Effects on coagulation of levonorgestrel- and desogestrel-containing low dose oral contraceptives: a cross-over study

Combined oral contraceptives (OC) are known to increase the risk of venous thromboembolism. The aim of this randomized, cycle-controlled, cross-over study in 28 healthy volunteers was to assess potential differences between the effects of an OC containing 150 microg levonorgestrel (as representative of the so-called second generation OC) and an OC containing 150 microg desogestrel (as representative of the third generation OC) in combination with 30 microg ethinylestradiol on several coagulation factors and markers of thrombin formation. All participants used each OC for two cycles, and were switched to the other OC after a washout period of two menstrual cycles. The plasma concentrations of factors II, VII, X, and fibrinogen significantly increased during use of both the levonorgestrel- and desogestrel-containing OC's. The plasma concentrations of factor VIII increased, and of factor V decreased, changes which only reached statistical significance during the use of the desogestrel-containing OC. During exposure to the desogestrel-containing OC, as compared with the levonorgestrel-containing OC, both factor VII and factor II showed a greater increase (FVII: 32% and 12% respectively; p <0.0001; FII: 16% and 12% respectively; p = 0.048), whereas factor V showed a greater decrease (-11% and -3% respectively; p = 0.010). Only one of the markers for ongoing coagulation (prothrombin fragment 1+2) showed a significant increase during OC use, whereas concentrations of thrombin-antithrombin complexes and soluble fibrin remained unchanged. For these markers, there was no difference between the tested OC's. We conclude that there are differences between the effects of levonorgestrel and desogestrel-containing OC's on some coagulation factors. Whether these changes provide a biological explanation for the reported differences in venous thromboembolic risk is as yet unclear. The real challenge now becomes to define a pattern of changes in the various systems which, if affected simultaneously, may tip the hemostatic balance towards a prethrombotic state and may lead to overt clinical venous thromboembolism.     

Effects of second and third generation oral contraceptives and their respective progestagens on the coagulation system in the absence or presence of the factor V Leiden mutation

Compared to second generation, the use of third generation oral contraceptives has been associated with an increased risk of venous thrombosis especially in women with the factor V Leiden mutation. To find an explanation for these risk differences we investigated the effects of desogestrel- and levonorgestrel-containing oral contraceptives as well as their progestagens separately on the coagulation system in the absence or presence of the factor V Leiden mutation. In a single center, double blind trial, 51 women without and 35 women with the factor V Leiden mutation were randomized to either a second generation (30 microg ethinylestradiol/150 microg levonorgestrel) or a third generation (30 microg ethinylestradiol/150 microg desogestrel) oral contraceptive. After two cycles of use and a wash-out period of 2 menstrual cycles, the participants received the corresponding progestagen-only preparation containing 150 microg levonorgestrel or 150 microg desogestrel. In plasmas of the participating women fragment 1+2, factor V, VII, VIII, IX, X and XI were determined. Both combined oral contraceptives induced a decrease in factor V, whereas the levels of all other coagulant parameters increased. However, in women without the factor V Leiden mutation the effects of desogestrel-containing preparations were significantly different compared to levonorgestrel-containing oral contraceptives for factor V (-8.0; 95% CI -13.4 to -2.6), factor VII (26.8; 95% CI 15.5 to 38.0) and factor IX (-9.6; 95% CI -16.2 to -3.2). When these women used progestagen-only pills, a differential effect between desogestrel and levonorgestrel was only found for factor IX (-6.5; 95% CI -11.4 to -1.5). In carriers of the factor V Leiden mutation desogestrel-containing oral contraceptives induced more pronounced changes in factor V (-14.2; 95% CI -22.4 to -6.0) and factor VII (36.1; 95% CI 19.7 to 52.6) compared to levonorgestrel-containing oral contraceptives. Comparing desogestrel- and levonorgestrel-only, only for factor V a differential effect was found in these women (-9.5; 95% CI -18.3 to -0.6). It appears that desogestrel-containing oral contraceptives have a more pronounced effect on the coagulation system than levonorgestrel-containing oral contraceptives which may be explained by a less effective compensation of the thrombotic effect of ethinylestradiol by desogestrel.     

