One type of therapy for thromboembolism is plasmatic thrombolysis. Several plasminogen activators (PA) are clinically available, including urokinase (u-PA), tissue plasminogen activator (t-PA), streptokinase (SK), plasminogen-streptokinase-activator-complex (PSAC), or mutants of t-PA such as reteplase (RP) or tenecteplase (TP). Therapeutic plasmatic fibrinolysis was simulated, using the PA at relevant plasma concentrations, and plasmin (Pli) and PA activities were determined. Normal citrated plasma was supplemented with 31 to 1,000 IU/mL u-PA, 0.31 to 20 microg/mL t-PA, 125 to 4,000 IU/mL SK, 12.5 to 400 U/mL PSAC, 125 to 4,000 U/mL RP, or 0.31 to 10 microg/mL TP. Ten IU/mL urokinase was also incubated with pooled plasma of stroke patients, that was previously oxidized with the singlet oxygen (1O2) donor chloramine T (CT), to destroy plasmatic PAI-1 and alpha2-antiplasmin. After 0 to 80 minutes (37 degrees C), 50-microL samples were withdrawn and added to 100 microL 1.5 M arginine, pH 8.7, and oxidized with 50 microL of 20 mM CT. For determination of plasmin activity, 10 microL thereof was incubated with 150 microL 1.5 M arginine, pH 8.7, and 100 microL 20 mM CT preoxidized (15 minutes 37 degrees C) pooled normal citrate buffered EDTA-plasma for 30 minutes (37 degrees C). For determination of [PA+Pli]-activity, arginine was added after this incubation. 25-microL 6 mM Val-Leu-Lys-pNA were added and deltaA/h at room temperature (RT) was monitored, using a microtiterplate reader. [PA+Pli]-Pli = PA. The PA concentration required to induce 25% [ED25] of the maximally inducible Pli-activity in plasma (= 1 U/mL = 45 mg/L = 0.53 micromol/L active Pli; deltaA = 363 +/- 8 mA/h RT) after 10 minutes (37 degrees C) were 320 IU/mL u-PA, 8 microg/mL t-PA, 140 U/mL PSAC, 6,000 IU/mL SK, 720 U/mL RP, and approximately 150 microg/mL TP. The approximate activity half-lives of the PA in plasma were 30 minutes for u-PA, 30 minutes for t-PA, greater than 80 minutes for SK, greater than 80 minutes for PSAC, 50 minutes for RP, and 80 minutes for TP. The present study shows--for the first time--a combined kinetic in vitro simulation of the plasmatic activity of six different PAs. At clinically used concentrations, RP induces the highest plasmatic Pli activity. Due to unselective generation of plasmin in plasma, all PA are of some danger in inducing severe hemorrhagias. Clinical thrombolysis might be improved by usage of more physiologic activators of thrombolysis, such as activators of polymorphonuclear neutrophils.