Platelet-dependent thrombin generation after in vitro fibrinolytic treatment.

BACKGROUND. Fibrinolytic therapy is associated with frequent rethrombosis. There is evidence of both increased coagulation and platelet activation. METHODS AND RESULTS. Platelet-rich plasma (PRP) or washed platelets were incubated with the fibrinolytic agents urokinase, recombinant tissue-type plasminogen activator (rt-PA), or plasmin at concentrations consistent with those in the plasma of patients treated for myocardial infarction. All of the fibrinolytic agents induced a more rapid generation of thrombin and decreased the clotting times of non-contact-activated PRP than in untreated PRP. This effect was not blocked by the inclusion of thrombin inhibitors during the fibrinolytic treatment. Washed platelets derived from rt-PA-treated PRP induced more rapid thrombin generation when resuspended in untreated plasma or treated plasma. Washed platelets were treated with plasmin, rt-PA, and urokinase and added to platelet-poor plasma. Platelets treated with either plasmin or rt-PA increased the ability of washed platelets to support thrombin generation, but urokinase was without significant effect. CONCLUSIONS. These results indicate not only that plasmin can cause increased platelet support of prothrombin activation but also that rt-PA in the absence of plasminogen can have a direct effect on the platelet, which increases thrombin generation.     

Plasmin effect on platelet glycoprotein Ib-von Willebrand factor interactions

We have studied the effect of streptokinase on platelets in platelet- rich plasma (PRP) and of plasmin on washed platelets. By three and one- half minutes after the addition of 50,000 IU/mL streptokinase to PRP, the maximum rate of ristocetin-induced platelet agglutination declined 40%, and by 60 minutes, it declined 70%. During the same time interval, the thrombin time increased from 20 seconds to over 120 seconds. At a concentration as low as 50 IU/mL, streptokinase reduced the maximum rate of ristocetin-induced platelet agglutination by 50% and prolonged the thrombin time to 1.5 times control value. Streptokinase added to PRP also caused inhibition of platelet aggregation following stimulation by 2.9 mumol/L adenosine diphosphate, 0.25 U/mL thrombin, and 0.025 mg/mL collagen. Plasmin, 0.05 to 1.0 CU/mL, reduced ristocetin-mediated agglutination of washed platelets in the presence of von Willebrand factor (vWF) from 66% of control to 2% of control, following a one-hour incubation. Autoradiograms produced following sodium dodecyl-polyacrylamide gel electrophoresis (SDS-PAGE) of plasmin- treated 125I-surface-labeled platelets demonstrated progressive loss of a protein with a molecular weight (mol wt) of 180,000; simultaneously, a protein with mol wt 135,000 appeared on autoradiograms produced following SDS-PAGE of the surrounding platelet medium. These proteins are similar in molecular weight to glycoprotein (gp) Ib, a platelet surface receptor for vWF, and glycocalicin, a proteolytic fragment of gpIb. By use of an enzyme-linked immunosorbent assay (ELISA) based immunoinhibition assay for glycocalicin, we were able to demonstrate that plasmin treatment of washed platelets released a glycocalicin- related antigen into the surrounding medium and that appearance of this material corresponding to loss of vWF-dependent, ristocetin-induced agglutination.     

Activation of plasminogen by tissue plasminogen activator on normal and thrombasthenic platelets: effects on surface proteins and platelet aggregation

