In vitro Simulation of Therapeutic Plasmatic Fibrinolysis

Fluorescently conjugated annular fibrin clot for multiplexed real-time digestion analysis

Impaired fibrinolysis has long been considered as a risk factor for venous thromboembolism. Fibrin clots formed at physiological concentrations are promising substrates for monitoring fibrinolytic performance as they offer clot microstructures resembling in vivo. Here we introduce a fluorescently labeled fibrin clot lysis assay which leverages a unique annular clot geometry assayed using a microplate reader. A physiologically relevant fibrin clotting formulation was explored to achieve high assay sensitivity while minimizing labeling impact as fluorescence isothiocyanate (FITC)-fibrin(ogen) conjugations significantly affect both fibrin polymerization and fibrinolysis. Clot characteristics were examined using thromboelastography (TEG), turbidity, scanning electron microscopy, and confocal microscopy. Sample fibrinolytic activities at varying plasmin, plasminogen, and tissue plasminogen activator (tPA) concentrations were assessed in the present study and results were compared to an S2251 chromogenic assay. The optimized physiologically relevant clot substrate showed minimal reporter-conjugation impact with nearly physiological clot properties. The assay demonstrated good reproducibility, wide working range, kinetic read ability, low limit of detection, and the capability to distinguish fibrin binding-related lytic performance. In combination with its ease for multiplexing, it also has applications as a convenient platform for assessing patient fibrinolytic potential and screening thrombolytic drug activities in personalized medical applications.

Functional Determination of Plasminin Arginine-stabilized Plasma

Reliable data on plasmin activities in blood of patients during fibrinolytic treatment are lacking. This is due to continuing plasminogen activation by plasminogen activators after blood withdrawal. The purpose of this study was to establish a new method for stabilization of blood and to detect plasmin activity in stabilized plasma. For optimization of plasma stabilization by arginine, 50 μL pooled normal citrated plasma was incubated with 50 μL of 0 to 1500 m M arginine, pH 8.7, and 25 μL 100 IU/mL u-PA, 1250 IU/mL t-PA, 10000 U/mL reteplase, 400 U/mL plasminogen-streptokinase-activator complex, 10 μg/mL tenecteplase in 6% BSA-PBS or 25 μL 25 μg/mL plasmin in 20% glycerol. Twenty-five microliters 3 m M HDVal-Leu-Lys-pNA were added immediately (1 step) or after 90 minutes (room temperature [RT]). The same experiment was performed with pooled normal citrated plasma supplemented with 3.2 mg/mL EDTA, preoxidized with 0 m M or 20 m M chloramine-T for 10 minutes (37°C). For optimization of plasmin activity, the oxidation time of the arginine-stabilized plasma sample containing 0.5 U/mL active plasmin and the chloramine-T amount was varied. Citrated plasma is stabilized against the in vitro action of all six plasminogen activators tested if the final arginine concentration is greater than 500 mM. Neither the addition of EDTA nor the addition of chloramine-T changes this plasma-stabilizing power of arginine. The optimized functional plasmin assay consists of incubation of 10 μL arginine-stabilized plasma with 10 μL 1.5 M arginine, pH 8.7, and 10 μL 100 m MCT in PBS. After 30 minutes (37°C), 75 μL 1.2 M KCl, 1.6 M Arg, 0.75 m M Val-Leu-Lys-pNA (Stop-CS Reagent), and 175 μL 6% BSAPBS are added and the absorbance increase (ΔA) at 405 nm is determined. With the present arginine stabilization procedure of plasma and the determination of plasmin activity in arginine-stabilized plasma as described, it is feasible to determine the activity of plasmin in blood of patients receiving fibrinolytic treatment without artefactual in vitro changes in the samples.

Leukocytes may have 2 opposing effects in intravenous rtPA treatment for ischemic stroke

We hypothesized that leukocytes have 2 opposing effects on patients with ischemic stroke treated with recombinant tissue plasminogen activator (rtPA). Patients with ischemic stroke treated with rtPA were divided into 2 groups using the peripheral leukocyte count: high leukocyte group (HLG) and low leukocyte group (LLG) and were evaluated with the National Institutes of Health stroke scale (NIHSS) during the first 24 hours. We defined significant improvement (SI) as NIHSS improving by more than 50% from the baseline, and deterioration following improvement (DFI) as the achievement of SI within 24 hours but its subsequent loss at 24 hours. Fifty-three patients were enrolled, and the rate of SI within 24 hours was higher in HLG than in LLG (85.2% vs 42.3%, P = .0011). However, the rate of DFI was significantly higher in HLG than in LLG (29.6% vs 7.7%, P = .0413). We found that leukocytes might have not only deleterious but also beneficial effects in intravenous rtPA treatment.

