Combination treatment with rt-PA is more effective than rt-PA alone in an in vitro human clot model

Incidence of intra-cranial hemorrhage linked to treatment of ischemic stroke with recombinant tissue plasminogen activator (rt-PA) has led to interest in adjuvant therapies such as ultrasound (US) or plasminogen, to enhance rt-PA efficacy and improve patient safety. High-frequency US (～MHz) such as 2-MHz transcranial Doppler (TCD) has demonstrated increased recanalization in situ. Low-frequency US (～kHz) enhanced thrombolysis (UET) has demonstrated higher lytic capabilities but has been associated with incidence of intracerebral hemorrhage in some clinical trials. In vitro studies using plasminogen have shown enhancement of lysis. This study compared rt-PA-induced lysis using adjuvant therapies, with 120-kHz or 2-MHz pulsed US, or plasminogen, in an in vitro human whole blood clot model. Blood was drawn from 30 subjects after local institutional approval. Clots were exposed to rt-PA at concentrations of 0 to 3.15 μg/ml. Clots were exposed to rt-PA alone (rt-PA) or in combination with plasminogen (Plg), 120-kHz US (120-kHz), or 2-MHz US (2-MHz). Thrombolytic efficacy was determined by assessing the percent fractional clot loss (FCL) at 30 minutes using microscopic imaging. There was no enhancement of lysis for combination therapy with [rt-PA]=0 μg/ml. Adding rt- PA increased lysis for all groups. As [rt-PA] increased, lysis tended to increase for 120-kHz and Plg (FCL: from 50% to 70%, 120-kHz; 65% to 83%, Plg) but not for 2-MHz (58% to 52%). Lytic efficacy in combination therapy depends on rt- PA concentration and the adjuvant therapy type. For non-zero rt-PA concentrations, all combination therapies produced more lysis than rt-PA alone.     

Ultrasound has synergistic effects in vitro with tirofiban and heparin for thrombus dissolution

Previous studies have shown synergism between ultrasound and thrombolytic agents or microbubbles on blood clot dissolution. It has not been investigated whether heparin or glycoprotein IIb/IIIa blockers enhance clot lysis by ultrasound. We compared the blood clot dissolution effect of saline, heparin, tissue plasminogen activator (tPA), tirofiban, and an echocardiographic contrast media (Optison) without and with ultrasound application. Human blood clots from four donors, 2 to 4 hours old, were cut into 200- to 400-mg sections, weighed, and immersed for 2 minutes in 1 L of normal saline 0.9% solution containing either heparin 1000 U, tirofiban 150 μg, tPA 20 mg, Optison 0.5 mL, or normal saline alone. Clots were randomized to 2 minutes ultrasound application or immersion alone without ultrasound. Ultrasound was applied with a 19.5 KHz catheter. After treatment, the clots were weighed, and the absolute and percent difference in weight was calculated. Immersion in heparin, tirofiban, and tPA without ultrasound did not augment clot disruption relative to normal saline alone. Immersion in Optison (p=0.07) tended to result in less lysis than saline alone. Ultrasound enhanced clot dissolution compared to immersion alone with: saline (48.1±15.3% vs. 26.0±13.8%, p<0.0000002); heparin (60.8±17.5% vs. 30.8±15.1%, p=0.000001); tirofiban (61.8±13.6% vs. 30.1±12.2%, p<0.0000001); tPA (53.1±15.3% vs. 30.2±11.5%, p<0.000002); and Optison (47.8±16.0% vs. 18.4±11.5%, p<0.0000001). The combination of tirofiban with ultrasound, as well as heparin with ultrasound, was associated with a significant augmentation of clot dissolution compared with the saline plus ultrasound group (p=0.002, 0.013, respectively). Ultrasound with tPA or with Optison had no significant augmentation of clot dissolution over the ultrasound+saline effect. This in vitro study of catheter-delivered high-intensity low-frequency ultrasound demonstrates that: (1) tirofiban and heparin, as well as perfluorocarbon microbubbles, augment clot dissolution by ultrasound; (2) augmentation of clot dissolution is evident even after only brief exposure of ultrasound and the drug studied.     

