients with protein S deficiency and a PROS1 gene defect were studied, together with 109 first-degree relatives. To avoid selection bias, we confined analysis of total and free protein S levels and thrombotic risk to the patients' relatives. In this group of relatives, a low free protein S level was the most reliable predictor of a PROS1 gene defect (sensitivity 97.7%, specificity 100%). First-degree relatives with a PROS1 gene defect had a 5.0-fold higher risk of thrombosis (95% confidence interval, 1. 5-16.8) than those with a normal PROS1 gene and no other recognized thrombophilic defect. Although pregnancy/puerperium and immobility/trauma were important precipitating factors for thrombosis, almost half of the events were spontaneous. Relatives with splice-site or major structural defects in the PROS1 gene were more likely to have had a thrombotic event and had significantly lower total and free protein S levels than those relatives having missense mutations. We conclude that persons with PROS1 gene defects and protein S deficiency are at increased risk of thrombosis and that free protein S estimation offers the most reliable way of diagnosing the deficiency. (Blood. 2000;95:1935-1941)

Evaluation of a global screening assay for the investigation of the protein C anticoagulant pathway.

We have evaluated a global screening test for the protein C pathway, the 'ProC Global' (Dade Behring Ltd, Milton Keynes, UK). Patient groups tested included inherited protein C or S deficient and inherited/acquired activated protein C resistance. Results showed that protein C deficiencies and activated protein C resistance could be successfully detected with this test whereas deficiencies of protein S were less readily distinguished from the normal population. The ProC Global was unreliable in patients with antiphospholipid antibodies, raised plasma factor VIII:C and in those receiving oral anticoagulant therapy.

Co-inheritance of the 20210A allele of the prothrombin gene increases the risk of thrombosis in subjects with familial thrombophilia.

The presence of the 20210A allele of the prothrombin (PT) gene has recently been shown to be a risk factor for venous thromboembolism. This is probably mediated through increased plasma prothrombin levels. The aim of this study was to compare the prevalence of the prothrombin 20210A allele in control subjects and in subjects with recognised thrombophilia and to establish whether the additional inheritance of the PT 20210A allele is associated with an increased risk of venous thromboembolism. 101 subjects with a history of venous thromboembolism and diagnosed as having either factor V Leiden (R506Q) or heritable deficiencies of protein C, protein S or antithrombin were studied. The prevalence of the PT 20210A allele in this group was compared with the results obtained for 150 control subjects. In addition, the relationships were examined between genetic status and the number of documented thromboembolic episodes, and between plasma prothrombin levels and possession of the PT 20210A allele. 8 (7.9%) of the 101 patients were also heterozygous for the PT 20210A allele. This compares with 0.7% in the control subjects (p = 0.005). After exclusion of patients on warfarin, the mean plasma prothrombin of 113 subjects without 20210A was 1.09 U/ml, as compared with 1.32 U/ml in 8 with the allele (p = 0.0002). Among the 101 patients with either factor V Leiden, protein S deficiency, protein C deficiency or antithrombin deficiency, the age adjusted mean (SD) number of venous thromboembolic episodes at diagnosis was 3.7 (1.5) in those with the PT 20210A allele, as compared with 1.9 (1.1) in those without (p = 0.0001). We have demonstrated that the prevalence of the PT 20210A allele is significantly greater in subjects with venous thrombosis and characterised heritable thrombophilia than in normal control subjects and that the additional inheritance of PT 20210A is associated with an increased risk of venous thromboembolism. We have also confirmed that plasma prothrombin levels are significantly greater in subjects possessing the PT 20210A compared with those who do not.

Molecular basis of protein S deficiency in three families also showing independent inheritance of factor V leiden.

The molecular basis of type I or III Protein S deficiency has been investigated in three kindred also showing independent inheritance of factor V (FV) Leiden. A T to C transition in codon 570 (Met-->Thr) was identified in the propositi and shown to segregate with protein S deficiency in all but one of the affected members of two kindred. This individual was heterozygous for a second transition (C to T) causing substitution of serine 624 by leucine. A second member of the same family, with markedly reduced free protein S levels when compared with affected relatives, was heterozygous for both mutations. Haplotype analysis of individuals with the mutated ATG570ACG allele in the two kindred suggested they may have been related by a common ancestor. A G to A transition resulting in substitution of cysteine 145 by tyrosine was detected in the third kindred. All mutations are believed to interfere with protein S binding to C4b-binding protein resulting in reduced free protein S levels. Of the five individuals studied who had experienced thrombotic events, three had combined protein S deficiency and FV Leiden reemphasising the importance of FV Leiden as an additional risk factor for thrombosis in protein S deficiency.

Further evidence that activated protein C resistance can be misdiagnosed as inherited functional protein S deficiency.

A recent report that activated protein C (APC) resistance interferes with functional protein S (PS) assays prompted us to re-investigate two pedigrees previously diagnosed as having functional PS deficiency. APC resistance was demonstrated in all individuals with apparent functional PS deficiency. The latter diagnosis was shown to be due to the assay being non-linear, functional protein S becoming normal at higher dilutions. This observation, taken in conjunction with results of in vitro recovery studies with purified PS, leads us to conclude that APC resistance was the primary disorder in both pedigrees. The misdiagnosis of APC resistance as functional PS deficiency can be prevented by performing the PS assay at several dilutions, including concentrations lower than those recommended by PS assay manufacturers. Subjects previously diagnosed as having functional PS deficiency should be re-investigated for APC resistance.

High prevalence of a mutation in the factor V gene within the U.K. population: relationship to activated protein C resistance and familial thrombosis.

Recent findings have indicated the importance of factor V (FV) in causing resistance to activated protein C (APC) in a high proportion of patients with venous thrombosis. This prompted us to investigate whether resistance could be due to defective inactivation of FVa by APC. Consequently, we amplified a 3.2 kb fragment of the FV gene sequence encoding the heavy chain APC cleavage site. DNA analysis showed a guanine to adenine transition at nucleotide 1691 in all affected members of two families with inherited APC resistance associated with thrombosis and confirmed suspected homozygosity in two individuals. The mutation, in heterozygous form, was also found in approximately 3.5% of our normal population (n = 144) and correlated with low APC resistance. The high prevalence of this mutation suggests that it may be a major contributory factor in early thrombosis.