Apolipoprotein A-I breakdown is induced by thrombolysis in coronary patients

BACKGROUND

The outcome of percutaneous coronary intervention (PCI) is apparently worse in patients receiving a prior thrombolytic therapy ('facilitated PCI'). Recombinant tissue-type plasminogen activator (rt-PA) can degrade circulating high-density lipoproteins (HDL) bound apolipoprotein A-I (apoA-I), thus possibly reducing the vascular protective activity. There have never been reports of the detection of apolipoprotein breakdown products in the circulation.

AIM

We studied the potential interactions between the protein components of HDL and tenecteplase, infused as thrombolytic therapy.

METHODS

Sera from a total of 40 patients with acute myocardial infarction (AMI), unstable angina (UA), and dilative cardiomyopathy (controls) were investigated. AMI patients underwent either immediate PCI or were treated with tenecteplase thrombolysis.

RESULTS

Products of extensive proteolysis of apoA-I were found in many acute coronary patients treated with tenecteplase, and in some AMI patients before starting the treatment (time 0). These were not detected in controls, UA patients as well as AMI patients undergoing immediate PCI. Small pre-beta-HDLs were selectively degraded.

CONCLUSION

Significant apoA-I degradation occurs in AMI patients after thrombolytic treatment. This finding may provide a potential mechanism for the apparent reduction of benefit of facilitated versus nonfacilitated PCI.

Monitoring of plasmin and plasminogen activator activity in blood of patients under fibrinolytic treatment by reteplase

There are no reliable data on plasmin or plasminogen activator (PA) activities in blood of patients receiving fibrinolytic treatment. This is due to continuing in vitro action of PA after blood withdrawal. These artefactual changes of PA or plasmin activities have been prevented by arginine stabilization of blood samples of myocardial infarction patients treated with plasminogen activators. Twelve patients with myocardial infarction were treated with reteplase 2 x 10,000,000 units in bolus application; one patient was treated with 100 mg t-PA in continuous infusion. Blood was immediately stabilized with EDTA and arginine. The plasma was analyzed with newly developed assays for plasmin and PA. Maximal plasmin activities in blood were obtained at 40 to 60 minutes reteplase treatment time (0.1-0.6 U/mL = approximately 0.05-0.3 micromol/L plasmin). The 50% clearance rate for plasmatic Pli was greater than 30 minutes. The plasmatic reteplase concentration peaked at approximately 2,000 U/mL after the first bolus infusion and at approximately 1,500-3,500 U/mL after the second bolus infusion. Reteplase was cleared to 50% within less than 30 minutes, also with great inter-individual variation. Arginine stabilization of blood allows reliable determinations of activities of plasmin and PA in blood of patients under fibrinolytic treatment: substantial plasmin activities occur in patients treated by reteplase. Therapeutic thrombolysis might be improved, imitating the physiologic cellular thrombolysis; i.e., polymorphonuclear phagocytes (PMN) that can be activated by singlet oxygen ((1)O(2)). PMN might be superior to PA in selective lysis of pathologic thrombi.

Clinical and biochemical predictors affect the choice and the short-term outcomes of different thrombolytic agents in acute myocardial infarction

BACKGROUND

The presence of plasminogen activator inhibitor-1, angiotensin-converting enzyme and others may play a role in unsuccessful recanalization after thrombolytic therapy.

OBJECTIVES

To find out the clinical and biochemical predictors that may affect the choice and short-term outcomes following different thrombolytic agents in acute myocardial infarction.

METHODOLOGY

Angiotensin-converting enzyme and plasminogen activator inhibitor-1 plasma levels of 184 patients with acute myocardial infarction, treated with streptokinase, metalyze or reteplase, were determined. Failure of thrombolysis was assessed by noninvasive reperfusion criteria. Prolonged hospitalization, impaired left ventricular ejection fraction and reinfarction were considered as short-term outcomes.

RESULTS

Patients who received streptokinase developed higher incidence of >50% resolution of ST-segment elevation (82.5 vs. 64.7%, P-value<0.05, in comparison with metalyze and 82.5 vs. 55.7%, P-value 0.001, in comparison with reteplase) than those who received other thrombolytic agents. High plasma angiotensin-converting enzyme was associated with prolonged hospitalization (55, 63 and 94%, P<0.02) following streptokinase, metalyze and reteplase, respectively. High plasma plasminogen activator inhibitor-1 is associated with impaired left ventricular ejection fraction (55.3, 76.7 and 68.5%, P<0.09), ST resolution<50% (13.2, 36.7 and 37.5%, P=0.03), ST resolution>50% (86.8, 63.3 and 62.5%, P=0.03) following streptokinase, metalyze and reteplase, respectively.