Tissue plasminogen activator (TPA) converts plasminogen to plasmin within the fibrin clot, thus localizing activation of fibrinolysis. To determine the extent to which platelets promote activation of plasminogen by TPA, we studied the interaction of TPA and plasminogen with unstimulated platelets. Normal washed platelets incubated in the presence of physiologic concentrations of plasminogen (180 micrograms/mL) and TPA (20 ng/mL) failed to generate plasmin activity. In contrast, incubation of platelets with TPA concentrations achieved during thrombolytic therapy (40 to 800 ng/mL) produced a tenfold to 50- fold increase in plasmin activity. After exposure to plasminogen and 200 ng/mL of TPA for one hour, platelets failed to agglutinate in the presence of ristocetin. Incubation of platelets suspended in autologous plasma with 400 ng/mL of TPA for one hour also inhibited ristocetin- induced agglutination. Exposure of platelets to plasminogen and increasing concentrations of TPA correlated with a decrease in glycoprotein Ib (GPIb) and an increase in glycocalicin, as shown by immunoblotting. The glycoprotein IIb/IIIa (GPIIb/IIIa) complex and a 250,000-dalton protein also disappeared from washed platelets after incubation with plasminogen and 200 ng/mL of TPA for one hour. These platelets failed to aggregate in the presence of adenosine diphosphate (ADP) or gamma thrombin, although aggregation in response to calcium ionophore A23187 and arachidonic acid remained intact. However, aggregation in response to all four agonists was normal when platelets were incubated with TPA in the presence of autologous plasma. Platelets from a patient with Glanzmann's thrombasthenia also generated plasmin in the presence of TPA. Hydrolysis of GPIb and inhibition of ristocetin- induced agglutination occurred to a lesser extent with these platelets than with control platelets. We conclude that platelets provide a surface for activation of plasminogen by pharmacologic amounts of TPA. Plasmin generation leads to degradation of GPIb and decreased ristocetin-induced agglutination in normal and thrombasthenic platelets, as well as degradation of GPIIb/IIIa in normal washed platelets and inhibition of ADP and gamma thrombin-induced aggregation. These findings suggest that pharmacologic concentrations of TPA may cause platelet dysfunction due to plasmin generation on the platelet surface.     

Contact activation triggers stimulation of the monocyte 5-lipoxygenase pathway via plasmin

The purpose of this study was to characterize the stimulus that activates the 5-lipoxygenase pathway in human peripheral monocytes (PM) during the process of contact activation. Incubation of PM, but not of polymorphonuclear leukocytes (PMN), in contact-activated, recalcified plasma induced a time-dependent release of leukotrienes (LT). The presence of platelets was required for the generation of cysteinyl-LT, but LTB4 formation also proceeded in their absence, although to a lesser extent. Plasmin, presumably generated via the intrinsic fibrinolytic pathway, was liable for the 5-lipoxygenase stimulation during contact activation inasmuch as (1) the 5-lipoxygenase pathway in PM was stimulated by contact-activated, recalcified, autologous or homologous plasma, but not by factor XII-deficient or prekallikrein- deficient plasma; (2) lysine analogs such as N alpha-acetyl-L-lysine, 6- aminohexanoic acid (6-AHA), or trans-4- (aminomethyl)cyclohexane-1- carboxylic acid (t-AMCA), which inhibit plasmin(ogen) binding to PM plasmin(ogen) binding sites, concentration-dependently reduced the cysteinyl-LT release; (3) plasminogen activators such as urokinase or streptokinase concentration-dependently enhanced the cysteinyl-LT release up to 10 and 1,000 IU/mL, respectively, while higher concentrations were less effective leading to bell-shaped concentration- response curves; (4) plasmin inhibitors such as aprotinin or alpha 2- antiplasmin concentration-dependently inhibited the cysteinyl-LT release; and (5) preincubation of plasma with monoclonal antibodies directed against plasminogen and capable of preventing plasminogen activation blocked the contact-mediated 5-lipoxygenase stimulation. Moreover, incubation of PM with plasmin, but not with plasma kallikrein, in Hanks' balanced salt solution (HBSS)-bovine serum albumin (BSA) 0.4% triggered a concentration-dependent release of LTB4 up to 0.1 caseinolytic units (CU)/mL, with higher concentrations being less effective. By contrast, release of cyclooxygenase metabolites such as thromboxane (TX) B2 and prostaglandin (PG) E2 was not stimulated by plasmin, indicating specificity for the 5-lipoxygenase pathway. With plasmin as a hitherto unknown stimulus of the 5-lipoxygenase pathway in PM, a novel link between contact activation and inflammation has been established.     

Procoagulant Activity of Platelets in Recalcified Plasma

High-spun platelet-poor plasma (HSPPP) and platelet-rich plasma (PRP), prepared with minimal contact activation and pH shifts, were recalcified with little dilution in the presence of phospholipid prepared from chloroform-extracted, acetone-dried brain tissue. The clotting times of HSPPP and PRP were the same whether or not the platelets in PRP were first incubated or aggregated with ADP or with collagen. This suggests that platelet procoagulant activity in normal recalcified plasma derives only from provision of platelet phospholipid.     

