Thrombolytic therapy: clinical applications

Effect of encapsulation on plasminogen activator delivery to the microcirculation and its implications for bleeding

BACKGROUND AND PURPOSE

It is known that encapsulation can alter the delivery of plasminogen activators by flow to accelerate fibrinolysis while other experimental studies suggest encapsulation may reduce the risk of hemorrhage with administration of the agent. The aim of this research is to resolve the effect of encapsulation on fibrinolysis and bleeding in the microcirculation.

METHODS

An established rabbit model of fibrinolytic hemorrhage was utilized to explore the potential of encapsulation to limit bleeding. Equal dosages of free or microencapsulated streptokinase (MESK) were infused to initiate thrombolysis of small vessel clots while tracking blood loss.

RESULTS

Compared to free streptokinase, significant improvements in bleeding were observed with MESK as demonstrated by (1) delayed onset of bleeding, (2) shortened duration, and (3) reduction in the volume of lost blood, consistent with less systemic fibrinogen degradation.

CONCLUSIONS

Findings demonstrate that encapsulation of streptokinase can inhibit clot lysis in small vessels. Combined with prior work on accelerated thrombolysis, results suggest a time-based regimen for avoiding bleeding complications during thrombolytic therapy with encapsulated agent.

Thrombolysis by chemically modified coagulation factor Xa

Essentials Factor Xa (FXa) acquires cleavage-mediated tissue plasminogen activator (tPA) cofactor activity. Recombinant (r) tPA is the predominant thrombolytic drug, but it may cause systemic side effects. Chemically modified, non-enzymatic FXa was produced (Xai-K), which rapidly lysed thrombi in mice. Unlike rtPA, Xai-K had no systemic fibrinolysis activation markers, indicating improved safety.

SUMMARY

Background Enzymatic thrombolysis carries the risk of hemorrhage and re-occlusion must be evaded by co-administration with an anticoagulant. Toward further improving these shortcomings, we report a novel dual-functioning molecule, Xai-K, which is both a non-enzymatic thrombolytic agent and an anticoagulant. Xai-K is based on clotting factor Xa, whose sequential plasmin-mediated fragments, FXaβ and Xa33/13, accelerate the principal thrombolytic agent, tissue plasminogen activator (tPA), but only when localized to anionic phospholipid. Methods The effect of Xai-K on fibrinolysis was measured in vitro by turbidity, thromboelastography and chromogenic assays, and measured in a murine model of occlusive carotid thrombosis by Doppler ultrasound. The anticoagulant properties of Xai-K were evaluated by normal plasma clotting assays, and in murine liver laceration and tail amputation hemostatic models. Results Xa33/13, which participates in fibrinolysis of purified fibrin, was rapidly inhibited in plasma. Cleavage was blocked at FXaβ by modifying residues at the active site. The resultant Xai-K (1 nm) enhanced plasma clot dissolution by ~7-fold in vitro and was dependent on tPA. Xai-K alone (2.0 μg g(-1) body weight) achieved therapeutic patency in mice. The minimum primary dose of the tPA variant, Tenecteplase (TNK; 17 μg g(-1) ), could be reduced by > 30-fold to restore blood flow with adjunctive Xai-K (0.5 μg g(-1) ). TNK-induced systemic markers of fibrinolysis were not detected with Xai-K (2.0 μg g(-1) ). Xai-K had anticoagulant activity that was somewhat attenuated compared with a previously reported analogue. Conclusion These results suggest that Xai-K may ameliorate the safety profile of therapeutic thrombolysis, either as a primary or tPA/TNK-adjunctive agent.

Tissue Plasminogen Activator Use in Children: Bleeding Complications and Thrombus Resolution

OBJECTIVE

To review our institutional experience with tissue plasminogen activator (tPA) to determine outcomes related to bleeding complications and thrombus resolution.

STUDY DESIGN

We performed a retrospective review of all patients who received systemic tPA for thrombolysis. Data points included location of thrombus, initial and maximum tPA dose, and duration of tPA. The primary endpoint was bleeding complication.

RESULTS

Between 2005 and 2014, 46 patients received systemic tPA for thrombolysis: 17 (37%) were patients with a primary cardiac diagnosis, there were 17 (37%) hematology/oncology patients, and 12 (26%) patients with noncardiac, nonhematology/oncology diagnoses. The indication for tPA was central venous thrombus (n = 23), pulmonary artery thrombus (n = 9), and cardiac or aortic thrombus (n = 14). Bleeding complications occurred in 15 patients (33%). Median initial tPA dose in the bleeding complication group was 0.10 mg/kg/h vs 0.03 mg/kg/h in the group without bleeding complication group (P = .01). Cardiac patients experienced more bleeding complications (P = .01). Multivariate analysis indicated that dose of tPA (P = .01) and diagnostic category (P < .01) were associated with bleeding complication. Complete thrombus resolution occurred in 21 patients, partial in 10 patients, and no resolution in 15 patients. Complete resolution of thrombus was not associated with diagnosis, thrombus location, tPA dose, or duration.

CONCLUSIONS

Cardiac patients appear to be at highest risk of bleeding complication; bleeding complications were associated with higher doses of tPA, and cardiac patients were the cohort who received the highest doses of tPA. Higher tPA doses are associated with increased risk of bleeding complication but are not associated with successful thrombus resolution.

Management of acute subdural hematomas in infants: intrathecal infusion streptokinase for clot lysis combined with subdural to subgaleal shunt

OBJECT

Subdural hematomas (SDHs) in full-term infants have the potential to cause death or lifelong disability. We report management and outcomes of eight cases of newborn with large SDH treated by streptokinase (SK) lavage and drainage.

MATERIALS AND METHODS

Between 2003 and 2006, eight infants with large acute SDH with focal or diffuse hypodensity showing signs and symptoms of neurological deterioration were treated by drainage and subdural SK lavage. There were eight full-term infants, five boys and three girls, with ages between 10 days and 2 months. Head injuries were shaken baby syndrome in three cases, fall from height in three cases, caused by traffic accident in one case, and reportedly not due to trauma in one case. In all patients, SDHs were unilateral. We used a new surgical approach, SDH evacuation, involving the subdural instillation of SK for lysis and after drainage of acute SDH in infants. Follow-up in the series ranged from 1 to 42 months (average 30 months). There was no mortality in this series, neither in the early postoperative period nor in the follow-up period. Five patients of this series lead a normal life; two children were mildly neurodevelopmentally delayed.

CONCLUSION

Subdural infusion of SK followed by drainage may be as safe and effective for treatment of acute SDHs in infants as other reported methods.

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.

Thrombolytic therapy in children

Thrombolysis is increasingly considered a treatment option in newborns and children with arterial and venous thromboembolic events, or occluded central venous lines. However, no uniform recommendations are available with regard to indications, drug of choice, route of administration, and dosing regimen. Thus, several protocols are used for the different thrombolytic agents, leading to differing outcome with respect to the effectiveness of therapy and bleeding complications. This article will summarize the available information on the use of thrombolytic agents in newborns and children, focussing on the potential indications, efficacy and safety profiles, and evidence supporting dosing schedules.