DIFFERENTIAL EFFECTS OF LYS- AND MINI-PLASMINOGEN ON CLOT LYSIS INDUCED BY RECOMBINANT UROKINASE AND RECOMBINANT PRO-UROKINASE IN A CANINE THROMBOSIS MODEL

These studies were conducted to examine the lytic efficacy of recombinant urokinase (r-UK) and pro-urokinase (r-proUK) in the presence and absence of truncated forms of plasminogen. Due to differences in their structures, these modified proteins are more readily activated to plasmin than the circulating form of plasminogen. Use of such modified substrates for plasminogen activators may improve the clinical outcome in patients treated for a variety of thrombotic diseases. Lys-plasminogen (46 units) or mini-plasminogen (in units of equivalent chromogenic activity), in conjunction with r-UK (7,500 units), were administered in the absence of heparin to dogs (9 – 11 kg) in which a radiolabelled thrombus was formed in a femoral artery. Fibrinolysis was measured as a loss of radioactivity from the clot. After intra-arterial administration of the agents, clot lysis was 48 ± 8%, 50 ± 9% and 75 ± 2% in the presence of r-UK + vehicle, r-UK + lys-plasminogen, and r-UK + mini-plasminogen, respectively. When these treatment groups were examined in the presence of heparin (500 units + 350 units/hour) in a second study, r-UK (2,000 units) produced clot lysis of 54 ± 35; addition of lys- or mini-plasminogen to the regimen resulted in lysis of 62 ± 9% and 46 ± 10%, respectively. A third phase of the study examined r-proUK (1,000 units) with heparin; in this case, lysis was 51 ± 9% in the presence of vehicle, but 55 ± 17% and 10 ± 5% when lys- and mini-plasminogen were administered, respectively. Flow restoration, measured in the femoral artery in each experiment, generally paralleled the lytic profile. The results indicate that supplementation with mini-plasminogen is only useful when added to a lytic regimen in the absence of heparin, and that lys-plasminogen, in conjunction with either of the lytic agents, does not improve clot lysis in this canine model.     

Influence of exogenous and endogenous tissue-type plasminogen activator on the lysability of clots in a plasma milieu in vitro

The fibrinolytic potential of tissue-type plasminogen activator (t-PA) either incorporated in a clot (endogenous) or added to the surrounding plasma (exogenous), was studied in an in vitro system consisting of 125I-labeled human plasma clots (200 microliters) immersed in human plasma (2 ml). Clot lysis was measured as a function of endogenous t-PA concentration (in the absence of added exogenous t-PA), as a function of exogenous t-PA concentration (without added endogenous t-PA) and as a function of the same concentration of both endogenous and exogenous t-PA. Equivalent clot lysis was obtained with a 2 to 4 times lower concentration of endogenous t-PA as compared to exogenous t-PA, corresponding to a 20 to 40 times smaller total amount of endogenous versus exogenous t-PA. Fifty percent lysis in 5 hrs was obtained with about 5 IU/ml of endogenous t-PA or with 10 IU/ml of exogenous t-PA. The presence of both exogenous (10 IU/ml) and endogenous (5 IU/ml) t-PA resulted in 50 percent lysis in 1.5 hrs, indicating that t-PA incorporated in a thrombus contributes significantly to its lysis by exogenous t-PA. Similar results were obtained with plasma obtained after 10 min of venous occlusion in seven healthy subjects. Spontaneous clot lysis within 5 hrs was only observed with post-occlusion clots in pre- or post- occlusion plasma in two subjects in whom the t-PA level rose to 10-15 IU t-PA/ml. In the five other subjects with post-occlusion t-PA levels below 2 IU/ml, no clot lysis was observed within 24 hrs. The influence of the fast-acting inhibitor of t-PA on clot lysability by endogenous or exogenous t-PA was investigated by immersing clots prepared from normal or inhibitor-rich plasma (endogenous inhibitor) in normal or inhibitor-rich plasma (exogenous inhibitor). Exogenous t-PA inhibitor efficiently neutralizes clot lysis by both exogenous and endogenous t-PA. Endogenous t-PA inhibitor, however, efficiently neutralizes endogenous t-PA but has little influence on clot lysis by exogenous t-PA. These findings indicate that t-PA inhibitor is not concentrated into a clot and that t-PA inhibitor in plasma efficiently neutralizes t-PA incorporated in a clot. alpha 2-Antiplasmin depleted plasma clots were more susceptible to lysis by both endogenous and exogenous t-PA than normal clots.(ABSTRACT TRUNCATED AT 400 WORDS)     

