Dependence of blood clot lysis on the mode of transport of urokinase into the clot--a magnetic resonance imaging study in vitro

Magnetic resonance imaging was employed to study the dependence of clot lysing patterns on two different modes of transport of urokinase into whole blood clots. In one group of clots (nonperfused clots, n1 = 10), access of urokinase to the fibrin network was possible by diffusion only, whereas in the other group (perfused clots, n2 = 10) bulk flow of plasma containing urokinase was instituted through occlusive clots by a pressure difference of 3.7 kPa (37 cm H2O) across 3 cm long clots with a diameter of 4 mm. It was determined separately that this pressure difference resulted in a volume flow rate of 5.05 +/- 2.4 x 10(-2) ml/min through occlusive clots. Perfused clots diminished in size significantly in comparison to nonperfused ones already after 20 min (p less than 0.005). Linear regression analysis of two-dimensional clot sizes measured by MRI showed that the rate of lysis was more than 50-times faster in the perfused group in comparison to the nonperfused group. It was concluded that penetration of the thrombolytic agent into clots by perfusion is much more effective than by diffusion. Our results might have some implications for understanding the differences in lysis of arterial and venous thrombi.     

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.     

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)     

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)     

A focal embolic model of cerebral ischemia in rats: introduction and evaluation

Cerebral thromboembolism is the most common type of acute stroke in the clinical setting. In the present study, we have described a focal embolic model of cerebral ischemia in rat. Cerebral ischemic injury in two different sizes was induced by injection of two different volumes of pre-formed clots into the middle cerebral artery (MCA). Neurological deficits were assessed at 1 and 24 h, respectively, after the MCA embolization. The brain infarction was evaluated with 2,3,5-triphenyltetrazolium chloride (TTC) staining at 72 h following embolic stroke. The incidence of gross hemorrhage was also identified on the TTC-stained brain sections. This study consisted of two groups. In the first group 10 microl of pre-formed clot was injected into MCA (n=10), and in the second group 5 microl of clot was injected (n=10). Embolizing a pre-formed clot resulted in an infarction in the territory irrigated by the MCA. Embolization with the different volume of clots resulted in different sizes of brain infarction, 32.1+/-2.9% (mean+/-S.E.) in the 10-microl group versus 23+/-4.5% (mean+/-S.E.) in the 5-microl group (P<0.05). The infarction size as well as neurological deficits correlated well with the volume of the clot injected. These results thus show that with the procedure described here a reliable and reproducible ischemic injury is produced in the brain. The model is relevant to thromboembolic ischemia in patients, and may offer a useful tool to investigate mechanisms underlying ischemic brain injury. It may also be used to test thrombolytic agents in ischemic brain injury.     

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)     

Comparative fibrinolytic properties of staphylokinase and streptokinase in animal models of venous thrombosis.

The thrombolytic and pharmacokinetic properties of staphylokinase were compared with those of streptokinase in hamsters with a pulmonary embolus produced from human plasma or from hamster plasma, and in rabbits with a jugular vein blood clot produced from rabbit blood. In both models, a continuous intravenous infusion of staphylokinase and streptokinase over 60 min in hamsters or over 4 h in rabbits, induced dose-dependent progressive clot lysis in the absence of significant systemic activation of the fibrinolytic system. The results of thrombolytic potency (clot lysis at 30 min after the end of the infusion, in percent, versus dose administered, in mg/kg) were fitted with an exponentially transformed sigmoidal function (formula: see text) and the maximal percent clot lysis (c), the maximal rate of lysis (z = 1/4 ac.eb) and the dose at which the maximal rate of lysis is achieved (b) were determined. In hamsters with a pulmonary embolus produced from human plasma, streptokinase had a somewhat higher thrombolytic potency than staphylokinase, as revealed by a higher z value (2,100 +/- 1,100% lysis per mg/kg streptokinase administered versus 1,100 +/- 330% lysis per mg/kg for staphylokinase). In hamsters with a pulmonary embolus produced from hamster plasma, staphylokinase had a somewhat higher thrombolytic potency than streptokinase (z = 1,600 +/- 440 versus 1,200 +/- 370% lysis per mg/kg). Staphylokinase had a higher thrombolytic potency than streptokinase in rabbits,as revealed by a higher z-value (950 +/- 350% lysis per mg/kg staphylokinase administered versus 330 +/- 39% lysis per mg/kg for streptokinase) and a lower b-value (0.035 +/- 0.010 mg/kg staphylokinase versus 0.091 +/- 0.008 mg/kg for streptokinase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thrombolytic properties of leukocytes from peripheral blood in healthy subjects and in patients with acute cerebral ischemia