Platelet activation in the pathogenesis of unstable angina: importance in determining the response to plasminogen activators

Unstable angina is a clinical syndrome of recurrent myocardial ischemia. In some cases, this reflects episodic platelet activation and coronary thrombosis. Thus, the biosynthesis of thromboxane A2, which is largely derived from activated platelets, is increased, often coincident with chest pain. The major role of platelets in unstable angina may influence the response to plasminogen activators. Platelets increase the resistance of thrombi to lysis, by inducing clot retraction and cross-linking and by releasing inhibitors. Thus, coronary thrombi in unstable angina may be resistant to lysis. Furthermore, both t-PA and streptokinase cause platelet activation and thrombin formation in vivo, possibly via plasmin. Plasmin can activate platelets and factor V directly. These prothrombotic effects of plasminogen activators may limit their activity in unstable angina. At the very least, their therapeutic efficacy may be highly dependent on the coadministration of potent antiplatelet agents and anticoagulants.     

Dependence of plasmin-mediated degradation of platelet adhesive receptors on temperature and Ca2+

The effects of activation of plasminogen by streptokinase and tissue-type-plasminogen activator on platelet activation and the membrane glycoproteins (GPs) that mediate platelet adhesion and aggregation are not yet fully defined. To clarify effects on platelets during activation of plasminogen in vitro, we used monoclonal antibodies (MoAbs), flow cytometry, and platelets surface-labeled with 125I to characterize changes in receptors for fibrinogen (GPIIb-IIIa), von Willebrand factor (GPIb), and collagen (GPIa-IIa). Activation of plasminogen in plasma with pharmacologic concentrations of plasminogen activators did not degrade GPIIb-IIIa or GPIb, and caused only a modest decrease in GPIa. In washed platelets GPIIb-IIIa was extensively degraded by plasmin at 37 degrees C in the absence of exogenous Ca2+, conditions that destabilize the IIb-IIIa complex. Degradation of GPIb in washed platelets displayed a similar although less-marked dependence on temperature and the absence of Ca2+. The binding of activation-specific MoAbs did not increase during activation of plasminogen in plasma. We conclude that during pharmacologic fibrinolysis, reported inhibition of platelet function in plasma is not due to degradation of platelet-adhesive receptors. In addition, platelet activation observed during thrombolytic therapy does not appear to be a direct consequence of plasminogen activation.     

Streptokinase-induced platelet aggregation. Prevalence and mechanism

BACKGROUND. Streptokinase (SK) is a bacteria-derived protein and one of the plasminogen activators that is currently available for therapeutic use. Exposure to SK induces synthesis of specific antibodies that may initiate platelet aggregation and paradoxical clot propagation during treatment. METHODS AND RESULTS. Using platelet-rich plasma (PRP), we found that SK (5,000 units/ml) but not urokinase (2,500 units/ml) or recombinant tissue-type plasminogen activator (2,500 units/ml) caused platelet aggregation in PRP from 14 of 100 normal volunteers. In 13 consecutive patients treated with SK for acute myocardial infarction, SK-mediated platelet aggregation was induced in five patients within 1 week after treatment. SK-mediated platelet aggregation was associated with significantly increased titers of both anti-SK antibodies and SK-neutralizing activity in plasma; it was partially inhibited by aspirin (1 mM) and by aprotinin (500 kallikrein inhibitor units/ml) and completely inhibited by tranexamic acid (1 mM) and by prostaglandin E1 (9 microM). Addition of SK (1,000 or 5,000 units/ml) induce a statistically significant dose-dependent thromboxane B2 release in mixtures of PRP with plasma from subjects with SK-induced aggregation but not in samples of PRP mixed with plasma from nonresponders; addition of recombinant tissue-type plasminogen activator (1 or 50 micrograms/ml) did not induce thromboxane B2 release. Mixing experiments with PRP and immunoglobulin G from reactive and nonreactive donors revealed that SK-induced aggregation requires the presence of anti-SK antibodies. When 125I-SK (50 nM) was used, platelets preincubated with plasminogen (0.5 microM) bound 9,500 +/- 600 (mean +/- SEM, n = 6) molecules SK/platelet, which increased to 25,000 +/- 3,100 molecules/platelet after thrombin stimulation. Tranexamic acid (1 mM) blocked specific binding of SK to resting platelets. CONCLUSIONS. These data demonstrate that SK-induced platelet aggregation is initiated by the binding of anti-SK antibodies to the SK-plasminogen complex located on the platelet surface. SK-induced platelet activation may limit the therapeutic effectiveness of the drug, and in view of the high prevalence of aggregation in a normal population, prospective evaluation of the effects of platelet aggregation during treatment with SK is warranted.     