Correlation between progressive adsorption of plasminogen to blood clots and their sensitivity to lysis

The binding of plasminogen to preformed human plasma clots immersed in citrated human plasma was measured and correlated with the sensitivity of these clots to lysis with recombinant tissue-type plasminogen activator (rt-PA), recombinant single-chain urokinase-type plasminogen activator (rscu-PA) or two chain urokinase-type plasminogen activator (tcu-PA, urokinase). When 0.15 ml plasma clots were compressed mechanically to about 1% of their original weight, and immersed in 0.15 ml plasma, 131I-labeled native plasminogen (Glu-plasminogen) adsorbed progressively from the plasma milieu onto the clot; binding was 3 +/- 1% (n = 10) after 1 h, 7 +/- 1% after 12 h and 12 +/- 1% after 48 h. This was associated with an increased sensitivity of the clot to lysis; 50% clot lysis in 4 h was obtained with 65 +/- 5 ng/ml (n = 3) rt-PA before and 30 +/- 5 ng/ml (n = 3) after 48 h preincubation in plasma (p less than 0.01), with corresponding values of 660 +/- 55 ng/ml (n = 3) and 280 +/- 25 ng/ml (n = 3) for rscu-PA, (p less than 0.01), and 800 +/- 85 ng/ml (n = 3) and 270 +/- 35 ng/ml (n = 3) for urokinase (p less than 0.01). Additional binding of plasminogen and increased sensitivity to lysis were reduced or abolished when the clot was preincubated in plasminogen-depleted or in t-PA-depleted plasma, or when 20 mM 6-aminohexanoic acid or 2,000 KIU/ml aprotinin were added.(ABSTRACT TRUNCATED AT 250 WORDS)     

Short-term high-dose effect of lovastatin on thrombolysis by rt-PA in a human whole-blood in vitro clot model

High-dose hydroxymethylglutaryl coenzyme. A reductase inhibitor (statin) administration reduces neuronal injury and improves outcomes in experimental models of acute ischemic stroke, and has been shown to be safe in a phase 1 dose-escalation study using lovastatin at doses higher than currently approved for daily use. Statins also affect the hemostatic system by upregulating t-PA expression and decreasing plasminogen activator inhibitor (PAI-1) expression, platelet adhesion and thrombus formation in animal models. Since a thrombolytic agent, recombinant tissue plasminogen activator (rt-PA), is currently the only FDA-approved therapy for use in ischemic stroke patients, it is important to ascertain whether high statin doses impact the efficacy of rt-PA. The main goal of this study was to evaluate the effect of a high dose of lovastatin and its active form, lovastatin hydroxy acid, on rt-PA thrombolysis in an in vitro model. Percentage clot lysis was measured in the presence and absence of rt-PA in three different treatment groups: lovastatin, lovastatin hydroxy acid, and ethanol. The effect of ethanol on clot lysis was studied since ethanol was used to disperse the highly hydrophobic lovastatin. The decrease in clot width over time was measured using microscopic imaging of an in vitro human whole blood clot model; an approximately 400 μm diameter clot was formed on suture silk, suspended in human fresh frozen plasma (hFFP) and exposed to treatment. In the absence of rt-PA, clot lysis did not show statistically significant differences in the percentage clot lysis between different treatment groups (p=0.103). In the presence of rt-PA, clot lysis was greater than in the absence of rt-PA for all groups, but there were no statistically significant differences between treatment groups (p=0.385). In this in vitro study, high doses of lovastatin neither impaired nor enhanced the lytic efficacy of rt-PA.     