Polymorphonuclear leukocytes are activated in acute ischemic stroke. Activated polymorphonuclear leukocytes may contribute to thrombolysis by proteolytic degradation of fibrin and by modification of the plasminogen system. We used an in vitro thrombolysis model to investigate (1) thrombolytic properties of leukocytes in young and healthy subjects, (2) to test the hypothesis of increased polymorphonuclear leukocyte-associated thrombolysis in patients with acute cerebral ischemia, and (3) to assess plasminogen-dependent and -independent thrombolytic properties of polymorphonuclear leukocyte elastase. Coincubation of polymorphonuclear leukocytes with fibrin clots led to increased thrombolysis, a process reaching statistical significance after 8 hours [1x10(7) polymorphonuclear leukocytes/mL; 12.8+/-1.9% (mean+/-SEM), spontaneous clot lysis: 7.3+/-0.7%]. Polymorphonuclear leukocytes inside clots caused more efficient thrombolysis than polymorphonuclear leukocytes in the incubation medium. Spontaneous and polymorphonuclear leukocyte-associated lysis tended to be lower in patients with acute cerebral ischemia (n=9, 24 hours, 9.5+/-1.8% and 12.9+/-2.2%) than in age- and sex-matched control subjects (n=8; 12.2+/-2.0% and 17.4+/-1.9%). In the presence of alpha(2)-antiplasmin, thrombolysis tended to be faster with elastase-digested plasminogen (miniplasminogen) than with native plasminogen. Purified polymorphonuclear leukocyte elastase itself had no thrombolytic effect. We conclude that the thrombolytic capacity of polymorphonuclear leukocytes from peripheral blood is small and slow and may have been overestimated in previous reports. Polymorphonuclear leukocyte thrombolytic activity may not be increased in acute cerebral ischemia. Miniplasminogen may be an interesting adjunct to plasminogen activators in acute stroke models.     

Tissue-type plasminogen activator (t-PA) and dilute blood clot lysis time in nephrotic patients

When compared to normal weight normolipidemic control subjects, dilute blood clot lysis time was found to be obviously (p less than 0.001) prolonged in hypertriglyceridemic patients without proteinuria and slightly (p less than 0.05) accelerated in hyperlipidemic nephrotic patients in spite of their very high levels of plasma fibrinogen. As a result the ratio plasma fibrinogen (mg/dl) per clot lysis time (minutes) was 1.241 +/- 0.08 (X +/- SEM) in control subjects, 0.574 +/- 0.07 in hypertriglyceridemic patients and 2.69 +/- 0.172 in nephrotic patients. This finding suggesting that a larger amount of fibrin is rather readily dispersed from dilute blood clots of nephrotic patients was associated with higher levels of plasma t-PA:Ag (9.45 ng/ml +/- 1.18 in nephrotic patients versus 5.8 ng/ml +/- 1.23 in controls before venous occlusion and respectively 33.1 ng/ml +/- 3.83 versus 20.3 +/- 3.40 in controls after venous occlusion). Plasminogen activator activity of the euglobulins as assessed by the bovine fibrin-agarose plate was significantly higher in nephrotic patients only after venous occlusion. Plasma samples of nephrotic patients exerted a more potent inhibition of fibrinolysis in a urokinase activated system. This effect was, however, mainly due to the high levels of alpha 2 macroglobulin in nephrotic plasma which apparently have little influence on dilute blood clot lysis time.     

The effect of vasodilators on aspirin-induced antagonism of t-PA thrombolysis.