In vitro effect of plasmin on human platelet function in plasma. Inhibition of aggregation caused by fibrinogenolysis.

BACKGROUND. Plasmin has been reported both to activate platelets and to inhibit platelet functions. The latter effect was thought to be caused by proteolysis of the main membrane glycoproteins. METHODS AND RESULTS. We found that incubation of citrated human platelet-rich plasma with streptokinase (SK) (300 IU/ml) does not produce any detectable activation but leads to a time-dependent inhibition of ADP-induced aggregation accompanied by substantial fibrinogenolysis. These effects were abrogated by previous addition of a plasmin inhibitor, aprotinin. Crossover experiments (SK-treated or control platelets mixed with SK-treated or control plasma) demonstrated that the platelets remained functional and that the aggregation defect was caused by fibrinogenolysis. Further experiments (addition of purified fibrinogen to fibrinogen-depleted plasma with either SK or thrombin) suggested that in addition to the low residual level of fibrinogen, fibrinogen degradation products had an inhibitory effect. Under the same conditions, tissue-type plasminogen activator (t-PA) (3,000 ng/ml) had no effect on platelet aggregation, and plasma fibrinogen was not significantly lowered. The effects on glycoproteins IIb-IIIa of incubation with SK, t-PA, or plasmin were assessed with immunoblots with murine monoclonal antibodies directed against either part of the complex, which is the receptor for fibrinogen. Proteolysis was detected only in the presence of EDTA, a potent chelator of divalent cations. CONCLUSIONS. The incubation of human platelets in citrated plasma with SK concentrations obtained during therapy leads to an aggregation defect that is related to the decrease in fibrinogen, the adhesive protein involved in this function, and to the impeding effect of fibrinogen degradation products on its binding onto platelets but not to an alteration of the corresponding platelet receptor, the heterodimer glycoproteins IIb-IIIa.     

G?r?g Thrombosis Test: a global in-vitro test of platelet function and thrombolysis.

This is the first laboratory evaluation of a new instrument, designed to test both platelet function and thrombolytic activity from a native blood sample, in vitro. The inventor assumed that the reduction and arrest of blood flow was due to activation, aggregation and stabilized thrombus formation by shear-activated platelets, and that re-establishment of flow was due to thrombolysis. Morphologic and functional studies presented here confirm these mechanisms. In vitro tests provided incontestable evidence for the principal role of platelets in the obstruction of flow (occlusion time) and for thrombolysis as the principal mechanism underlying the restoration of blood flow (lysis time). In addition to aggregation, it is the explosive generation of thrombin by shear-activated platelets that results in the formation of an occlusive haemostatic thrombus. Anticoagulation of blood completely prevented occlusion. Platelet-rich thrombus formation (occlusion time) was dose-dependently inhibited by monoclonal antibody against platelet glycoprotein (GP) Ib (6B4 and 12E4), aurin tricarboxylic acid, monoclonal antibody against platelet GPIIb/IIIa (MA-16N7C2 and abciximab), a synthetic GPIIb/IIIa antagonist (TAK-029), thrombin inhibitor (argatroban), and anti-von Willebrand factor, but not by anti-fibrinogen. Plasminogen activator streptokinase (Varidase) and tissue-type plasminogen activator (Monteplase) dose-dependently enhanced thrombolysis (lysis time) without affecting platelet function (occlusion time). The test is specific for thrombolysis. The plasmin inhibitor tranexamic acid prevented plasminogen activator-induced thrombolysis, while inhibition of clot retraction by cytochalasin B did not affect the lysis time. This rapid and sensitive global test of platelet function and thrombolytic activity could be of great value both in research and in clinical practice.     

Plasmin accelerates platelet-dependent prothrombinase formation without activating the platelets