Studies on the influence of reactants and buffer environment on clot lysis induced by human plasminogen activators

Clot lysis induced by tissue plasminogen activator and urokinase has been studied and the influences of pH, ionic environment and reactant concentrations have been determined. Both pH and ionic strength strongly affect the rate of clot lysis and distinctly different dependency profiles are obtained for tissue plasminogen activator and urokinase. Variations in concentration of plasminogen also profoundly affect the rate of clot lysis, maxima being obtained at different plasminogen concentrations depending on the concentration of fibrinogen. For urokinase, these maxima occurred at about a tenfold higher concentration of plasminogen than for the tissue plasminogen activator. The lysis times are directly dependent on the concentration of fibrinogen. Variation in thrombin concentration did not significantly affect the lysis times. Suitable conditions for the assays of tissue plasminogen activator and urokinase are suggested.     

Tissue plasminogen activator: Comparison of dose and route of administration in a rabbit model of thromboembolic stroke

Abstract

The thrombolytic activity of tissue plasminogen activator was evaluated in a rabbit model of thromboembolic stroke using both various concentrations (3, 5, and 10 mg/kg; 20% bolus with the remaining 80% given over 30 min.) and routes of administration (intravenous versus regional intra-arterial). An autologous tin-tagged clot was embolized to the brain via the carotid artery. Tissue plasminogen activator was then given at the doses and routes noted (n = 3 in all groups). Thrombolytic activity was followed by serial x-rays of the tin-laden clot over a four-hour period. The brains were then removed and subjected to gross inspection. Only the intravenous dose of 5 mg/kg tissue plasminogen activator produced greater than 50% clot lysis in all animals. Doses of t-PA higher (10 mg/kg) or lower (3 mg/kg) than this were less effective in producing thrombolysis, demonstrating greater than 50% clot lysis in only one animal of each group. We conclude that in this model of thromboembolic stroke the intravenous administration of tissue plasminogen activator is more effective than intra-arterialand that the optimal dose is in the range of 5 mg/kg. [Neurol Res 1993; 15: 405-408]     

Biochemical and biological properties of a recombinant tissue-type plasminogen activator derived from the rat JMI-229 cell line.

Recombinant tissue-type plasminogen activator (rt-PA), produced by expression of the genomic t-PA DNA from the JMI-229 cell line, which is of rat origin, in the host cell line, was purified to homogeneity. JMI-229 rt-PA was obtained essentially as a single chain molecule which was quantitatively converted to a two-chain moiety by treatment with plasmin. The plasminogen activating potential of single chain JMI-229 rt-PA was 5-fold lower than that of commercially available human rt-PA (Actilyse) in the absence of fibrin, but comparable in the presence of fibrin; it showed a concentration-dependent binding to fibrin, with a significantly more pronounced binding than Actilyse at low fibrin concentration (85 +/- 8% versus 20 +/- 7% at 0.025 mg/ml fibrin; p = 0.004). In human plasma in the absence of fibrin, the concentrations of both single chain and two-chain JMI-229 rt-PA required to induce 50% fibrinogen degradation in 2 h, were about 15-fold higher than those of Actilyse. Both single chain and two-chain forms of JMI-229 rt-PA and of Actilyse induced a similar time- and concentration-dependent lysis of a 125I-fibrin-labeled plasma clot immersed in human plasma, in the absence of significant systemic fibrinolytic activation. Equally effective concentrations (causing 50% clot lysis in 2 h) were 0.11 or 0.10 micrograms/ml for single chain or two-chain JMI-229 rt-PA, as compared to 0.11 or 0.15 micrograms/ml for single chain or two-chain Actilyse.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative study of the efficacy and specificity of tissue plasminogen activator and pro-urokinase: demonstration of synergism and of different thresholds of non-selectivity