Although i.v. t-PA has proven successful in reducing neurologic deficits in acute ischemic stroke, the disadvantages of a narrow therapeutic time window and the failure of thrombolysis in more than 50% of patients treated have necessitated an examination of adjuvant therapies to improve the rate of thrombolysis. Experimentally, the combination of aspirin therapy with t-PA has resulted in a paradoxical antagonism of thrombolysis. Reversal of this antagonism with nitric oxide (NO) donors suggested that aspirin may inhibit/ antagonize NO-related mechanisms. Using this rabbit model of thromboembolic stroke, this hypothesis is now expanded to compare two clinically relevant anti-hypertensive agents, atenolol (NO-dependent) and hydralazine (NO-independent), for their ability to improve t-PA-mediated clot lysis following aspirin pre-treatment. Thirty rabbits (10 per group) were pre-treated with aspirin (20mg kg(-1), i.v.) and then randomized to receive either vehicle, atenolol (20 microg kg(-1) h(-1), i.v.) or hydralazine (10 microg kg(-1) min(-1), i.v.) beginning 30 min following autologous clot embolization. All rabbits then received t-PA (6.3 mg kg(-1), i.v.) beginning 1 h after embolization, with completion of the protocol 4 h after embolization. Aspirin therapy reduced regional cerebral blood flow (rCBF) from 82.8m +/- 4.7 to 62.5 +/- 6.6 (n = 30; p = 0.0005). In the aspirin control group only 30% (3 of 10) rabbits demonstrated complete clot lysis, whereas the combined atenolol (60%) and hydralazine (70%) groups experienced a clot lysis rate of 65% (13 of 20 rabbits), similar to clot lysis rates previously observed with t-PA alone. In a separate series of experiments, all agents able to reverse aspirin antagonism of thrombolysis demonstrated an improvement in rCBF, suggesting a common mechanism for this diverse group of agents in reversing aspirin's antagonism of thrombolysis.     

Ultrasound affects distribution of plasminogen and tissue-type plasminogen activator in whole blood clots in vitro

Ultrasound of 2 MHz frequency and 1.2 W/cm(2) acoustic intensity was applied to examine the effect of sonication on recombinant tissue-type plasminogen activator (rt-PA)-induced thrombolysis as well as on the distribution of plasminogen and t-PA within whole blood clots in vitro. Thrombolysis was evaluated quantitatively by measuring clot weight reduction and the level of fibrin degradation product D-dimer (FDP-DD) in the supernatant. Weight reduction in the group of clots treated both with ultrasound and rt-PA was 35.2% +/-6.9% which is significantly higher (p<0.0001) than in the group of clots treated with rt-PA only (19.9% +/-4.3%). FDP-DD level in the supernatants of the group treated with ultrasound and rt-PA increased sevenfold compared to the group treated with rt-PA alone, (14895 +/-2513 ng/ml vs. 2364 +/-725 ng/ml). Localization of fibrinolytic components within the clots was accomplished by using gel-entrapping technique and immunohistochemistry. Spatial distributions of t-PA and plasminogen showed clearly that ultrasound promoted the penetration of rt-PA into thrombi significantly (p<0.0001), and broadened the zone of lysis from 8.9 +/-2.6 microm to 21.2 +/-7.2 microm. We speculate that ultrasound enhances thrombolysis by affecting the distribution of rt-PA within the clot.     

Thrombolytic and pharmacokinetic properties of human tissue-type plasminogen activator variants, obtained by deletion and/or duplication of structural/functional domains, in a hamster pulmonary embolism model

A pulmonary embolism model in hamsters was used for the quantitative evaluation of the thrombolytic and pharmacokinetic properties of variants of tissue-type plasminogen activator (t-PA). A 25 microliters 125I-fibrin labeled human plasma clot was made in vitro and injected into the jugular vein of heparinized hamsters. The extent of thrombolysis within 90 min was determined as the difference between the radioactivity injected in the jugular vein and that recovered in the heart and lungs. Recombinant t-PA (home-made rt-PA or Activase) infused intravenously over 60 min caused dose-dependent progressive thrombolysis. The results of thrombolytic potency (clot lysis in percent versus dose administered in mg/kg) and of specific thrombolytic activity (clot lysis in percent versus steady state plasma level in microgram/ml) were fitted with an exponentially transformed sigmoidal function y = 100 c/(1 + e-a(ax-eh] and the maximal percent lysis (c), the dose or plasma level at which maximal rate of lysis is achieved (b) and the maximal rate of lysis (z = 1/4 ac.eb) were determined. With rt-PA, these parameters were c = 72 +/- 6% (mean +/- SEM), b = 0.19 +/- 0.08 mg/kg, z = 68 +/- 25% lysis per mg/kg, with corresponding values of 87 +/- 5%, 0.07 +/- 0.03 mg/kg and 150 +/- 38% lysis per mg/kg for Activase (p = NS). Deletion of the finger and growth factor domains in rt-PA (rt-PA-delta FE) was not associated with marked alteration of the thrombolytic potency (c = 90 +/- 30%, b = 0.34 +/- 0.35 mg/kg, and z = 54 +/- 14% per mg/kg), but was associated with a significant reduction of the specific thrombolytic activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of pulmonary emboli ex vivo by magnetic resonance imaging and ultrasound

