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 response to ancrod therapy: characterization of fibrinogen and fibrin degradation products

Ancrod is a purified coagulant venom which renders blood incoagulable by cleaving fibrinopeptide A (FPA) from fibrinogen, but the mechanism involved in the clearance of fibrin from the circulation is unknown. To investigate the fibrinolytic response to ancrod, and to increase understanding of clearance mechanisms, six patients with peripheral vascular disease causing claudication were infused with ancrod at 2 u/kg over 6 h followed by 2 u/kg at 12 h intervals for 38 h. Venous blood samples were taken at time 0, 3, 6, 25 and 49 h for assay of fibrinogen (Fbg), fibrinopeptide A (FPA), total fibrin(ogen) degradation products (TDP), fibrin degradation products (FbDP), fibrinogen degradation products (FgDP), cross-linked fibrin degradation products (XL-FDP), tissue plasminogen activator (tPA), urinary type plasminogen activator (u-PA), plasminogen, α₂ antiplasmin (α₂AP) and plasminogen activator inhibitor-1 (PAI-1). Fibrinogen (median and range) was 2.3 (1.4–3.90) g/l at time 0 and thereafter was undetectable. FPA rose from 2.5 (1.8–3.6) to 600 and 188 pmol/l at 3 h and 6 h and remained elevated. TDP, FbDP and FgDP increased greatly following ancrod while there was no evidence of XL-FDP. The surprising increase in FgDP during defibrination suggests either that fibrinogen is digested following its incorporation into circulating fibrin protofibrils or that some of the fibrin subunits in the photofibril retain one of the two fibrinopeptide A's. tPA and uPA remained unchanged. Plasminogen fell from 125 (100–155)% to 79 (40–118)% at 49 h and α₂AP fell from 91 (75–107)% to 24 (10–35)% at 49 h. The level of PAI-1 was depressed during defibrination, with the exception of the 6 h data. The results demonstrate that ancrod removes FPA from fibrinogen to produce non-cross-linked (soluble) fibrin. This is cleared from the circulation without evidence of an increase in the circulating activities of the plasminogen activators, tPA or UK, but with evidence of plasminogen activation and consumption.     

Newly developed stenocardia: effect of intensive physical training on the indicators of the blood coagulation system and fibrinolysis

The impact of 6-week strenuous exercise training (SET) on blood coagulative and fibrinolytic parameters (levels of fibrinogen, soluble fibrin, fibrinogen-fibrin degradation products, activities of plasminogen and plasmin) was studied in 28 patients with first angina pectoris, in 16 of whom in the first 3 months of onset of the disease, but angina pectoris lasting 3-4 prior to SET. The 6-week strenuous exercises in patients with first angina were found to cause a decrease in fibrinogen levels, exert no action on thrombin and fibrin formation. They did not diminish plasminogen activator release during exercise in patients with pre-exercise unstable angina.     

Fibrin degradation products generation and fibrinopeptide A release in normal plasma incubated with thrombolytic agents: proposed mechanisms.

Clinical data have shown that the evaluation of fibrin degradation products (FbDP) does not reflect the efficiency of thrombolytic therapy in vivo. In this study, we found that the addition of plasminogen activators to normal plasma resulted in generation of FbDP and release of fibrinopeptide A (FpA) as shown by ELISA and HPLC. This FpA release was concomitant with fibrinogen degradation, and was not inhibited by thrombin inhibition or by prothrombin depletion in plasma. Thus, the increase in FpA did not result from coagulation activation and may result from the plasmin-induced release of FpA from fibrinogen degradation product E1. The generation of cross-linked FbDP after tPA addition occurred in normal plasma as well as in factor-XIII-deficient plasma and quickly reached a plateau. It was not inhibited by hirudin. Therefore FbDP in these plasmas probably derived from the plasmin degradation of cellular transglutaminase cross-linked fibrin/fibrinogen derivatives present in plasma.     

Activated protein C stimulates the fibrinolytic activity of cultured endothelial cells and decreases antiactivator activity.