Clot lysis and non-specific plasminogen activation in human plasma by tissue tissue plasminogen activator (t-PA) and/or pro-urokinase (pro-UK) were studied. The fibrinolytic activity of pro-UK was expressed as latent units, i.e. measured after activation with plasmin on a fibrin plate against the reference standard. The t-PA unitage was assigned on a weight basis of a similar equivalence of 100,000 IU/mg. To simplify comparison, both activators were expressed in IU (1 IU = −10 ng). At low concentration (1–50 IU/ml), t-PA induced more effective and more linear clot lysis, whereas pro-UK induced lysis was preceded by a lag phase. The two activators were equivalently effective at higher concentrations and saturated at the same lysis rate. Clots made from platelet rich plasma or whole blood were more responsive to lysis by pro-UK but not t-PA than corresponding platelet poor clots. At very low concentrations (2.5–5 IU/ml) of t-PA combined with moderate concentrations (25–50 IU/ml) of pro-UK, a synergistic effect on clot lysis, which was fibrin-specific, was observed. Plasminogen and fibrinogen and the appearance of plasmin-inhibitor complexes in plasma were measured after incubation with either activator with and without a clot present. Non-specific plasminogen activation occurred above a certain concentration of either activator but was found at lower concentrations of t-PA than pro-UK. In the absence of a clot, plasmin generation occurred with t-PA at about 30% of the concentration at which pro-UK induced a corresponding effect. It is concluded that there are important differences in the fibrinolytic and clot selective properties of t-PA and pro-UK, and that some of these properties may be complementary resulting in a fibrin specific, synergistic fibrinolytic effect.     

Direct microscopic monitoring of initial and dynamic clot lysis using plasmin or rt-PA in an in vitro flow system

Introduction

Plasmin is a direct-acting thrombolytic agent with a favorable safety profile upon intra-arterial delivery in pre-clinical and phase I studies. However, the thrombolytic efficacy of plasmin, relative to that of rt-PA, remains to be established. We have compared the dynamics of clot lysis with plasmin or rt-PA in an in vitro perfusion system, in which thrombolytic agent is administered locally, allowed to induce lysis for short intervals, then washed with plasma in a re-circulation circuit.

Materials and Methods

Whole blood human clots were prepared in observation chambers, exposed to plasmin or rt-PA at equimolar concentrations (1.2/1.0, 1.8/1.5 and 2.4/2.0 mg/ml) for measured intervals of time, followed by perfusion with human plasma. Clot size was monitored by digital analysis of sequential photographs obtained through an optical microscope.

Results

Plasma perfusion after incubation with thrombolytic agent rapidly removed superficial clot fragments. This initial decrease in clot size was greater with plasmin than with rt-PA when tested at the highest concentrations of agent (0.63 ± 0.11 vs. 0.30 ± 0.11, p = 0.001 for clots with non-cross-linked fibrin and 0.53 ± 0.15 vs. 0.14 ± 0.15, p = 0.02, for clots with cross-linked-fibrin). Subsequent clot lysis during plasma flow was greater after prior incubation with rt-PA. Longer incubation times of plasmin resulted in larger portions of the clot being washed free. Repeated plasmin incubations and plasma perfusions of a clot successfully induced stepwise reductions in clot size.

Conclusions

Initial clot lysis is greater with direct exposure using plasmin than rt-PA. During washout and circulation with plasma, rt-PA induced continued clot lysis, while plasmin lysis was curtailed, presumably because of plasmin inhibition.     

Biochemical, thrombolytic and pharmacokinetic properties of rt-PA P47G, K49N, a substitution variant of human tissue-type plasminogen activator.

rt-PA P47G, K49N, a substitution variant of recombinant human tissue-type plasminogen activator (rt-PA), in which proline at position 47 and lysine at position 49 were replaced by glycine and asparagine respectively, was previously described by Ahern et al. (J Biol Chem 1990; 265:5540-5) to have an extended in vivo half-life with unaltered in vitro fibrinolytic properties. Because this variant might possess an increased in vivo thrombolytic potency, we have constructed its cDNA, expressed it in Chinese hamster ovary cells and determined its biochemical, thrombolytic and pharmacokinetic properties relative to those of home-made rt-PA and of alteplase (Actilyse). The specific fibrinolytic activities on fibrin plates were 160,000 +/- 17,000, 210,000 +/- 88,000 and 460,000 +/- 72,000 IU/mg (mean +/- SEM) for rt-PA P47G, K49N, rt-PA and alteplase, respectively, while the catalytic efficiencies for plasminogen activation (k2/Km) in the absence of fibrin were comparable (1.1 to 1.7 x 10(-3) microM-1s-1). Fibrin enhanced the rate of plasminogen activation by rt-PA P47G, K49N 100-fold and by both wild-type molecules 390-fold. Binding of the variant rt-PA to fibrin was significantly reduced, but its affinity for lysine-Sepharose was unaltered. In an in vitro clot lysis system, consisting of a radiolabeled human plasma clot submersed in plasma, 50% clot lysis in 2 h required 0.67 +/- 0.14 micrograms/ml rt-PA P47G, K49N, 0.36 +/- 0.01 micrograms/ml rt-PA and 0.17 +/- 0.01 micrograms/ml alteplase, respectively (mean +/- SEM; n = 3 or 4). At these doses residual fibrinogen levels at 2 h were in excess of 80%.(ABSTRACT TRUNCATED AT 250 WORDS)     

