Partial identification of the fibrinolytic activators in onion.

A steam-distilled and an ether extract of onion have both been found to enhance blood fibrinolysis without depressing fibrinogen content in groups of human volunteers. Chemical analysis has shown which sulphur-containing compounds were in highest concentration and common to both and thus likely to carry this property, but their very intense and prolonged flavour precludes their clinical use. One sulphur containing but nearly odourless compound has been identified as having indirect fibrinolytic potential. A species difference in respect of fibrinolysis has been found between English and Spanish onion but is of little importance.     

Characterization of the fibrinolytic state by measuring stable cross-linked fibrin degradation products in disseminated intravascular coagulation associated with acute promyelocytic leukemia

Plasma samples from patients with disseminated intravascular coagulation (DIC) associated with acute promyelocytic leukemia (APL) exhibited higher levels of the D-fragment of fibrin and fibrinogen degradation products [FDP(D)], with relatively lower levels of cross-linked fibrin degradation products (XDP), than samples of DIC with non-APL. The difference between FDP(D) and XDP levels increased only when alpha 2-plasmin inhibitor (alpha 2-PI) fell below 60% of the normal level in APL patients. These findings suggest that fibrinogenolysis occurs in APL patients when the alpha 2-PI level has decreased significantly.     

Activation of the fibrinolytic system

The fibrinolytic system is activated either directly or indirectly by proteins that convert plasminogen to plasmin in the circulation, within the interstitices, and on the surface of fibrin clots, or both. Agents that activate circulating and clot-bound plasminogen comparably induce a systemic lytic state accompanying clot lysis. Agents that activate plasminogen in the domain of fibrin preferentially exhibit clot selectivity. Fibrinolytic activators are assayed by detection of protein, generally immunologically, or of functional activity, generally by visualization of lysis of fibrin or by spectrophotometric determination of amidolytic activity.     

Interactions between fibrin and the plasminogen activators produced by cultured endothelial cells

Serum-free conditioned medium (CM) from cultured bovine aortic endothelial cells (BAEs) was fractionated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and analyzed for plasminogen activator (PA) activity by fibrin autography. Distinct size forms of PA with molecular weights (mol wt) of 100,000, 74,000, and 52,000 were readily identified by this approach. When fibrinogen and thrombin were added to CM containing these forms, approximately 55% of the total activity was found to associate with the resultant fibrin clot. The other 45% remained free in the supernatant. This relationship did not change at higher fibrin concentrations. Subsequent analysis revealed that only the larger PA forms (mol wt 74,000-100,000) were recovered in the clot. The 52,000 form did not bind to the polymerizing fibrin under these conditions. The fibrin-binding forms also bound to immobilized concanavalin-A and could be separated from those forms that did not interact with fibrin by concanavalin-A affinity chromatography. The PA activity of the separated forms was then compared by assessing their ability to cleave 125I-plasminogen. Although cleavage by the 52,000 mol wt form was apparent, little if any cleavage was initiated by the mixture containing the 74,000-100,000 forms. The addition of fibrin to this sample resulted in the generation of a potent PA activity. These results indicate that cultured BAEs produce multiple forms of PA that differ both in size and in behavior toward fibrin and concanavalin-A. These forms include molecules that functionally and immunochemically resemble human urokinase, and others that resemble human tissue-type PA.     

Increased immunoreactivity of plasma after fibrinolytic activation in an anti-DD ELISA system. Role of soluble crosslinked fibrin polymers

After addition of a low concentration of thrombin to normal plasma, a progressive and significant increase in crosslinked fibrin polymers was found by sodium dodecyl sulfate agarose gel electrophoresis, reaching 27% of total fibrinogen and fibrin before gel formation. As measured by enzyme-linked immunosorbent assay with a monoclonal antibody specific for an epitope near the gamma gamma crosslink site, increased immunoreactivity of plasma did not occur after adding thrombin despite formation of crosslinked fibrin polymers, which indicates that the antibody does not recognize the epitope in the polymers. Addition of tissue-type plasminogen activator (t-PA) to plasma resulted in a more rapid degradation of fibrin polymers than of fibrinogen, indicating that the fibrin specificity of t-PA is retained with soluble fibrin. Coincident with degradation of plasma crosslinked fibrin polymers, plasma DD immunoreactivity increased 70-fold from 50.3 +/- 4.5 (mean +/- SD) to 3,560 +/- 1,235 ng/ml. The presence of increased crosslinked fibrin polymers produced by adding thrombin to plasma significantly increased maximum immunoreactivity after t-PA-induced degradation to 18,500 +/- 11,780 ng/ml. The increase in DD immunoreactivity was dependent on t-PA concentration; no elevation occurred below 0.01 micrograms/ml, and maximal increases occurred above 100 micrograms/ml. Analysis of gel electrophoretic patterns of thrombin and t-PA-treated plasma samples suggests that the DD reactivity of t-PA-treated plasma is mainly due to degradation of soluble crosslinked fibrin polymers. Our findings indicate that plasmic degradation of soluble fibrin polymers in plasma may be an important source of fragment DD during thrombolytic therapy.     