Determination of plasma protein C inhibitor and of two activated protein C-inhibitor complexes in normals and in patients with intravascular coagulation and thrombotic disease

We developed an ELISA to quantitate complexes of activated protein C (APC) with a major plasma APC inhibitor, alpha 1-antitrypsin (alpha 1AT) in human plasma based on the sandwich principle using two different antibodies directed towards protein C and alpha 1AT, respectively. This ELISA test was specific for APC:alpha 1AT complexes and sensitive to greater than or equal to 150 pg complex. Fifty-one of 56 healthy donors had APC:alpha 1AT complex levels above the detection limit (3 ng/ml) ranging from 4 to 14 ng/ml (mean value +/- SD: 7.6 +/- 2.5 ng/ml). Patients (n = 10) with disseminated intravascular coagulation (DIC) had detectable levels of APC:alpha 1AT complex ranging from 21 to 125 ng/ml (median: 69 ng/ml). Complexes of APC with plasma protein C inhibitor (PCI) were also measured using an ELISA sandwich assay. None of the 30 healthy donors had detectable levels (greater than or equal to 5 ng/ml) of APC:PCI complex, and plasma samples from 9 of 10 DIC patients had detectable concentrations of APC:PCI complex ranging from 10 to 63 ng/ml (median: 22 ng/ml). APC:alpha 1AT complex was detected in 25 of 26 patients with deep venous thrombosis (DVT), with levels ranging from 5 to 136 ng/ml (median: 23 ng/ml), whereas APC:PCI was detected in only 6 DVT patients, with levels between 11 and 105 ng/ml. PCI antigen levels in 70 normals ranged from 56 to 175% (mean +/- SD: 99.1% +/- 24.2%). PCI antigen levels were decreased in DIC patients, in patients with cerebral arterial thrombosis, and in DVT patients undergoing heparin therapy, but not in patients with myocardial infarction. PCI antigen levels were decreased much further in DVT patients receiving heparin compared to those not receiving heparin, showing that heparin therapy is associated with a decrease in PCI levels. The detection in normal subjects and in thrombotic patients of circulating APC:inhibitor complexes supports the view that the protein C pathway is activated during DIC and DVT. Moreover, it emphasizes that both PCI and alpha 1AT are physiologic inhibitors of APC. Thus, measurement of APC complexes may provide sensitive parameters for specific detection of activation of the clotting and protein C pathways.     

Protein C inhibitor and other components of the protein C pathway in patients with acute deep vein thrombosis during heparin treatment

The protein C inhibitor (PCI) concentration and other parameters of the protein C pathway were studied in 19 patients with symptomatic acute deep vein thrombosis before and during the first 5 days of heparin treatment. The mean levels of PCI antigen and activity decreased rapidly and significantly during the first day of heparin therapy from 83 and 84% to 60 and 59% of the pooled normal human plasma (p less than 0.01), respectively, and to 56 and 54% after 5 days of treatment (p less than 0.01). In contrast, antithrombin III decreased progressively 25% during 5 days of heparin treatment. Protein C antigen and activity and total protein S remained unchanged during heparin treatment. Free protein S was decreased before heparin treatment (83%, p less than 0.05) and increased to normal values after 5 days of treatment. C4b-binding protein was significantly increased before and during heparin treatment (p less than 0.01). Activated protein C (APC) complexed to its two major plasma inhibitors, PCI and alpha 1-antitrypsin (alpha 1AT) were measured by specific ELISA's. Before treatment, 18 of the 19 patients studied had increased levels of APC:alpha 1AT complexes with a mean value of 27 +/- 22 ng/ml (range, 6-86 ng/ml) compared to normal values (8 +/- 2 ng/ml) and 12 of the patients also had detectable APC:PCI complex levels with a mean value of 11 +/- 17 ng/ml (range, 5-68 ng/ml). Both APC:inhibitor complexes decreased significantly during heparin treatment.     