The effects of bovine activated protein C (APC) on the fibrinolytic activity of cultured bovine aortic endothelial cells were investigated. Confluent monolayers were incubated with purified APC under various conditions and changes in total fibrinolytic activity and in the level of plasminogen activator and plasminogen activator inhibitor (antiactivator) were monitored. The addition of APC to the cells in the absence of other blood or plasma components led to a rapid, dose-dependent increase of fibrinolytic activity both in the media and in cellular extracts. For example, 3.4 micrograms of APC per ml resulted in a 15-fold increase of fibrinolytic activity in the medium within 1 hour. The enhanced fibrinolytic activity reflected increases in both the urokinase-related and tissue-type plasminogen activators produced by these cells. Interestingly, treatment of cells with APC also caused a rapid, dose-dependent decrease in antiactivator activity. Diisopropyl fluorophosphate-inactivated APC did not decrease antiactivator or increase plasminogen activator. Although a small but significant direct (i.e., cell-independent) effect of APC on both fibrinolytic activity and antiactivator activity could be demonstrated, the major portion of these changes appeared to be cell-mediated. These observations indicate that the fibrinolytic potential of cultured endothelial cells is increased by APC and that the enzyme active site is essential for this change. Moreover, the results suggest that one of the primary mechanisms for this stimulation of endothelial cell fibrinolytic activity involves an APC-mediated decrease in antiactivator.     

Characterization in vivo of the fibrin specificity of activators of the fibrinolytic system

Development of appropriate clinical dose regimens of individual plasminogen activators such as tissue-type plasminogen activator (t-PA) has generally relied primarily on nonpharmacological endpoints such as angiographically documented clot lysis. The recent availability of monoclonal antibodies that differentiate products of plasmin lysis of fibrin from those of lysis of fibrinogen should permit delineation of the relative fibrin specificity of different plasminogen activators or of different doses of the same activator in vivo. Thus, their use should accelerate and facilitate development of implementation of optimal dose regimens for diverse activators and combinations of activators. The present study was designed to determine whether assay of such markers effectively differentiates effects of two doses of t-PA, each of which are comparably effective in opening infarct-related arteries, in patients studied at the Washington University Clinical Unit of the National Institutes of Health-sponsored Thrombolysis in Myocardial Infarction Trial. The extent of lysis of fibrin and of lysis of fibrinogen by plasmin resulting from administration of t-PA was evaluated in 19 patients given 150 mg t-PA over 6 hours and 17 given 100 mg over the same interval by assay of serially obtained plasma samples for crosslinked fibrin degradation products (XL-FDP) and B beta 1-42, a peptide released when fibrinogen is degraded to fragment X by plasmin. XL-FDP were markedly elevated after 6-hour infusions of both doses of t-PA. However, elevations were not more with the higher dose [peak value, 4,321 +/- 986 ng/ml (+/- SEM)] compared with the lower dose (3,397 +/- 1,096 ng/ml) (p = NS).(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of the common bile acids on the fibrin/fibrinogen fragments in rheumatoid synovial fluid. A possible clue to the ameliorating effect of jaundice in rheumatoid arthritis.

Fibrin/fibrinogen degradation products observed in rheumatoid synovial fluid exhibit resistance to plasmin proteolysis. In the present study, the influence of the common bile acids on the plasmin digestion of these degradation products in 16 rheumatoid synovial fluids were quantitated immunologically by radial immunodiffusion, and qualitatively estimated by crossed immunoelectrophoresis. Addition of chenodeoxycholic acid, deoxycholic acid, and their taurine and glycine conjugates in concentrations of 3.33 mumole/ml of a mixture of rheumatoid synovial fluid and plasmin resulted in complete plasmin degradation. Cholic acid and its taurine and glycine conjugates were effective only in concentrations of 4.44 mumole/ml. A detergent, such as Triton X-100, had little or no effect on the plasmin digestion. Other proteins capable of influencing fibrinolytic activity, such as plasminogen and the inhibitors alpha1-antitrypsin and alpha2-macroglobulin, were not affected by the two detergents. The bile acids are thought to influence the fibrin/fibrinogen degradation products by unfolding the protein at a molecular level, by virtue of their properties as steroid detergents, leaving the fibrin/fibrinogen degradation products susceptible to plasmin digestion.     