INTRODUCTION: Magnetic resonance imaging (MRI) and transesophageal ultrasound (US) are promising methods for detection and characterization of central pulmonary emboli. Both methods employ different physical principles. We tested how US and MRI characterized pulmonary emboli ex vivo. METHODS: Thirty six ex vivo pulmonary emboli, obtained during routine autopsies of patients who died of massive pulmonary embolism, were subjected to US imaging (linear vascular probe, 5.7-10 MHz) and to high resolution three-dimensional T1-weighted spin-echo MRI. In another 3 pulmonary thromboemboli and 2 tumor emboli, we compared MRI with immunohistochemistry to platelets, red blood cells and renal carcinoma cells. We also studied model clots in vitro (retracted and non-retracted red whole-blood clots, platelet aggregates and compacted and non compacted fibrin-rich plasma clots) with MRI and US. RESULTS: T1-weighted MR images of pulmonary thromboemboli consistently showed dark regions that corresponded to red cell-rich regions and bright layers that corresponded to platelet aggregates, but bright signal was obtained also from viable carcinoma cells and necrotic regions in tumor emboli. US images provided less structural detail than MRI, but clot retraction or compaction increased image brightness. The correlation between US and MRI characteristics of pulmonary emboli was poor. CONCLUSIONS: T1-weighted MRI of pulmonary emboli is capable of non-invasive assessment of the red cell-rich and platelet-rich components of pulmonary thromboemboli. US imaging shows increased brightness with clot retraction or compaction. Thus, both methods detect clot characteristics that influence susceptibility to thrombolytic treatment.     

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.     

Protraction of whole blood and plasma clot lysis in patients with high levels of an inhibitor of tissue-type plasminogen activator

The influence of the newly discovered, fast-acting inhibitor of tissue-type plasminogen activator (t-PA) on the lysis time of plasma clots was studied by visual observation of lysis of clotted citrated plasma after addition of purified t-PA. To a series of plasma samples with various concentrations of naturally occurring PA-inhibitor purified t-PA was added to a final concentration, which in pooled normal plasma is sufficient to induce clot lysis within a few hours. In those plasma samples with a high free inhibitor level, determined by measuring the recovery of the activity of added purified t-PA, clot lysis was retarded. Whole blood clots were made by clotting freshly collected non-anticoagulated blood with thrombin after admixture of a trace amount of radiolabeled fibrinogen and a fixed amount of t-PA. Lysis rate, read from the appearance of radioactivity in the serum after centrifugation, was significantly lower in clots obtained from subjects with a high free inhibitor level than in those with a low inhibitor level. It is concluded that the PA-inhibitor protracts clot lysis and may be relevant for physiological fibrinolysis.     

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)     