Alpha 2-macroglobulin enhances prothrombin activation and thrombin potential by inhibiting the anticoagulant protein C/protein S system in cord and adult plasma

Protein S (PS) is a vitamin K-dependent plasma protein and serves as a cofactor for the anticoagulant activities of activated protein C (APC). We investigated the effects of different PS concentrations on prothrombin activation and thrombin generation in cord and adult plasma containing APC and different amounts of alpha 2-macroglobulin (a2-M). Prothrombin activation was assessed by monitoring the time-course of prothrombin fragment 1+2 (F1+2) generation. Thrombin generation curves were determined by means of a subsampling technique using the chromogenic substrate S-2238. We demonstrate a dose-dependent inhibition of the anticoagulant action of PS by a2-M: suppression of F1+2 and thrombin generation due to addition of PS was stronger in plasma containing low amounts of a2-M than in plasma with elevated a2-M levels. Since no complex formation between a2-M and PS was observed by means of SDS-PAGE, we attribute decreased anticoagulant action of PS at high a2-M levels to enhanced complex formation between APC and a2-M. Thereby, APC is subtracted from its cofactor PS, resulting in suppressed formation of the anticoagulant APC/PS complex. Thus, our data suggest that a2-M, besides its well-known anticoagulant effects, also acts as a procoagulant by suppressing the formation of the anticoagulant APC/PS complex. Our findings have implications particularly on thrombin generation and inhibition in cord plasma, since a2-M levels in newborns are elevated over adult values and the antithrombotic APC/PS pathway is up-regulated at birth. Therefore, elevated levels of a2-M might restrict the up-regulation of the APC/PS pathway.     

Effects of the contraceptive patch, the vaginal ring and an oral contraceptive on APC resistance and SHBG: a cross-over study

INTRODUCTION: The transdermal patch (20 microg ethinylestradiol+150 microg norelgestromin daily) and the vaginal ring (15 microg ethinylestradiol+120 microg etonogestrel daily) are new contraceptives, designed to deliver a low dose of hormones, suggesting a low exposure. However, few data are available about their risk of venous thrombosis. The objective was to investigate the effect of the patch, the ring, and an oral contraceptive (30 microg ethinylestradiol+150 microg levonorgestrel daily) on activated protein C sensitivity ratio (APC-sr) and on sex hormone-binding globulin (SHBG) levels in plasma. MATERIALS AND METHODS: After a two month wash-out, 13 volunteers were randomly assigned to either the patch followed by the oral contraceptive or vice versa, or the ring followed by the oral contraceptive or vice versa. All treatments lasted two cycles and were separated by a wash-out of two cycles. APC-sr and SHBG levels were determined on day 18-21 of the second cycle of the wash-out and of each treatment period. RESULTS: Compared to the oral contraceptive, both the patch and the ring led to higher APC resistance (mean difference APC-sr 1.1; 95% CI 0.67-1.52 and 0.55; 95% CI 0.11-1.00, respectively) and higher SHBG levels (mean difference 210 nmol/l; 95% CI 134-286 and 148 nmol/l; 95% CI 48-248, respectively). CONCLUSION: The activity of the protein C system in plasma was impaired more by contraceptive patch and vaginal ring than by an oral contraceptive containing the second generation progestagen levonorgestrel.     

Effect of oral contraceptives on the anticoagulant activity of protein S in plasma

We determined anticoagulant parameters that depend on protein S function in plasma, i.e. the APC-independent anticoagulant activity of protein S (expressed as pSR) and APC resistance determined with thrombin generation-based tests (expressed as APCsr) as well as plasma levels of total and free protein S and prothrombin in men, women not using oral contraceptives (OC), and in women using second or third generation OC. Thrombin generation in the APC resistance assays was initiated either with factor Xa (Xa-APCsr) or tissue factor (TF-APCsr). The APC-independent anticoagulant activity of protein S was highest in men (pSR=1.69) and gradually decreased from women not using OC (pSR=1.49) via women using second generation (pSR=1.35) to women using third generation OC (pSR=1.27). The pSR correlated inversely with nAPCsr determined with the tissue factor-based APC resistance test (TF-APCsr) but not with nAPCsr determined with the factor Xa-based assay (Xa-APCsr). Multiple linear regression analysis in which sex, OC use, and protein S and prothrombin levels were included as independent variables and the pSR, TF-APCsr or Xa-APCsr as dependent variables indicated that plasma protein S levels poorly predict the pSR and the TF-APCsr, but are the main determinant of the Xa-APCsr. This indicates that OC use alters the expression of protein S activity. This phenomenon can be caused by differences in modulation of the activity of protein S by other plasma proteins that change during OC use or by OC-induced changes in the protein S molecule that impair its anticoagulant activity. Functional impairment of protein S as a result of hormonal influence may, at least in part, contribute to the thrombotic risk of OC users.     