Measurements of plasmin-alpha 2 plasmin inhibitor complex and FDP.D dimer levels in the fibrinolytic therapy of acute pulmonary thromboembolism]

The key enzyme for fibrinolysis is plasmin, which is converted from plasminogen by plasminogen activator. Activated plasmin lyses fibrinogen and fibrin to make fibrin degradation products(FDPs) and plasmin is inactivated immediately by alpha 2 plasmin inhibitor. As FDP.D dimer is derived solely from insoluble fibrin, FDP.D dimer is thought of as an index for clot lysis. We measured plasmin-alpha 2 plasmin inhibitor complex(PIC) and FDP.D dimer plasma levels in 3 patients with acute pulmonary thromboembolism treated with recombinant tissue plasminogen activator(tPA). Fifteen million units of tPA(TD-2061) were infused in one hour on the first, second and third hospital days. PIC and FDP.D dimer before tPA infusion showed slightly elevated values as compared to normal ranges. They increased markedly after tPA infusion. These findings suggest that the fibrinolytic system is slightly activated in the acute phase of pulmonary thromboembolism and also strongly activated by tPA infusion. Increased FDP D dimer suggests that fibrin clots are dissolved by activated plasmin. Improvement of arterial oxygen tension was observed after tPA infusion. As sustained higher FDP.D dimer means the existence of fibrin clots, heparin treatment should be continued for prevention of clot formation as long as FDP.D dimer shows higher value. In conclusion, PIC and FDP.D dimer are useful indices not only to detect the activated state of the fibrinolytic system but also to know clot lysis in tPA treatment.     

Content of fibrinogen degradation products, soluble fibrin and the fibrinolytic activity of blood in myocardial infarct]

The blood content of soluble fibrin and D and E fibrinogen fragments, the protamine sulfate test and the activity of plasmin and plasminogen activator were studied in patients with macrofocal myocardial infarction. It was established that the content of soluble fibrin in blood considerably increases in the first days of the disease, and the level of products of fibrinogen D and E disintegrationand the value of the protamine sulfate test increase in the 2nd--3rd week of the disease. The appearance in the blood of fibrinogen derivates was attended by low activity of plasmin and plasminogen activator in blood. The highest content of fibrinogen derivates and low activity of plasmin and plasminogen activator were noted in patients with arrhythmias and congestive circulatory insufficiency. It is suggested that the appearance in circulation of high-molecular fibrinogen compounds is important in the development of rheological disorders.     

Fibrinolysis at Rest and after Exercise in Hepatic Cirrhosis

S ummary . A study of the fibrinolytic enzyme system in 37 cirrhotic patients at rest and 15 cirrhotic patients following a treadmill exercise procedure is reported. An outstanding feature of the resting studies was a significant elevation in the levels of plasma plasminogen activator and serum fibrin/fibrinogen degradation products, when compared to age and sex-matched healthy controls. Moreover, there was a significant positive correlation between those two fibrinolytic parameters. No significant difference was demonstrated between the control and cirrhotic groups in relation to plasma fibrinogen, euglobulin plasminogen and plasma urokinase inhibitor activity. The exercise studies showed that following an entirely physiological stimulus the plasminogen activator response in some cirrhotics was excessive in terms of either the initial response and/or prolongation of the recovery period. However, an exaggerated initial response was not necessarily followed by a prolongation recovery period nor was a relationship established between the resting levels of plasminogen and an abnormal exercise response. Furthermore, there was no correlation between the increases in plasminogen activator and serum fibrin/ fibrinogen degradation products following exercise.     

链激酶,尿激酶静脉溶栓对凝血和纤溶系统的影响

尿激酶（ＵＫ）和链激酶（ＳＫ）同属第一代溶栓剂，二者均无“纤维蛋白选择性”，本研究目的在于比较ＳＫ和ＵＫ对凝血和纤溶系统的影响及其与临床的关系。静脉溶栓治疗急性心肌梗塞１１１例，其中５５例使用ＳＫ（１５０万单位／例），５６例使用ＵＫ（１．７－２．３万单位／ｋｇ体重，平均１５３．２５万单位／例），于溶栓前、溶栓后２、６、１２、２４小时、第３天、第７天分别测定血浆纤溶酶原激活物（ＰＡ）、纤溶酶原激活物抑制物（ＰＡＩ）、及纤溶酶原（ＰＬＧ）活性，并测定纤维蛋白原（ＦＧ）浓度、激活的试管法凝血时间（ＡＣＴ）。结果显示：ＳＫ引起的凝血和纤溶系统变化均比ＵＫ明显，特征为：在溶栓后２～６小时有较高的ＰＡ活性和较低的ＰＡＩ活性；溶栓后２小时较长的凝血时间；较低的纤维蛋白原浓度从２小时持续到第７天，上述差异均有极显著意义。本文结果提示ＳＫ对凝血和纤溶系统的影响比ＵＫ强烈而持久，二者在血液学特征上的差异与临床疗效及使用抗凝剂等问题可能有一定的关系。     

