Limiting systemic plasminogenolysis reduces the bleeding potential for tissue-type plasminogen activators but not for streptokinase.

Clinical experience suggests that thrombolytic-induced bleeding is associated with systemic activation of the thrombolytic system. Using fibrin specific variants of tissue-type plasminogen activator (t-PA) and making use of the apparent fibrin specificity of streptokinase (SK) in the rabbit we tested the hypothesis that minimizing systemic plasmin production and fibrinogenolysis will decrease hemorrhages in models of peripheral bleeding and embolic stroke. t-PA consumed 51% of the available fibrinogen; caused cerebral bleeds and increased peripheral bleeding time. Fibrin-specific variants of t-PA depleted less than 20% of the fibrinogen and did not cause peripheral or cerebral bleeding. However, an equipotent dose of SK converted only 12% of the available fibrinogen but increased bleeding time and caused hemorrhagic conversion in 75% of embolic stroke model animals treated. The data suggest that bleeding associated with tissue-type plasminogen activators is linked to systemic plasmin generation and subsequent fibrinogenolysis. This hypothesis does not explain the mechanism(s) of SK-induced bleeding.

An experimental model of intracranial hemorrhage during thrombolytic therapy with t-PA.

Multiple clinical trials have proven that thrombolytic therapy is an effective treatment for acute myocardial infarction. Spontaneous intracranial hemorrhage (ICH) occurs in a small percentage of patients as a result of the treatment. The etiology of the ICH is unknown and there is currently no established experimental model for this side effect. A model of ICH during thrombolytic therapy has been developed using spontaneously hypertensive rats (SHR). The SHR were made susceptible to ICH during thrombolytic therapy by bilateral ligation of the external jugular veins. This procedure produced asymptomatic hemorrhagic lesions in the brains of the animals in the hours preceding the administration of t-PA/heparin. The incidence of ICH following the administration of test substances was assessed by histological examination and by measuring the red blood cell count in a sample of cerebrospinal fluid taken from the atlanto-occipital space. t-PA administration produced a low frequency of ICH in this model. The incidence and severity of ICH were dramatically increased, and significant mortality at 24h was observed, by combining heparin were administered sequentially rather than simultaneously. Furthermore, ICHs were observed whether the t-PA dose was administered over 4 h, 1 h, or as a double bolus 30 min apart. The potentiation of ICH by heparin was dose dependent and proportional to the prolongation of the aPTT. Although the precise mechanism of ICH during thrombolytic therapy is unknown, many similarities exist between the observations made in this model and in the human clinical experience.

A long-half-life and fibrin-specific form of tissue plasminogen activator in rabbit models of embolic stroke and peripheral bleeding.

BACKGROUND AND PURPOSE: We compared the activity of a new long-half-life, fibrin-specific tissue-type plasminogen activator (TPA) variant with that of wild-type TPA in rabbit models of embolic stroke and peripheral bleeding. METHODS: In the embolic stroke model. TPA-induced clot lysis is followed by continuous monitoring of a radiolabeled clot lodged in the middle cerebral artery. Twenty-four hours after embolization and treatment with either thrombolytic agent or excipient, the brains are removed, fixed, and evaluated for cerebral hemorrhage. In a parallel template bleeding time experiment, the effects of equipotent doses of the two TPA molecules were measured. RESULTS: Infusion of wild-type TPA or bolus administration of the TPA variant resulted in dose-dependent clot lysis. The TPA variant was found to be an order of magnitude more potent than wild-type TPA on a milligram-per-kilogram basis. Unlike wild-type TPA, the variant caused less systemic activation of plasminogen (P < .05) and fewer hemorrhagic transformations in this model (P < .05). The TPA variant did not extend template bleeding times. CONCLUSIONS: These findings show that by combining increased fibrin specificity with decreased plasma clearance, it is possible to produce a thrombolytic agent that is more convenient and more potent than wild-tpe TPA. At the same time the significant reduction in hemorrhagic conversions may be attributable to the conservation of systemic plasminogen seen with this molecule.

A variant of t-PA (T103N, KHRR 296-299 AAAA) that, by bolus, has increased potency and decreased systemic activation of plasminogen.

In the accompanying paper, we reported that the properties of decreased plasma clearance rate, increased fibrin specificity, and resistance to inactivation by PAI-1 could be effectively combined in the t-PA variant T103N, KHRR 296-299 AAAA. In the current study we evaluated the in vivo efficacy of this variant as well as variants containing the individual mutations T103N and KHRR 296-299 AAAA. Plasma clearance and in vivo lysis of whole blood and platelet-rich clots were determined in a rabbit arterio-venous shunt model. The T103N containing variants were administered as an intravenous (i.v.) bolus. KHRR 296-299 AAAA and t-PA were infused i.v. over 90 min. The clearance rate of the KHRR 296-299 AAAA variant was similar to t-PA. However, the clearance of the T103N and T103N, KHRR 296-299 AAAA variants were 8 and 6-fold reduced, respectively. Potency of the variants relative to t-PA on whole blood clots ranged from 0.9 (T103N, KHRR 296-299 AAAA) to 1.7 (T103N). Relative potency on platelet-rich clots ranged from 2.4 (T103N) to 4.2 (T103N, KHRR 296-299 AAAA). Fibrinogen concentrations in rabbits 120 min after dosing with a 2.5 mg/kg bolus were: 24, 16, 82, and 77% of initial for t-PA; T103N; KHRR 296-299 AAAA; and T103N, KHRR 296-299 AAAA treatment groups, respectively. These results suggest that the T103N, KHRR 296-299 AAAA variant of t-PA, given as a bolus, could result in greater efficacy, particularly on refractory platelet-rich clots, without inducing the severe systemic lytic state produced by a bolus of a less fibrin specific variant.

Optimized thrombolysis of cerebral clots with tissue-type plasminogen activator in a rabbit model of embolic stroke.

The dose-dependent effects of tissue-type plasminogen activator (t-PA) on the kinetics of cerebral clot lysis in a rabbit model of middle cerebral artery embolic stroke were investigated. The clots were formed in vitro and tagged with 99Tc for gamma-scintigraphic imaging. After embolization, groups of animals were treated with t-PA. Dose-response curves for the t-PA were generated, and in addition, long and short dosing schedules were assessed. The optimal doses for frequency and rate of cerebral clot lysis in this model are approximately 6.3 mg/kg given over 2 hr or 3.3 mg/kg given over 30 min. These dosing regimens for t-PA were accompanied by approximately 50% consumption of plasma plasminogen, fibrinogen and alpha 2-antiplasmin. Doses of t-PA on either side of this optimum caused attenuation in both the frequency and rate of cerebral clot lysis. Treatment with t-PA under either dosing regimen did not augment the frequency of hemorrhagic transformation, but the size of the resultant hemorrhage in those animals where intracranial bleeding occurred was reduced by 3.3 mg/kg t-PA given over 30 min.