Relationship between tissue plasminogen activator and the activators in blood and vascular wall

To explore the relation between tissue plasminogen activator and both vascular and blood fibrinolytic activity, an antiserum against a tissue plasminogen activator, recently purified from human uterus, was used. By measuring the extent of quenching of fibrinolytic activities by the IgG fraction of this antiserum immunological relationship with tissue plasminogen activator was established. Thus, the plasminogen activator activity in the vascular wall, responsible for the lysis in Todd's fibrin slide technique and released by perfusion of a cadaver limb was completely identified as tissue plasminogen activator activity. In addition, a part of the fibrinolytic activity of blood which was notably enhanced after venous occlusion or physical exercise was attributed to tissue plasminogen activator related activity. The intrinsic activators/proactivators in blood were found to be immunologically unrelated to tissue plasminogen activator. By immunoadsorption chromatography tissue plasminogen activator related activator was isolated from venous occlusion plasma. Comparison with the uterine tissue plasminogen activator showed that both activators had similar immunological properties, temperature stabilities, and molecular weights on dodecylsulphate polyacrylamide gel electrophoresis besides a small difference on gel filtration. These close similarities support the hypothesis that plasminogen activator is synthesized in the vascular wall and released into the circulating blood.     

Whole blood clot lysis: In vitro modulation by activated protein C

Lysis of clots prepared from native or citrated whole blood as measured by release of ¹²⁵I fibrinogen degradation products was 10% or less at 20 hours. Lysis of these clots was accelerated by activated protein C in a dose-dependent manner (0.1 to 20 μg/ml) from less than 10% to 60–80% at 20 hours. Lysis of clots prepared from native or citrated platelet poor plasma across the same concentration range of activated protein C was less than 15%. Gla-domainless activated protein C was equally effective in accelerating clot lysis whereas DIP-activated protein C or factor Xa did not accelerate clot lysis. This suggested that this action of activated protein C was enzymatic and this this action was limited to protein C among the vitamin K dependent proteins.The unresponsiveness of platelet poor plasma to activated protein C was completely restored to that of whole blood by addition of mononuclear leukocytes. Addition of red corpuscles or platelets $\text{alone}$ had no effect on this response, while addition of polymorphonuclear leukocytes partially restored this response. Addition of metabolic inhibitors 2-deoxyglucose and oligomycin inhibited the response of whole blood and of plasma-mononuclear leukocytes to activated protein C. Reconstitution studies of platelet poor plasma made deficient in plasminogen activator and plasminogen showed that accelerated clot lysis produced by mononuclear leukocytes and activated protein C required the presence of plasminogen. We concluded, therefore, that activated protein C accelerates whole blood or plasma-leukoycte clot lysis by modulating activation of the plasminogen system by metabolically active leukocytes.     

Role of alpha 2-antiplasmin in fibrin-specific clot lysis with single-chain urokinase-type plasminogen activator in human plasma