Patients with acute myocardial infarction who undergo thrombolytic therapy may shortly thereafter present evidence for increased platelet activation and thrombin activity, and recurrent thrombosis. This study investigated whether plasmin activates platelets and prothrombin in recalcified platelet-rich plasma (RPRP) to cause (at least in part) these side-effects of thrombolytic therapy. Plasmin (0.1 and 1.0 CU/ml) addition to RPRP with 1 μ M r-tick anticoagulant peptide (the latter a factor Xa inhibitor which abrogates prothrombin activation by prothrombinase at the concentration used) resulted in no change in the concentration of prothrombin fragment 1 + 2, or in the expression of GMP-140, the resting and activated GP IIb–IIIa conformers, and GPIb on platelets. Thus, plasmin neither activates platelets nor prothrombin in RPRP. However, plasmin accelerated platelet activation and secretion, and prothrombin fragment 1 + 2 production in RPRP. When combined with 1 μ M r-tick anticoagulant peptide and 1 or 10 n M α-thrombin to RPRP, plasmin also increased the number of GMP-140 molecules expressed/platelet without enhancing α-thrombin binding to the platelets. Additionally, plasmin accelerated prothrombin activation when it was added to washed platelets resuspended in factor V depleted plasma simultaneously with 10 m M CaCl₂, 10 n M α-thrombin for 10 s (to activate platelets and platelet factor V), followed by 4 μ M hirudin and 1 n M factor Xa. Thus, plasmin potentiates the platelet release reaction in response to α-thrombin (probably by increasing the availability of factor V on the platelets) to enhance prothrombin activation in RPRP. These actions of plasmin may contribute to the increased platelet activation and thrombotic side-effects that can occur after thrombolytic therapy.     

Enhanced prothrombin-converting activity and factor Xa binding of platelets activated by the alternative complement pathway

Platelet prothrombin-converting activity and factor Xa binding were studied after exposure of human platelet rich plasma (PRP) to various conditions leading to platelet activation. Zymosan resulted in increased platelet-bound C3, enhanced prothrombin-converting activity and increased factor Xa binding. Similar findings were observed with normal platelets resuspended in factor XII-deficient plasma. The combined use of zymosan and thrombin to activate platelets resulted in synergistic prothrombin-converting activity and factor Xa binding. In contrast, no synergism was obtained with the concomitant use of zymosan and collagen, suggesting that collagen and zymosan share the same pathway for platelet activation. Heterologous antibody to factor V completely inhibited the platelet prothrombin-converting activity for all modes of platelet activation, indicating that this activity is mediated by factor V.     

Platelet activation and subsequent inhibition by plasmin and recombinant tissue-type plasminogen activator.

The success of plasminogen activators in recanalizing occluded coronary arteries may be influenced by their effect on blood platelets; however, some previous studies have shown platelet activation by plasmin and thrombolytic agents while others have shown an inhibitory effect. Moreover, it has not been determined whether these effects reflect an alteration of intracellular signal transduction, fibrinogenolysis, degradation of adhesive protein receptors, or a combination of these events. To distinguish among these possibilities, the increase of cytoplasmic [Ca2+] [( Ca2+]i), which is an intracellular marker of platelet activation that precedes fibrinogen binding to the surface of activated platelets, was measured along with aggregation and release of 5-hydroxytryptamine (5-HT) in washed human platelets incubated with plasmin or recombinant tissue-type plasminogen activator (rt-PA). Plasmin (0.1 to 1.0 CU/mL) induced a prompt, concentration-dependent [Ca2+]i increase when added to platelets, but subsequently inhibited the [Ca2+]i increase in response to thrombin or the endoperoxide analog U44069. Platelet aggregation accompanied the [Ca2+]i increase if the platelets were stirred, while the aggregation of platelets unstirred during plasmin incubation was inhibited upon agonist addition and resumption of stirring. The release of 5-HT paralleled the [Ca2+]i increase induced by plasmin and was also inhibited after the subsequent addition of a second agonist. The effects of rt-PA, added with plasminogen (100 micrograms/mL), were similar to those of plasmin, and could be accounted for by the concentration of plasmin generated. The ADP scavengers apyrase and CP/CK each prevented the [Ca2+]i increase, and aggregation caused by plasmin or rt-PA, and also prevented their inhibitory effects on thrombin-induced activation. Thus, plasmin and rt-PA initially activate platelets, inducing a [Ca2+]i increase, and, if the platelets are stirred, aggregation. Such activation is followed by subsequent inhibition of cellular activation by a second agonist; the inhibitory effect is in proportion to the degree of initial activation, and ADP is an important cofactor in both processes. These platelet effects occur at rt-PA concentrations achievable clinically, and may affect the success of therapy with thrombolytic and adjunctive agents.     