The fibrinolytic system in man

The existence of a system in the human body capable of inducing the dissolution of endogenous pathologically formed thrombi was appreciated in ancient times. Considered in detail in this article are the data that have elucidated the physiologic regulation of which plasmin formation is dependent on, the plasma concentration of plasminogen, availability of activators of plasminogen in the plasma and surrounding tissue environment, the concentration of naturally present inhibitors, and the existence of fibrin in the circulation. Important in this rapidly progressive scientific discipline is consideration of the factors which control the synthesis of the components of this proteolytic enzyme system. Recently abundant information has indicated that this plasminogen-plasmin proteolytic enzyme system can be utilized therapeutically. Knowledge of the mechanisms of this system has permitted identification of agents that can be exogenously administered to releave thrombotic obstruction to blood flow in the venous (pulmonary emboli, deep vein thrombosis) and arterial (peripheral and central vessels) circulatory systems. Particularly important is the demonstration that thrombolytic agents can directly attack and alleviate the immediate cause of acute myocardial infarction. As a result of the innovations in the present decade, it is evident that the plasminogen system can be advantageously employed to reverse the pathologic effects of all thrombotic diseases.     

The fibrinolytic system in man

The fibrinolytic system comprises a proenzyme, plasminogen, which can be activated to the active enzyme plasmin, that will degrade fibrin by different types of plasminogen activators. Inhibition of fibrinolysis may occur at the level of plasmin or at the level of the activators. Fibrinolysis in human blood seems to be regulated by specific molecular interactions between these components. In plasma, normally no systemic plasminogen activation occurs. When fibrin is formed, small amounts of plasminogen activator and plasminogen adsorb to the fibrin, and plasmin is generated in situ. The formed plasmin, which remains transiently complexed to fibrin, is only slowly inactivated by alpha 2-antiplasmin, while plasmin, which is released from digested fibrin, is rapidly and irreversibly neutralized. The fibrinolytic process, thus, seems to be triggered by and confined to fibrin. Thrombus formation may occur as the result of insufficient activation of the fibrinolytic system and (or) the presence of excess inhibitors, while excessive activation and/or deficiency of inhibitors might cause excessive plasmin formation and a bleeding tendency. Evidence obtained in animal models suggests that tissue-type plasminogen activator, obtained by recombinant DNA technology, may constitute a specific clot-selective thrombolytic agent with higher specific activity and fewer side effects than those currently in use.     

The fibrinolytic system in children

The fibrinolytic system comprises a cascade of serine proteinase activation events that culminate in the generation of plasmin and, subsequently, degradation of fibrin. Although all components of the fibrinolytic system are present at birth, plasma concentrations of key components in infants and children differ physiologically from those in adults. Until the age of 6 months, plasma concentrations of plasminogen and alpha (2)-antiplasmin are decreased to 50% and 80% of adult values, respectively, while plasma concentrations of tissue-type plasminogen activator are decreased and plasminogen activator inhibitor-1 are increased throughout childhood. In addition, the rate of plasmin generation in newborns and the overall fibrinolytic activity during childhood are decreased compared with adults. Strong evidence suggests that age-dependent differences in the fibrinolytic system critically influence the effectiveness and safety of thrombolytic agents. In addition, recent studies suggest that impaired fibrinolysis may play an important role in the pathogenesis of several diseases such as venous and arterial diseases and vasculitis, which are associated with both endothelial cell damage and increased thrombotic risk. This article will discuss the ontogenic features of the fibrinolytic system in children and summarize the available information on the effect of developmental fibrinolysis on both the course of specific disease states and the response to thrombolytic therapy in children.