The role of plasma alpha 2-antiplasmin (alpha 2-AP) in the fibrin-specificity of clot lysis by recombinant single-chain urokinase-type plasminogen activator (rscu-PA) and in the conversion of rscu-PA to its two-chain derivative (rtcu-PA, urokinase) was investigated in an in vitro human plasma clot lysis system. Fifty % lysis in 2 h of a 0.1 ml 125I-fibrin labeled human plasma clot immersed in 0.5 ml normal human plasma was obtained with 1.4 +/- 0.15 micrograms/ml rscu-PA (mean +/- SD, n = 8). This was associated with degradation of 23 +/- 7% of fibrinogen and generation of 0.20 +/- 0.09 micrograms/ml rtcu-PA. In alpha 2-AP-depleted plasma 50% clot lysis in 2 h required 2-fold less rscu-PA which was associated with 3-fold more extensive fibrinogen degradation and 2-fold more rtcu-PA generation. Fifty % lysis in 2 h, of a 0.1 ml alpha 2-AP-depleted plasma clot, submersed in 0.5 ml normal plasma, was obtained with 0.80 +/- 0.05 micrograms/ml rscu-PA (n = 3, p less than 0.001 vs normal clot) and was associated with 17 +/- 6% fibrinogen breakdown (p = 0.22 vs normal clot) and 0.08 +/- 0.02 micrograms/ml rtcu-PA generation (p less than 0.05 vs normal clot). In alpha 2-AP-depleted plasma the equipotent rscu-PA concentration was 4-fold lower than in normal plasma and was associated with 3-fold more fibrinogen degradation and a similar extent of rtcu-PA generation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Rt-PA causes a significant increase in endogenous u-PA during experimental focal cerebral ischemia

The aim of this study was to investigate the effects of different doses of exogenous recombinant human tissue plasminogen activator (rt-PA) on the endogenous cerebral plasminogen-plasmin system in focal ischemia in rats. Ischemia was induced using the suture model. Each group of rats (n = 6) received either treatment (0.9, 9 or 18 mg rt-PA/kg body weight) or saline (control group) at the end of ischemia; a sham-operated group was added. The activity of the plasminogen activators was measured by casein-dependent plasminogen zymography. In the cortex urokinase (u-PA) rose from sham (no ischemia), 91 +/- 7% to ischemia, 176 +/- 10% (P < 0.005). Increasing rt-PA doses led to further significant (P < 0.001) cortical u-PA activation which was maximal at 18 mg: 249 +/- 13%. An extreme increase in the u-PA activity was observed in the basal ganglia to 1019 +/- 22% (P < 0.001). This increase was further aggravated by higher rt-PA doses (18 mg, 1236 +/- 15%; P < 0.001). The t-PA level did not change I3R24 during (3 h ischemia followed by reperfusion for 24 h); however, during low and moderate doses of rt-PA, endogenous t-PA was reduced. In conclusion, while ischemia leads to a significant increase in u-PA, mainly in the basal ganglia, t-PA is not altered. Increasing doses of rt-PA lead to a further elevation of u-PA. Thus, u-PA seems to play a major role in the endogenous plasminogen activator system following focal cerebral ischemia.     

Influence of intrinsic and extrinsic plasminogen upon the lysis of thrombi in vitro.

When the rate of lysis of artificial thrombi (prepared from plasma or whole blood) was expressed according to the concentration of tissue type plasminogen activator (t-PA) or single chain urokinase type plasminogen activator (sc-uPA) then bell-shaped dose response curves were obtained, low rates being observed at concentrations of activator greater than 500 units/ml. Bell-shaped dose response curves were not observed for rate of lysis of artificial thrombi over the concentrations of streptokinase tested (SK) or for the lysis of plasma gel clots by any of the activators tested. Further investigation indicated that the preponderant mechanism for dissolution of thrombi at 500 units/ml of t-PA was by activation of the plasminogen within the thrombus (intrinsic) since the plasminogen present in the plasma perfusing the thrombus (extrinsic) rapidly became depleted. On the other hand, at 50 units/ml t-PA the lysis was observed to be due preponderantly to the action of plasmin arising from extrinsic rather than intrinsic plasminogen. If "plasminogen enriched" thrombi were prepared in the presence of Lys plasminogen (Lys-Plg) faster rates of lysis occurred and bell-shaped biometric curves were not observed.     

Comparison of affinities of urokinase and tissue plasminogen activator for fibrin clots

Affinities of low molecular weight two-chain urokinase (UK) and tissue plasminogen activator (t-PA) for fibrin clots were investigated by using clot lysis rates to estimate an affinity (Kd) between activator and fibrin clots. Lysis rates were obtained using a simple spectrophotometric based clot lysis assay which is described here. Fibrin clots, containing residual plasminogen, were suspended in a 1 ml cuvette and the increase in absorbance at 280 nm due to release of soluble fibrin peptides measured over a 150 to 250 minute time period. Lysis rates were obtained from plots of time squared vs absorbance change. Plots of activator concentration vs reciprocal rates yielded regression coefficients of 0.999 and Kd values of nM for the affinity of both activators for fibrin clots. Although both activators are known to differ in affinity for fibrin, they nonetheless had similar affinities and lysis rates for the insoluble fibrin clots. This assay also suggested possible synergism; rates over twice that expected by an additive effect were observed when the two activators were mixed at 0.3 to 7.6 nM each.     