Workshop: Developing an Agenda for Anticoagulation Management Research

Background. Platelet activation after myocardial infarction and thrombolytic treatment has been documented; but its relationship with the onset of symptoms and with thrombolysis, and the influence of aspirin in this setting is not well defined. In this study we measured platelet activity in the early phase of myocardial infarction treated with either streptokinase or rt-PA and evaluated influence of aspirin in this framework. Methods. 41 patients (age 57 ± 6 years) were treated with thrombolytic therapy during myocardial infarction; 21 patients with 1,5 million units of streptokinase (Group 1) and 20 patients with 100 mg of rt-PA (Group 2); 10 randomly selected patients in each group were given 500 mg aspirin i.v. prior to infusion of thrombolytic drug and, subsequently, 325 mg aspirin a day orally. Consecutive samples of beta-thromboglobulin (BTG), a marker of platelet activity, were collected at admission and after thrombolysis for the following 48 hours. Results. At admission, BTG plasma levels averaged 125 ± 31 IU/ml in Group 1 and 134 ± 35 IU/ml in Group 2 (p = 0.81). Thrombolysis was followed by a similar increase of platelet activity with maximal values reached at the 3rd hour in both groups (196 ± 43 IU/ml in Group 1 and 192 ± 39 in Group 2: p < 001 versus baseline and p NS between the groups). Higher levels of BTG were observed in streptokinase-treated group starting from the 24th hour (p < 0.05). Patients treated with aspirin showed lower levels of BTG only from the 48th hour after thrombolysis in both groups. An inverse correlation was found between time elapsed from onset of symptoms to admission and BTG value on admission (r = −0.86 p < 0.001); in patients admitted within two hours from the beginning of symptoms, with higher levels of BTG, thrombolysis not induced a significant increase of platelet activity; who was observed in patients admitted later. Conclusions. A marked platelet activation is more evident in the first hours of myocardial infarction and is differently influenced by thrombolytic treatment in relation with the delay of patient presentation. Both streptokinase and rt-PA induce a similar increase of platelet activity which is more persistent after streptokinase; cyclooxygenase inhibition seems to influence the platelet activity only from the second day. Condensed abstract. Influence of aspirin on platelet activity during myocardial infarction treated with thrombolytic therapy is not well defined. Twenty-one patients treated with streptokinase (Group 1) and 20 patients treated with rt-PA (Group 2) were randomly selected to give 500 mg of aspirin i.v. prior thrombolysis and subsequently 325 mg a day orally. Platelet activity was evaluated through determination of beta-thromboglobulin plasma levels. Thrombolysis was followed by a similar increase of platelet activity in both groups with maximal values reached at the 3rd hour; higher levels of beta-thromboglobulin were observed in streptokinase-treated group starting from 24th hour. Treatment with aspirin reduced beta-thromboglobulin plasma levels only at 48th hour in both groups. This revised version was published online in August 2006 with corrections to the Cover Date.     

Platelet aggregation impacts thrombin generation assessed by calibrated automated thrombography

A calibrated automated thrombogram (CAT) is performed usually with human platelet-free plasma (PFP) but may be more relevant with platelet-rich plasma (PRP). In this case, platelets are not stimulated by subendothelial molecules like collagen. Our aim was to assess the consequence of strong (collagen) or weak (ADP) induction of platelet release and aggregation on thrombin generation. Platelet aggregation in PRP was triggered with 10 µg/mL collagen or 10 µM ADP using a lumi-aggregometer. Thrombin generation curves were monitored by CAT in different conditions: PRP, PRP with activated platelets (actPRP), aggregated PRP (agPRP), aggregated platelets resuspended in autologous PFP (resPRP), PFP and PFP obtained after aggregation (agPFP). We found a 3-fold shortening of the lag time and time to peak and a marked increase in velocity and thrombin peak without changes in endogenous thrombin potential (ETP) in agPRP with both agonists compared with PRP. The same holds true in agPFP but with a marked increase in ETP compared with PFP. Similar changes in the kinetics of thrombin generation were observed with actPRP-collagen and to a lesser extent in resPRP-collagen compared with PRP. By contrast, there were no modifications of the thrombin generation curves in actPRP-ADP. Alpha-2-macroglobin-thrombin complexes were unchanged in the different PRP conditions but were increased in PFP prepared from agPFP compared to control PFP. Platelet aggregation during activation by agonists other than thrombin did not increase thrombin generation but accelerated its kinetics mainly via platelet content release and platelet-derived extracellular vesicules formation. In diseases characterized by altered platelet granule content or release as well as altered platelet activation, a platelet aggregation step prior to CAT analysis may be clinically relevant to improve laboratory estimation of the bleeding/thrombotic balance.     