Progress of fibrinolysis during tumor necrosis factor infusions in humans. Concomitant increase in tissue-type plasminogen activator, plasminogen activator inhibitor type-1, and fibrin(ogen) degradation products.

Several investigators have reported that tumor necrosis factor (TNF) can alter the production of plasminogen activator type-1 (PAI-1) and plasminogen activators (PAs) by endothelial cells in vitro. We have examined the in vivo effects of recombinant human TNF administration on fibrinolysis as assessed by parameters in plasma during a 24-hour period of continuous TNF infusion to 17 cancer patients with active disease. The plasma levels of PAI activity increased sevenfold after 3 and 24 hours of TNF infusion. This was the result of an increase of PAI-1 antigen; PAI-2 antigen was not detectable. Plasma concentrations of tissue-type PA (t-PA) antigen increased twofold to fivefold after 3 and 24 hours of TNF infusion, whereas urokinase-type PA antigen levels in plasma remained unaltered. After 3 hours of TNF infusion the plasma levels of alpha 2-antiplasmin were slightly decreased, 5% on average, suggesting that fibrinolysis continued. After 24 hours of TNF infusion a highly significant increase in fibrin- plus fibrinogen-degradation products, and separately of fibrin degradation products and fibrinogen degradation products, was found. This indicates that fibrinolysis persisted, at least partly, in the presence of high levels of PAI activity. Whereas PAI-1 production increased, t-PA production by human endothelial cells in vitro remains unaltered or even decreases on TNF addition. It has been shown previously that TNF infusion in our patients results in thrombin and fibrin generation. Therefore, it is possible that thrombin, not TNF, is the actual stimulus for t-PA production in our patients. We speculate that fibrin is formed during TNF infusions and that plasmin is generated by t-PA action immediately on the initial formation of (soluble) fibrin molecules. Such a process may explain the generation of degradation products of both fibrin and fibrinogen during infusion of TNF in patients.     

A catalytic switch and the conversion of streptokinase to a fibrin-targeted plasminogen activator

Plasminogen (Pg) activators such as streptokinase (SK) save lives by generating plasmin to dissolve blood clots. Some believe that the unique ability of SK to activate Pg in the absence of fibrin limits its therapeutic utility. We have found that SK contains an unusual NH(2)-terminal "catalytic switch" that allows Pg activation through both fibrin-independent and fibrin-dependent mechanisms. Unlike SK, a mutant (rSKDelta59) fusion protein lacking the 59 NH(2)-terminal residues was no longer capable of fibrin-independent Pg activation (k(cat)/K(m) decreased by >600-fold). This activity was restored by coincubation with equimolar amounts of the NH(2)-terminal peptide rSK1-59. Deletion of the NH(2) terminus made rSKDelta59 a Pg activator that requires fibrin, but not fibrinogen, for efficient catalytic function. The fibrin-dependence of the rSKDelta59 activator complex apparently resulted from selective catalytic processing of fibrin-bound Pg substrates in preference to other Pg forms. Consistent with these observations, the presence (rSK) or absence (rSKDelta59) of the SK NH(2)-terminal peptide markedly altered fibrinolysis of human clots suspended in plasma. Like native SK, rSK produced incomplete clot lysis and complete destruction of plasma fibrinogen; in contrast, rSKDelta59 produced total clot lysis and minimal fibrinogen degradation. These studies indicate that structural elements in the NH(2) terminus are responsible for SK's unique mechanism of fibrin-independent Pg activation. Because deletion of the NH(2) terminus alters SK's mechanism of action and targets Pg activation to fibrin, there is the potential to improve SK's therapeutic efficacy.     