Hyperprothrombinaemia-induced APC resistance: differential influence on fibrin formation and fibrinolysis

The prothrombin gene mutation G20210A is a common risk factor for thrombosis and has been reported to cause APC resistance. However, the inhibition of thrombin formation by APC not only limits fibrin formation but also stimulates fibrinolysis by reducing TAFI activation. We evaluated the influence of prothrombin G20210A mutation on the anticoagulant and fibrinolytic activities of APC (1 microg/ml). Thirty-two heterozygous carriers and 32 non carriers were studied. APC anticoagulant activity was assessed by aPTT prolongation whereas APC fibrinolytic activity was determined by a microplate clot lysis assay. APC-induced aPTT prolongation was markedly less pronounced in carriers than in non carriers. On the contrary, fibrinolysis time was shortened by APC to a comparable extent in both groups. Accordingly, prothrombin levels were strongly correlated with APC-induced aPTT prolongation but not with APC-induced shortening of lysis time. The addition of purified prothrombin to normal plasma (final concentration 150%) caused APC resistance in the clotting assay over the whole range of tested APC concentrations (0.125-1.5 microg/ml). In the fibrinolytic assay, instead, prothrombin supplementation made the sample resistant to low but not to high concentrations of APC (>0.5 microg/ml). Thrombin and TAFIa determination in the presence of 1 microg/ml APC revealed that hyperprothrombinemia, although capable of enhancing thrombin generation, was unable to induce detectable TAFIa formation. It is suggested that APC resistance caused by hyperprothrombinaemia does not translate in impaired fibrinolysis, at least in the presence of high APC levels, because the increase in thrombin formation is insufficient to activate the amount of TAFI required to inhibit plasminogen conversion. These data might help to better understand the relationship between thrombin formation and fibrinolysis down-regulation.     

Effects of alpha(2)-macroglobulin and antithrombin on thrombin generation and inhibition in cord and adult plasma

Thromboembolic complications rarely occur during infancy and childhood. It has been reported that increased capacity of cord plasma to inhibit thrombin due to elevated alpha(2)-macroglobulin (alpha(2)-M) levels may in part provide protection from thrombosis. In antithrombin (AT)-deficient plasma, alpha(2)-M exhibits anticoagulant action by complexing substantial amounts of generated free thrombin. It has been suggested that alpha(2)-M has the same impact on thrombin inhibition as AT, the most important thrombin inhibitor in adult plasma. The aim of our study was to examine this assumption by determining time-courses of free thrombin generation and prothrombin activation. Additionally, the amount of thrombin complexed to alpha(2)-M was assessed by comparing the heights of the end-level of amidolytic activity curves (AACs) after extrinsic activation of platelet poor plasma in the presence of different concentrations of AT or alpha(2)-M. Increasing the AT content by 30% resulted in significantly suppressed generation of free thrombin and prothrombin fragment 1+2 (F1+2) in cord and adult plasma. In contrast, increasing the alpha(2)-M content in plasma containing physiologic amounts of AT by the same percentage had no effect on free thrombin generation and on F1+2 generation in both cord and adult plasma. In addition, the effect of AT supplementation on the end-level of the AACs was significantly higher compared to the effect of alpha(2)-M supplementation. Since alpha(2)-M, in contrast to AT, had no effect on free thrombin generation and prothrombin activation, our study suggests that the action between alpha(2)-M and thrombin might not be fast enough to prevent thrombin from its feedback activation in both cord and adult plasma and, therefore, in cord and adult plasma containing physiological amounts of AT alterations of the alpha(2)-M content had no effect on thrombin generation and inhibition.     

Involvement of Lys 62(217) and Lys 63(218) of human anticoagulant protein C in heparin stimulation of inhibition by the protein C inhibitor.