Relative efficacy of antithrombin compared with antiplatelet agents in accelerating coronary thrombolysis and preventing early reocclusion

BACKGROUND. Optimal coronary thrombolysis should be prompt and persistent. Although activation of platelets and increased thrombin activity have been associated with clinical thrombolysis, the role of each in delaying thrombolysis or inducing early coronary reocclusion has been difficult to define. METHODS AND RESULTS. In conscious dogs with coronary thrombosis induced by electrical current, we assessed the impact on the rapidity of thrombolysis and the incidence of reocclusion of two types of adjunctive treatment given concomitantly with intravenous tissue-type plasminogen activator (t-PA): 1) inhibition of platelet function with a peptide mimetic antagonist of platelet glycoprotein IIb/IIIa receptors or with lysine acetylsalicylic acid (ASA) and 2) inhibition of thrombin activity with recombinant hirudin or with heparin. ASA but not the receptor antagonist shortened the time to thrombolysis with t-PA (20 +/- 13 [mean +/- SD] minutes with ASA, 36 +/- 15 minutes with receptor antagonist, and 43 +/- 16 minutes with the saline control). Reocclusion occurred promptly after completion of the infusion of t-PA in all seven dogs given saline. Reocclusion was delayed and prevented in some dogs within 90 minutes after the end of the infusion of t-PA by both antiplatelet agents but still occurred in 42% despite continued inhibition of platelet function (i.e., three of six dogs given ASA and two of six given receptor antagonist). In contrast, inhibition of thrombin activity with recombinant hirudin in a dose that prolonged the partial thromboplastin time modestly (1.5-2-fold) resulted in accelerated lysis (19 +/- 10 minutes) and prevention of reocclusion in each of six dogs. Heparin given in doses that elicited similar prolongation of the partial thromboplastin time did not accelerate lysis nor prevent reocclusion, which occurred in five of six dogs. CONCLUSIONS. Inhibition of thrombin by recombinant hirudin facilitates thrombolysis and maintains patency of coronary arteries recanalized with t-PA particularly effectively. The benefit conferred may reflect direct anticoagulant effects plus diminished activation of platelets secondary to decreased thrombin activity.     

Plasminogen interactions with platelets in plasma

In this report we used a fluorescent flow cytometry-based assay to examine plasminogen binding to platelets in plasma. Our data indicate that platelets activated in platelet-rich plasma (PRP) by adenosine-5'- diphosphate (ADP) or thrombin bind plasminogen to their surface. Fab fragments of the monoclonal antibody LJ-CP8 that are directed against the fibrinogen binding site on the glycoprotein (GP) IIb-IIIa complex inhibit both plasminogen and fibrinogen binding to ADP-stimulated platelets as does 5 mmol/L EDTA. Platelet aggregation and plasminogen and fibrinogen binding are also concurrently inhibited by the Gly-Arg- Asp (RGD) analogue Gly-Arg-Gly-Asp-Ser (GRGDS) when it is added to PRP before ADP stimulation. The scrambled peptide analogue SDGRG has no effect. The monoclonal antibody 6D1, directed against the von Willebrand factor binding site on GPIb, has no effect on plasminogen- platelet binding, nor does antithrombospondin antibody. epsilon- Aminocaproic acid (EACA), however, inhibits plasminogen binding to ADP- activated platelets. These data indicate that plasminogen binds to platelets activated in plasma, that binding occurs on platelet GPIIb/IIIa, and that binding may be mediated via plasminogen association with fibrinogen via lysine binding domains. Finally, we found both plasminogen and fibrinogen on resting platelets in PRP and demonstrated that they are equally displaced by EDTA, LJ-CP8, and 10E5 (an additional anti-GPIIb/IIIa monoclonal antibody). Plasminogen is also equally displaced by EACA. These data suggest that plasminogen is also bound to GPIIb/IIIa on resting platelets, possibly also via interaction with fibrinogen.     