The effect of flow on lysis of plasma clots in a plasma environment

Fibrinolysis initially generates channels in an occluding thombus which results in blood flow through the thrombus. Since the impact of flow along the surface of a thrombus on thrombolysis has not been investigated in detail, we studied in vitro how such a flow affects lysis. Compacted and noncompacted plasma clots were used as model thrombi. With compacted clots, fibrin-specific lysis induced by alteplase in the outer plasma was accelerated about 2-fold by strong flow (arterial shear rate). Non-fibrin-specific lysis induced either by a high concentration of alteplase or by streptokinase was slow, was accompanied by rapid depletion of plasminogen in the outer plasma, and was only slightly accelerated by flow. With noncompacted clots, similar acceleration factors were documented, when mild flow (venous shear rate) was applied. Strong flow further accelerated fibrin-specific lysis, up to 10-fold as compared to lysis without flow, but paradoxically retarded non-fibrin-specific lysis. The data suggest that flow accelerates lysis by enhancing transport of plasminogen from the outer plasma to the surface of the clot. Both opposite effects of the strong flow were mediated by forceful intrusion of the outer plasma into the noncompacted clot due to flow irregularities. In the case of non-fibrin-specific lysis this resulted in the replacement of the plasminogen-containing milieu by plasminogen-depleted outer plasma in certain areas of the clot turning them into virtually unlysable fragments. This flow-enforced "plasminogen steal" may contribute to the relatively high percentage of incomplete thrombolysis (TIMI-2 grade flow) documented in a number of trials for non-fibrin-specific thrombolytic agents. In the case of fibrin-specific lysis, the effect of flow on the speed of fibrinolysis is always beneficial.     

Effects of recombinant plasminogen activator inhibitor type 1 on fibrinolysis in vitro and in vivo

A biologically active recombinant PAI-1 (rPAI-1) was evaluated for its effects on clot lysis in vitro and in vivo. At concentrations of 0.5 to 10 micrograms/ml, the rPAI-1 significantly prolonged the time to lysis of rabbit euglobulin clots both in the presence and absence of exogenous tissue plasminogen activator. To examine the effects of PAI in vivo, we infused rPAI-1 into conscious rabbits after i.v. injection of homogenized fibrin clots, and assessed fibrinolysis by measuring the appearance of d-dimer fibrin degradation products (FDP). Plasma fibrinolytic activity, PAI activity and antigen were also measured in plasma samples taken during and after infusion of rPAI-1. In control rabbits, endogenous fibrinolytic activity resulted in a significant and continual generation of FDP, reaching 32.6 +/- 13.6 ng/ml 90 minutes after fibrin injection. Infusion of 1, 2, or 5 micrograms/kg/min rPAI-1 led to dose dependent increases in PAI activity and antigen, while FDP levels at 90 minutes were only 8.8 +/- 2.9, 5.7 +/- 2.4, and 0.3 +/- 0.3 ng/ml, respectively. Complete inhibition of fibrinolysis was observed with 10 micrograms/kg/min rPAI-1. These studies directly demonstrate that increases in PAI-1 impair the fibrinolytic system, and support indirect observations of an association between elevated levels of this protein and thromboembolic diseases.     

Clot penetration and fibrin binding of amediplase,a chimeric plasminogen activator (K2 tu-PA)

Amediplase (K(2) tu-PA) is a hybrid plasminogen activator, consisting of the kringle 2 domain of alteplase and the protease domain of urokinase. The objective of this study was to determine the in vitro clot penetration of amediplase in relation to its fibrin binding and to compare the properties with those of alteplase. The clot lysis activity of amediplase in internal clot lysis models (both purified system and plasma system) was about 10 times less than that of alteplase. The clot lysis activity of amediplase in an external clot lysis model (plasma system) was similar to that of alteplase at therapeutic concentrations around 1 micro g/ml. The fibrin-clot binding properties of amediplase and alteplase were studied in a purified system as well as in a plasma system. In both systems amediplase bound to fibrin although to a significantly lower extent than alteplase. The binding of amediplase or alteplase did not increase during plasmin-mediated degradation of fibrin. The binding of amediplase was fully inhibited by epsilon-aminocaproic acid, indicating that the observed binding was specific and occurred via the lysine binding site in the kringle of amediplase. Clot penetration was studied during pressure-driven fluid permeation using syringes containing plasma clots. Amediplase was able to enter the clot without significant hindrance, while alteplase was concentrated on the top of the plasma clot and hardly entered into the inner parts of the clot. Diffusion-driven clot penetration was studied during clot lysis using confocal microscopy. Alteplase was detected on or close to the clot surface, while two-chain urokinase, which has no affinity to fibrin, was also detected deep inside the clot. Amediplase showed a penetration behaviour, which was distinct from that of alteplase and similar to that of two-chain urokinase. We concluded that the fibrin binding of amediplase is moderate and does not hinder clot penetration under permeation-driven or diffusion-driven transport conditions. Enhanced clot penetration, especially in large clots, could allow a more efficient lysis during thrombolytic therapy.