Inhibition of activated protein C (APC) by protein C inhibitor (PCI) is stimulated by heparin, whereas inhibition by alpha1-antitrypsin (AAT) is heparin-independent. Three lysine residues located in a positively charged cluster in the serine protease domain of protein C (PC) were mutated to probe their involvement in the heparin stimulation of inhibition by PCI. These mutations were selected after analysis of the three-dimensional structure of APC and of molecular models for PCI and the APC-PCI complex. A double mutant, K62[217]N/K63[218]D, a single mutant, K86[241]S, and wild-type PC were expressed in embryonic human kidney 293 cells. Heparin stimulated the rate of inhibition of wt-APC by PCI approximately 400-fold, with second order rate constants (k2) in the absence and presence of heparin of 0.72 x 10(3) M(-1)s(-1) and 2.87 x 10(5) M(-1)s(-1), respectively. In contrast, heparin only yielded a 52-fold stimulation of the rate of inhibition of the double mutant APC by PCI as the rate constants in the absence and presence of heparin were k2 = 2.44 x 10(3) M(-1)s(-1) and k2 = 1.26 x 10(5)M(-1)s(-1), respectively. The double mutant K62N/K63D eluted at approximately 10% lower NaCl concentration from a heparin Sepharose column than the K86S mutant or wt-APC. These data suggest K62 and K63 in APC to be part of a heparin binding site which is important for heparin-mediated stimulation of inhibition of APC by PCI.     

A second plasma inhibitor of activated protein C: alpha 1-antitrypsin

Inactivation of activated protein C (APC) in normal human plasma was studied in the absence and presence of heparin. In the absence of heparin APC inactivation followed pseudo-first order kinetics. In the presence of heparin the neutralization of APC was found to be biphasic. Up to 500 nM APC could be readily inactivated in normal plasma, indicating that the concentration of the APC inhibitor must be higher than previously assumed. Plasma deficient in the protein C inhibitor (PCI-I, as described by Suzuki and coworkers) and deficient in beta 2-glycoprotein I still possessed APC neutralizing capacity, presumably through the formation of complexes of APC with another plasma protein as was demonstrated by immunoblotting with anti-protein C antibodies. Together these data made us to conclude that a second inhibitor of APC (PCI-II) must be present in normal human plasma. This second inhibitor should be heparin independent, have a relatively high plasma concentration and form complexes with APC. Subsequently, we purified this PCI-II by isolating APC-PCI-II complexes from plasma deficient of vitamin K dependent proteins, PCI-I and beta 2-glycoprotein-I, to which purified human APC had been added. Purified PCI-II has a molecular weight of 50,000 daltons and aminoacid analysis revealed that PCI-II is identical with alpha 1-antitrypsin (alpha 1-AT). The second order rate constant for the reaction between purified alpha 1-AT and APC was found to be 269 M-1 min-1 in the absence of calcium and 602 M-1 min-1 in the presence of calcium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interspecies loop grafting in the protease domain of human protein C yielding enhanced catalytic and anticoagulant activity.

Human anticoagulant activated protein C (hAPC) is less potent than the bovine APC (bAPC) molecule and our aims were to elucidate the molecular background for this difference and to create an APC with enhanced anticoagulant activity. In the protease domain of human protein C (hPC), the loop 148 (GWGYHSSREKEAKRN) is four residues longer than the corresponding loop in bovine APC (GWGY RDETKRN). To investigate whether this caused the species difference, the loop in hPC was replaced by the shorter bovine loop, whereas the longer human loop was introduced in bovine protein C. The mutation in hAPC yielded enhanced catalytic activity against chromogenic (4-fold) as well as natural (factors Va and VIIIa) substrates and 2-3-fold increased anticoagulant activity. The opposite effects were obtained with the bovine mutant. As compared to wild-type hAPC, the mutant hAPC was inhibited slightly faster by the protein C inhibitor, whereas the inhibition by alpha1-antitrypsin was unaffected by the mutation. A computer model of bAPC was developed in order to analyse further our data. Collectively, our results demonstrate enhanced catalytic efficiency to result from mutagenesis in the loop 148 and show that APC mutant with increased anticoagulant activity can be created.     