CONCLUSIONS

Rapid determination of pretreatment angiotensin-converting enzyme and plasminogen activator inhibitor-1 plasma levels in patients with acute myocardial infarction may influence the choice and outcomes of the thrombolytic agents. The presence of a high plasma level of either angiotensin-converting enzyme or plasminogen activator inhibitor-1 is significantly associated with adverse short-term outcomes after treatment with reteplase or metalyze.

In vitro simulation of therapeutic thrombolysis with microtiter plate clot-lysis assay

Only limited comparable data are available on the clot lysis power of the clinically used plasminogen activators (PA). Here the PA were used at different clinically relevant concentrations, and the lysis of the microclots was determined. A microclot lysis assay was used to study thrombolysis by urokinase, tissue-PA (t-PA), streptokinase, plasminogen-streptokinase activator complex (PSAC), reteplase, or tenecteplase. The clot turbidity served as a tool to determine clot mass: 100 microL fresh microclots were incubated with 25 microL PA in 6% bovine serum albumin (BSA)-phosphate-buffered saline (PBS) and 100 microL BSA-PBS or pooled normal human plasma; that is, the PA were in the liquid supernatant of a plasma clot and were not entrapped in the clot, an assay system comparable to normal physiology. The turbidity was determined after 0 to 5 hours (37 degrees C) by a microtiter plate reader. The lysable clot turbidity (clot mass) was expressed in percent of 100% lysable clot control. The clot lysis activity is 100% minus the clot mass in percent. The effective doses at 50% (ED(50)) of lysis of fresh clots after 4 hours (37 degrees C) with 6% BSA or pooled normal human plasma in the clot-supernatant were urokinase 128 or 180 IU/mL; t-PA 0.3 or 0.2 microg/mL; streptokinase 215 or 1371 IU/mL; PSAC 60 or 91 U/mL; reteplase 664 or 996 U/mL; tenecteplase 0.2 or 0.2 microg/mL. The presence of a plasma thrombus with plasma supernatant increases the activity of t-PA approximately 20-fold and that of tenecteplase approximately 400-fold after 4 hours (37 degrees C), when compared to urokinase; in contrast, the lytic activity induced by reteplase decreases; i.e., the plasmin generated by reteplase is hampered on its lytic action against a thrombus. When comparing the clot lysability of microclots of 29 different donors, the only correlation (r > 0.6) was that between u-PA and t-PA. The lysability of individual clots by PA can be measured with the present routine-suited technique. It is suggested that different thrombolytic agents or concentrations thereof would have a different clinical outcome in different individuals.

Functional determination of plasminogen activator in arginine-stabilized plasma

Reliable data on plasminogen activator (PA) activities in blood of patients receiving fibrinolytic treatment are lacking. This is due to the continuing in vitro action of PA after blood withdrawal. We have elaborated a new simple stabilization technique for plasma involving the addition of arginine in final concentrations greater than 500 mM. In this study, new assays for PA in stabilized plasma are developed. The assay was performed with substrate plasma, that is, pooled normal plasma, preoxidized with chloramine-T; oxidant amount and oxidation time were optimized. The chloramine consumption by plasma was assayed with a KJ-assay (absorbance increase at 405 nm by addition of 200 microL 4 M KJ to 25 microL oxidized plasma). The substrate plasma concentration in the PA assay and the PA acting time was optimized. The inhibition of PA by the cations Na(+), K(+), Mg(2+), and Ca(2+) was evaluated. The optimized PA assay consists of incubation of 10 microL arginine-stabilized plasma with 10 microL 1.5 M arginine, pH 8.7 and 10 microL 100 mM CT in PBS. After 30 minutes (37 degrees C), 175 microL 15 mM CT oxidized EDTA plasma are added. After 40 minutes (37 degrees C), 75 microL Stop-CS Reagent is added and DeltaA at 405 nm was determined, giving PA + plasmin activity in plasma. A control value (basal plasmin activity) consists of the addition of Stop-CS Reagent before 175 microL oxidized EDTA plasma. To obtain plasmatic PA activity, the control value has to be subtracted from the PA main value. The assay is matrix-independent and linear up to 1250 IU/mL t-PA, 790 U/mL reteplase, or 199 IU/mL u-PA (37 nM). With arginine stabilization of plasma and the described determination of plasminogen activator activity in arginine-stabilized plasma, it is feasible to determine the activity of plasminogen activators in blood of patients receiving fibrinolytic treatment without artefactual in vitro changes of the samples.