Turbulent axially directed flow of plasma containing rt-PA promotes thrombolysis of non-occlusive whole blood clots in vitro

The rate of thrombolysis markedly decreases after a thrombosed vessel is partly recanalized and the remaining clot poses serious risk for rethrombosis. We studied in vitro how thrombolysis depends on penetration of plasma containing thrombolytic agents - 0.2 micro g/ml rt-PA or 250 IU/ml streptokinase (SK) - and the magnetic resonance contrast agent Gd-DTPA (at 1 mmol/l) into non-occlusive clots under conditions of fast (turbulent) or slow (laminar) axially directed flow. Cylindrical non-retracted (fresh) or retracted (aged) whole blood clots were pierced lengthways and connected to a perfusion system. Dynamical spin-echo MRI was used for measuring the penetration of labeled plasma into clots and for assessing the remaining clot size. In both types of clots fast flow enhanced the penetration of Gd-DTPA-labeled plasma into clots in comparison to slow flow. In non-retracted clots, lysis with rt-PA and to a lesser extent also lysis with SK followed the path of plasma penetration into clots. After 40 minutes of fast axially directed flow rt-PA resulted in almost complete lysis and SK left only about a third of the clot undissolved, whereas with slow flow lysis was much slower (undissolved clot: 86 +/- 5 % with rt-PA and 95 +/- 1 % with SK). In retracted clots, substantial lysis was possible only with rt-PA and rapid flow (53 +/- 28% of the clot undissolved after 60 min), whereas the use of SK or slow flow precluded meaningful lysis. We conclude that rapid (turbulent) axially directed flow of plasma along non-occlusive blood clots causes forceful exchange of serum inside the clot with outer plasma which enhances both fibrin-specific and non-fibrin-specific lysis of fresh clots. Dissolution of non-occlusive retracted (aged) clots occurs only under fibrin-specific conditions combined with adequate transport of rt-PA into clots.     

Biological and thrombolytic properties of proenzyme and active forms of human urokinase--IV. Variability in fibrinolytic response of plasma of several mammalian species

The fibrinolytic and fibrinogenolytic properties of recombinant pro-urokinase (Rec-pro-UK) and recombinant urokinase (Rec-UK) were compared with those of natural urokinase (Nat-UK) and of tissue-type plasminogen activator (t-PA) in an in vitro system consisting of 125I-labeled autologous plasma clots immersed in plasma of humans, five primate species, dogs, rabbits and pigs. With each of the four plasminogen activators, a dose-dependent clot lysis was observed, the degree of which differed, however, very markedly from one species to the other. At a concentration of 100 IU/ml of urokinase extensive plasma clot lysis was obtained in plasma of man, Macaca mulatta, Macaca fascicularis and Macaca radiata, while the plasma clots of Papio cynocephalus, Papio anubis and rabbit, dog and pig were much more resistant to lysis. No significant differences in the extent of lysis were observed between Rec-pro-UK and Rec-UK nor between Rec-UK and Nat-UK. Comparable degrees of lysis were obtained with t-PA at 3- to 5-fold lower concentrations. Lysis with Rec-UK or Nat-UK was always associated with extensive activation of the fibrinolytic system in plasma, evidenced by fibrinogen breakdown and plasminogen activation and alpha 2-antiplasmin consumption. With t-PA, extensive clot lysis was obtained in the absence of fibrinolytic activation in the plasma. With Rec-pro-UK the response was intermediate; at high concentrations (200 IU/ml) extensive lysis in the reactive species was associated with fibrinogen consumption, while at intermediate concentrations (50-100 IU/ml) significant clot lysis was obtained in the reactive species in the absence of marked activation of the fibrinolytic system in the plasma.