Increased fibrinolytic activity during use of oral contraceptives is counteracted by an enhanced factor XI-independent down regulation of fibrinolysis: a randomized cross-over study of two low-dose oral contraceptives

The effect of oral contraceptives (OC) on fibrinolytic parameters was investigated in a cycle-controlled cross-over study in which 28 non-OC using women were randomly prescribed either a representative of the so-called second (30 microg ethinylestradiol, 150 microg levonorgestrel) or third generation OC (30 microg ethinylestradiol, 150 microg desogestrel) and who switched OC after a two month wash out period. During the use of OC, the levels of tissue-type plasminogen activator (tPA) activity, plasminogen, plasmin-alpha2-antiplasmin complexes and D-dimer significantly increased (by 30 to 80%), while the levels of plasminogen activator inhibitor- (PAI-1) antigen, PAI-1 activity and tPA antigen significantly decreased (25 to 50%), suggesting an increase in endogenous fibrinolytic activity. These OC-induced changes were not different between the two contraceptive pills. TAFI (thrombin-activatable fibrinolysis inhibitor) levels increased on levonorgestrel, and even further increased on desogestrel. A clot lysis assay that probes both fibrinolytic activity and the efficacy of the coagulation system to generate thrombin necessary to down regulate fibrinolysis via TAFI showed no change of the clot lysis time during OC use. This finding suggests that the OC-induced increase in endogenous fibrinolytic activity is counteracted by an increased capacity of the coagulation system to down regulate fibrinolysis via TAFI. Indeed we observed that during OC use there was a significant increase of F1+2 generation during clot formation. When these assays were performed in the presence of an antibody against factor XI, we observed that the clot lysis time was significantly increased during OC use and that the increase in F1+2 generation during OC therapy was due to a factor XI-independent process, which was significantly higher on desogestrel than on levonorgestrel. These data indicate that the OC-induced inhibition of endogenous fibrinolysis takes place in a factor XI-independent way and is more pronounced on desogestrel than on levonorgestrel-containing OC.     

Evaluation of coagulometric assays in the assessment of protein C anticoagulant activity; variable sensitivity of commercial APTT reagents to the cofactor effect of protein S

In vivo expression of protein C activity is dependent on the availability of the activated protein C (APC) cofactor protein S. In the clinical laboratory, measurement of protein C anticoagulant activity is mostly performed in modified APTT assays. We have evaluated 13 commercial APTT reagents for their sensitivity to the cofactor effect of protein S by comparing APC-dependent clotting time prolongations in normal plasma and in protein S depleted plasma. In normal plasma, the sensitivities of the APTT reagents to the anticoagulant effect of APC were markedly different and correlated with the sensitivity of reagents to factor V and VIII. Reagents containing soy phosphatides appeared more sensitive than reagents containing phospholipid of animal origin. Analysis of dose-response curves obtained in normal plasma distinguished one group of reagents showing clotting time prolongations linearly related to the APC concentrations, a second group showing a log-linear relationship and a third group showing a log-log relationship. In protein S depleted plasma, sensitivity of APTT reagents to APC was in general proportional to that observed in normal plasma. However, for some reagents dose-response curves were qualitatively different in normal and in protein S depleted plasma. With all the APTT reagents, APC-dependent clotting time prolongations corresponding to 30-80% of APC anticoagulant activity observed in normal plasma, were observed in protein S depleted plasma. At variance, in a modified Xa one-stage clotting assay, negligible clotting time prolongations were observed in protein S depleted plasma, indicating that over 90% of the APC anticoagulant activity was protein S dependent in this assay system. Dilution of a relative insensitive APTT reagent effectively increased its sensitivity to the cofactor effect of protein S, suggesting that different phospholipid content and/or composition might be responsible for the different sensitivity of APTT reagents to protein S. These results question the validity of APTT based assays for the identification of qualitative protein C abnormalities with defective interaction with protein S.     