Streptokinase-induced platelet activation involves antistreptokinase antibodies and cleavage of protease-activated receptor-1

Streptokinase activates platelets, limiting its effectiveness as a thrombolytic agent. The role of antistreptokinase antibodies and proteases in streptokinase-induced platelet activation was investigated. Streptokinase induced localization of human IgG to the platelet surface, platelet aggregation, and thromboxane A(2) production. These effects were inhibited by a monoclonal antibody to the platelet Fc receptor, IV.3. The platelet response to streptokinase was also blocked by an antibody directed against the cleavage site of the platelet thrombin receptor, protease-activated receptor-1 (PAR-1), but not by hirudin or an active site thrombin inhibitor, Ro46-6240. In plasma depleted of plasminogen, exogenous wild-type plasminogen, but not an inactive mutant protein, S(741)A plasminogen, supported platelet aggregation, suggesting that the protease cleaving PAR-1 was streptokinase-plasminogen. Streptokinase-plasminogen cleaved a synthetic peptide corresponding to PAR-1, resulting in generation of PAR-1 tethered ligand sequence and selectively reduced binding of a cleavage-sensitive PAR-1 antibody in intact cells. A combination of streptokinase, plasminogen, and antistreptokinase antibodies activated human erythroleukemic cells and was inhibited by pretreatment with IV.3 or pretreating the cells with the PAR-1 agonist SFLLRN, suggesting Fc receptor and PAR-1 interactions are necessary for cell activation in this system also. Streptokinase-induced platelet activation is dependent on both antistreptokinase-Fc receptor interactions and cleavage of PAR-1. (Blood. 2000;95:1301-1308)     

Temporal effects of thrombolytic agents on platelet function in vivo and their modulation by prostaglandins

To examine the temporal effects of plasmin generated in vivo on platelet function, we infused tissue-type plasminogen activator (t-PA) in rabbits over 3 hours and measured ex vivo platelet aggregation. We noted an initial increase in the aggregation response to ADP occurring 30 minutes after the start of infusion. This enhanced response was short-lived and by 180 minutes was reduced, compared with pretreatment levels. Baseline aggregation response was restored by 240 minutes. This pattern of aggregation response to t-PA infusion was also seen with thrombin as the agonist. Coinfusion of either prostaglandin I2 or prostaglandin E1 abolished the initial hyperaggregable phase induced by t-PA; the hypoaggregable phase occurred earlier (after 60 minutes) and persisted throughout the 1-hour recovery period. Similarly, streptokinase infused for 1 hour also increased platelet aggregation at early times and then reduced aggregation responses after the first hour. Plasma plasmin activity increased as expected with t-PA infusion alone, peaking at 30 minutes and returning to baseline by the first hour. Interestingly, prostaglandin E1 blunted the rise in plasma plasmin activity. This same dose of prostaglandin E1 or prostaglandin I2 used alone did not appreciably alter platelet function at any time during the experiment. Our data show that therapeutic doses of t-PA or streptokinase produce a biphasic effect on platelet aggregation response in the rabbit. Coinfusion of either of the antiplatelet agents, prostaglandin E1 or prostaglandin I2, abolishes the hyperaggregable phase and prolongs the inhibitory effects on platelet aggregation produced by t-PA. These data suggest that the effects of thrombolytic agents on platelet function are complex and can be modulated by antiplatelet prostaglandins.     

Thrombin binding to platelets and their activation in plasma

Summary. The interactions of α-thrombin with platelets are critical in haemostasis and arterial thrombosis. This study established methods for characterizing the binding of α-thrombin to platelets and some of its consequences in platelet-rich plasma. The binding of α-thrombin to platelets and the subsequent platelet activation were quantified by flow cytometry, using affinity purified polyclonal antibodies to human α-thrombin and a monoclonal antibody to GMP-140, respectively. Dose-dependent binding of α-thrombin to platelets and their activation occurred in parallel, both reaching the maxima for each enzyme concentration within 10 s after → 1.0 n m α-thrombin was added to recalcified PRP containing 1 μ m recombinant tick anticoagulant peptide. The tick anticoagulant peptide abrogated prothrombin activation in the platelet-rich plasma. α-Thrombin binding to platelets, and their activation, were abrogated by a monoclonal antibody to the hirudin tail-like domain of the seven transmembrane thrombin receptor on platelets. Therefore this receptor represents an important site for α-thrombin binding to platelets suspended in plasma. d -Phe-Pro-ArgCH₂-α-thrombin only bound to platelets when its concentration was → 100 n m , and it did so without inhibiting platelet activation by α-thrombin. Whereas concentrations of hirudin equimolar to those of α-thrombin failed to abrogate α-thrombin-mediated activation of platelets, a 10-fold molar excesses of hirudin over α-thrombin abrogated α-thrombin binding to platelets. The demonstration that → 1.0 n m α-thrombin can bind to platelets and initiate their activation raises the possibility that the levels of thrombin generated in venous and arterial thrombosis contribute to platelet activation in vivo .