Krasimir Kolev scite author profile

SummaryThe structure of the fibrin network, the hemodynamic environment of the clot, the kinetic properties of the fibrinolytic enzymes and the balance of their formation and inactivation essentially determine the effectiveness of fibrinolysis in vivo. The fibrin structure and the action of proteases, however depend considerably on additional, apparently inert physiological and pathological factors, which are restricted to more or less transient compartments in fluid-solid interface, such as thrombus (fibrin with platelet membrane structures), endothelial cell surface, the environment of polymorphonuclear cells (PMN). In these compartments extreme changes in concentrations and rate enhancements are observed. Components released by endothelial cells, PMNs and platelets or molecules present in circulating blood create a heterogeneous milieu that modulates fibrinolysis. This review summarizes the effects, and where it is possible, explains the mechanism of modulators of the fibrinolytic processes, such as cell membrane and cellular contents of endothelium, PMN and platelets present in thrombi, the action of normal and pathological blood plasma- and extracellular matrix-components.

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Quantitative Comparison of Fibrin Degradation with Plasmin, Miniplasmin, Neurophil Leukocyte Elastase and Cathepsin G

Kolev

Komorowicz

Owen

et al. 1996

Thromb Haemost

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SummaryThe relative contribution of plasmin, miniplasmin, PMN-elastase and cathepsin G to the fibrin-gel dissolution is studied. The global kcat/KM ratios are determined as a measure of the fibrinolytic catalytic efficiency using spectrophotometric kinetic analysis of the competition between fibrin and synthetic peptide substrates for the proteases, turbi-dimetric assay for fibrin dissolution and gel-filtration of the partially degraded fibrin. When the substrate is fibrin polymerized in the presence of 3 mM Ca2+, the value of this ratio is 4.3 × 105 M-1·s-1 for plasmin, 1.9 × 105 M-1·s-1 for miniplasmin, 5.0 × 104 M-1·s-1 for PMN-elastase and 2.2 × 103 M-1·s-1 for cathepsin G. When fibrin is polymerized without addition of Ca2+, the kcat/KM values are increased by a factor of 2.3 for plasmin, 2.0 for miniplasmin and 1.6 for cathepsin G, whereas that of PMN-elastase is unchanged. Progressive crosslinking of fibrin decreases the catalytic action of all studied proteases, but no change in their relative contribution to fibrinolysis is observed. When plasmin inhibitor (at physiological concentration) is also crosslinked to fibrin, the most efficient fibrinolytic enzymes are miniplasmin and PMN-elastase. The effect of 6-aminohexanoate on the formation of fibrin degradation products by plasmin and miniplasmin suggests that the high-affinity lysine binding site in the N-terminal kringle domain of plasmin is involved in the interactions with the native polymerized fibrin, whereas the fifth kringle found in both enzymes participates in binding to newly exposed lysine residues. These results provide a quantitative basis for the evaluation of fibrinolytic efficiency and support the concept of synergistic fibrinolysis.

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Flow Rate–Modulated Dissolution of Fibrin With Clot-Embedded and Circulating Proteases

Komorowicz

Kolev

Léránt

et al. 1998

Circulation Research

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The efficiency of plasmin, miniplasmin, and neutrophil leukocyte elastase in fibrin digestion is well characterized in static systems. Since in vivo the components of the fibrinolytic system are permanently exposed to flow, we have developed two in vitro models and studied the effect of shear forces on fibrin dissolution with these proteases. Cylindrical nonocclusive fibrin clots are perfused at various flow rates through their preformed axial channel, and dissolution of fibrin is followed by measuring the absorbance of degradation products released into the circulating fluid phase. In one experimental setting, fibrin surface is degraded with enzymes applied in the recirculating fluid phase; in another setting, clots containing gel-embedded proteases are perfused with enzyme-free buffer. As shear rate at fibrin surface is changed from 25 to 500 s(-1), the rate of product release by recirculated enzymes increases 2.8-, 2.9-, and 4-fold for plasmin, miniplasmin, and porcine pancreatic elastase, respectively. Buffer-perfused fibrin containing gel-embedded plasmin or miniplasmin is disintegrated by shear forces at a relatively early stage of dissolution, and this disassembly is related to the formation of fragment Y (150 kDa) and fragment D (100 kDa) fibrin degradation products. Fibrin clots degraded by incorporated polymorphonuclear leukocyte elastase, which yields different degradation products, do not disassemble abruptly, even at the highest shear rate (500 s(-1)). Our results suggest that fibrin surface degradation is accelerated with increasing shear rate and that plasmin or miniplasmin embedded in the clot promotes the release of particular clot remnants into the circulating phase, whereas polymorphonuclear leukocyte elastase does not.

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Immunoglobulin G from Patients with Antiphospholipid Syndrome Impairs the Fibrin Dissolution with Plasmin

et al. 2002

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SummaryImmunoglobulin G (IgG) isolated from normal human blood plasma stabilizes the structure of perfused crosslinked fibrin and prolongs the time for its dissolution with plasmin, when the fibrin surface is exposed to 500 s-1 shear rate flow. The IgG from patients suffering in antiphospholipid syndrome with thrombotic complications exerts even stronger antifibrinolytic effect. A patient, whose IgG does not affect the fibrin dissolution with plasmin, displays a bleeding tendency. The shear stress-induced disassembly of the fibrin clots containing IgGs with antifibrinolytic potency occurs at a much more advanced stage of fibrin digestion, as evidenced by the electrophoretic pattern of the ureatreated samples. The antifibrinolytic effects are also produced under static conditions and these are caused by the variable portion of the IgG molecules (fragment Fab), whereas the constant part (fragment Fc) has no inhibitory effect. The IgGs with antifibrinolytic properties do not affect directly the plasmin activity in amidolytic assay, but the IgGs from APS patients obliterate the competition of the fibrin and the peptidyl-p-nitroanilide for the protease in the same assay system suggesting interference of the IgGs with the plasmin action on the fibrin substrate. Thus, the correlation of the clinical symptoms with the effect of the isolated IgG on the dissolution of perfused fibrin clots supports a physiological and a pathological role of IgG in the fibrinolytic process related to the variability of the cross-reactions of immunoglobulins with fibrin, fibrin degradation products or fibrin-plasmin complexes.

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Contraction of Human Brain Endothelial Cells Induced by Thrombogenic and Fibrinolytic Factors

Nagy

Kolev

Csonka

et al. 1995

Stroke

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In an in vitro model we have demonstrated that factors involved in thrombus formation and dissolution induce endothelial cell contraction, which could affect focally the permeability of the blood-brain barrier by opening paracellular avenues between endothelial cells in vivo. Thus, the genesis of brain edema in thromboembolic stroke or occasionally during fibrinolytic therapy can be attributed in part to the contact of these factors with the microvascular endothelium.

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Krasimir Kolev

Molecular and cellular modulation of fibrinolysis

Quantitative Comparison of Fibrin Degradation with Plasmin, Miniplasmin, Neurophil Leukocyte Elastase and Cathepsin G

Flow Rate–Modulated Dissolution of Fibrin With Clot-Embedded and Circulating Proteases

Immunoglobulin G from Patients with Antiphospholipid Syndrome Impairs the Fibrin Dissolution with Plasmin

Contraction of Human Brain Endothelial Cells Induced by Thrombogenic and Fibrinolytic Factors

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