Treatment of endothelium with the chemotherapy agent vincristine affects activated protein C generation to a greater degree in newborn plasma than in adult plasma

INTRODUCTION: Activated protein C (APC) is well-established as a physiologically important anticoagulant. During development, plasma concentrations of protein C and alpha(2)macroglobulin, factors involved in APC generation, differ from adult levels. Chemotherapy drugs can perturb endothelial expression of PC-activating receptors. This study examines the effect of chemotherapy treatment of endothelium on APC generation in newborn and adult plasma. MATERIALS AND METHODS: APC generations were initiated on endothelial cells treated with vincristine or media by recalcifying defibrinated plasma with buffer containing thromboplastin. APC generation was terminated by mixing timed subsamples into FFRCMK-EDTA or heparin, followed by EDTA. APC-PCI and APC-alpha(1)AT were assayed by ELISA. APC-alpha(2)M was measured chromogenically. Since heparin converts free APC to APC-PCI, the difference between APC-PCI detected in heparin subsamples and APC-PCI detected in FFRCMK-EDTA subsamples gave the free APC. Cellular expression of EPCR and TM were measured by flow cytometry and Western blot. RESULTS: Vincristine-treated endothelium decreased free APC generation in newborn plasma to a greater degree than in adult plasma. APC-PCI levels in both adult and newborn plasma were unaffected by chemotherapy. Vincristine treatment reduced levels of APC-alpha(1) AT and APC-alpha(2) M to a greater degree in newborn plasma versus adult plasma. Expression of EPCR was reduced in cells treated with vincristine. Conversely, TM was reduced on the cell surface, but increased in whole cell lysates. CONCLUSIONS: The differential response of newborn and adult plasma PC components to chemotherapy-mediated changes in cell surface components may be a factor in the increased risk of thrombosis in children receiving chemotherapy.     

Interaction between brivaracetam (100 mg/day) and a combination oral contraceptive: A randomized,double‐blind,placebo‐controlled study

This randomized, double‐blind, placebo‐controlled, two‐way crossover study aimed to assess the pharmacokinetic interactions between brivaracetam 100 mg/day and a combination oral contraceptive (OC) containing 30 μg ethinylestradiol and 150 μg levonorgestrel. The study was performed in 28 healthy women over five 28‐day menstrual cycles: baseline (OC only), two treatment cycles with brivaracetam (50 mg b.i.d.) or placebo coadministered with OC separated by a wash‐out cycle (OC only), and a follow‐up cycle (OC only). The OC was administered on days 1–21 of each cycle, and brivaracetam or placebo on days 1–28 of the treatment cycles. Pharmacokinetics of ethinylestradiol and levonorgestrel were determined on day 20; brivaracetam morning trough levels on days 20 (with OC) and 29 (without OC) were compared. C_max (maximum plasma concentration) and AUC (area under the plasma concentration versus time curve) ratios for brivaracetam versus placebo (90% confidence interval [CI]) were 0.96 (0.88–1.04) and 0.90 (0.86–0.95) for ethinylestradiol, and 0.95 (0.91–0.99) and 0.92 (0.88–0.97) for levonorgestrel, within predefined bioequivalence limits (0.80–1.25). Brivaracetam trough levels were similar on days 20 and 29 (ratio 1.08; 90% CI 0.98–1.18). No differences in breakthrough bleeding were seen across the five cycles. It was concluded that there were no interactions between brivaracetam 100 mg/day and the OC. A PowerPoint slide summarizing this article is available for download in the Supporting Information section here .     

A sensitive immunochemical assay for measuring the concentration of the activated protein C-protein C inhibitor complex in plasma: use of a catcher antibody specific for the complexed/cleaved form of the inhibitor

Activated protein C (APC) is a serine proteinase that regulates blood coagulation. In plasma it is inhibited mainly by the protein C inhibitor (PCI). The plasma concentrations of APC-PCI complex is increased in hypercoagulative states such as deep venous thrombosis. Formation of the APC-PCI complex induces a drastic conformational change in PCI that exposes new epitopes (neoepitopes) on the molecule. We have devised a simple immunofluorometric sandwich assay for measurements of the concentrations of APC-PCI complex, employing as the catcher, a monoclonal antibody that has a high affinity (K(D) = 4 x 10(-11) M) for a complexation-specific neoepitope that is expressed on PCI. A monoclonal antibody against protein C is employed as the tracer. The method gives a linear dose-response curve (0.06-50 microg/l), has a low detection limit (0.06 microg/l) and no crossreactivity with native PCI at physiologic plasma concentrations. We have now determined the concentration of the APC-PCI complex in healthy individuals.     

Interaction of plasma kallikrein with protein C inhibitor in purified mixtures and in plasma.

The interaction between plasma kallikrein (KK) and protein C inhibitor (PCI) and the influence of KK on the complex formation between activated protein C (APC) and PCI was studied in purified systems as well as in plasma in order to assess the significance of these reactions in the plasma milieu. PCI complexed to KK (KK:PCI) or to APC (APC:PCI) was measured by sandwich ELISA's using antibodies directed against each protein in the complexes. The formation of KK:PCI complexes assayed by this method paralleled the inhibition of KK amidolytic activity by PCI in purified system. Incubation of normal plasma (NHP) at 4 degrees C, which can induce prekallikrein activation due to cold activation, resulted in PCI inactivation and appearance of KK:PCI complexes. PCI activity fell to 35% of the NHP and 1.2 micrograms/ml of KK:PCI complex was formed. However, incubation of NHP at room temperature or of prekallikrein deficient plasma at 4 degrees C did not result in significant decrease of PCI activity. Thus the PCI inactivation was associated with prekallikrein activation and complexation to PCI following cold activation. Incubation of exogenous purified KK with NHP resulted in PCI inactivation and complexation with KK in a temperature-dependent manner. Addition of 2.8 micrograms/ml KK to plasma at 4 degrees C resulted in the inactivation of 55% of plasma PCI and the formation of 0.9 microgram/ml KK:PCI which represents 21% of the KK added, whereas at 37 degrees C PCI was inactivated to 30% and only 0.30 microgram/ml KK:PCI complexes were measured. These results indicate that PCI is a major KK inhibitor at 4 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Species specificity of the fibrinolytic effects of activated protein C.

Activated protein C (APC) has been shown to stimulate fibrinolysis in both in vitro and in vivo experimental systems. In order to test the importance of protein S in the fibrinolytic activity of APC we have compared the activity of APC, prepared from rabbit, bovine and human plasma, in the stimulation of whole blood clot lysis, the inactivation of plasminogen activator inhibitors and anticoagulant activity. When whole blood clot lysis was performed using tissue plasminogen activator in either human or rabbit blood, APC was found to enhance clot lysis in a species specific manner that paralleled the pattern observed for its anticoagulant activity. Bovine APC, was the poorest stimulator of fibrinolysis in human plasma. However, if bovine protein S was also added to human plasma, bovine APC was as effective in promoting fibrinolysis as human APC. In contrast, no species specific effects on the inactivation of plasminogen activator inhibitor activity was observed. Though substantial effects of APC on plasminogen activator inhibitor levels were made by rabbit, human and bovine activated protein C in human plasma, there was no effect of activated protein C on the rate of clot lysis of human plasma. These results suggest that protein S is important for the expression of the fibrinolytic activity of activated protein C and that the effect of protein S may be useful for the differentiation of fibrinolytic effects of activated protein C that may be related to the inactivation of plasminogen activator inhibitors and those that are not.     

Characterization of transgenic mice that secrete functional human protein C inhibitor into the circulation

Protein C inhibitor (PCI) is a heparin binding serine protease inhibitor in plasma, which exerts procoagulant activity by inhibiting thrombomodulin-bound thrombin or activated protein C (APC). Since the role of PCI in vivo is largely unknown we generated genetically modified mice with expression of human PCI mRNA in hepatocytes only. Three transgenic lines have been characterized. Transgenic mice did not show gross developmental abnormalities. Two lines showed a pericentral and one line showed a periportal expression pattern of human PCI mRNA in the liver. Genetically modified mice secreted a functional transgenic protein into the circulation (3-5 microg/ml plasma in heterozygous mice and 10 microg/ml in homozygous mice), which inhibited human APC activity in the presence of heparin. Interestingly, transgenic mice in which human PCI was expressed periportally in the liver had the highest specific activity. Endogenous mouse PCI mRNA could only be detected in the male and female reproductive system, but not in the liver, indicating that endogenous PCI levels in the circulation are low or even absent in mice. These results demonstrate that the human PCI transgenic mice are a suitable model for studying the in vivo role of PCI in blood coagulation.