Fibrin-associated plasminogen activation in alpha 2-plasmin inhibitor deficiency

The clot formed from the plasma of a patient with congenital deficiency of alpha 2-plasmin inhibitor underwent a spontaneous extensive fibrinolysis. Radiolabeled fibrinogen was added to the plasma before clotting, and the whole process of the fibrinolysis was followed by measuring the release of radiolabels. Plasminogen activation was also followed by measuring the amidolytic activity that developed. There was an initial latent period, followed by an exponential increase of fibrinolytic activity. During the latent period, there was little or no release of radiolabels and no development of amidolytic activity. During the latent period, the clot was washed thoroughly to remove unbound proteins from fibrin and was incubated in buffered saline. The washed clot still underwent fibrinolysis, similar to the original plasma clot, suggesting that the plasminogen/plasminogen activators bound to fibrin during the initial latent period are responsible for fibrinolysis. The amount of plasminogen bound to fibrin during the latent period was close to the amount of plasminogen activated during the whole process of fibrinolysis. When the amount of plasminogen bound to fibrin was decreased by epsilon aminocaproic acid, the extent of fibrinolysis was decreased in parallel with the decrease of the amount of the bound plasminogen. This suggests that the amount of plasminogen bound to fibrin is one of the determinants of the rate of the fibrinolytic process.     

Regulation by alpha 2-antiplasmin and fibrin of the activation of plasminogen with recombinant staphylokinase in plasma

The effects of alpha 2-antiplasmin and fibrin on the activation of plasminogen by recombinant staphylokinase (STAR) were studied in an effort to elucidate further the molecular basis of the fibrin- specificity of this fibrinolytic agent. In purified systems consisting of 1.5 mumol/L intact or low-M(r) plasminogen and 3 mumol/L alpha 2- antiplasmin, at 37 degrees C and in the absence of fibrin, STAR did not induce plasminogen activation and plasmin-alpha 2-antiplasmin complex (PAP) formation. Addition of a purified fibrin clot (30% vol at a concentration of 3 mg/mL) to mixtures containing intact plasminogen caused approximately 40% plasminogen activation within 2 hours, whereas in mixtures containing low-M(r) plasminogen, no activation was observed. In contrast, 10 nmol/L streptokinase (SK) induced 74% to 100% plasminogen activation within 2 hours in mixtures containing either intact or low-M(r) plasminogen, in both the absence and the presence of fibrin. In citrated human plasma in the absence of fibrin, 30 nmol/L STAR did not induce measurable plasminogen activation and PAP formation (< 1.5% within 2 hours), whereas addition of a plasma clot (12% vol) resulted in complete clot lysis and conversion of 19% +/- 8% of the plasminogen to PAP within 2 hours. Addition of a second plasma clot produced 23% +/- 2% additional plasminogen activation. Equipotent concentrations for plasma clot lysis of SK (100 nmol/L) induced 54% +/- 11% plasminogen activation in the absence and 49% +/- 16% in the presence of fibrin. Addition of 50 mmol/L 6-aminohexanoic acid (6-AHA) abolished the effect of fibrin on plasminogen activation with STAR, but not on activation with SK. In alpha 2-antiplasmin-depleted human plasma in the absence of fibrin, 30 nmol/L STAR did not induce fibrinogen breakdown (> 90% residual fibrinogen after 6 hours), whereas 30 nmol/L preformed plasmin-STAR complex induced extensive fibrinogen degradation (70% within 20 minutes). Thus, in the absence of fibrin, alpha 2- antiplasmin inhibits the activation of plasminogen by STAR, by preventing generation of active plasmin-STAR complex. Fibrin stimulates plasminogen activation by STAR via mechanisms involving the lysine- binding sites of plasminogen, probably by facilitating the generation of plasmin-STAR complex and by delaying its inhibition at the clot surface.     

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.     

Mini-plasminogen: a mechanism for leukocyte modulation of plasminogen activation by urokinase

Urokinase activation of blood fibrinolysis involves polymorphonuclear leukocytes. To determine if a leukocyte proteinase can modulate plasminogen activation, plasminogen was digested with leukocyte elastase. A major product was a small, approximately 34,000 dalton fragment (mini-plasminogen), without lysine-binding function, but with fibrin-binding activity. After urokinase activation, the resulting mini- plasmin had amidolytic activity for a tripeptide plasmin substrate and fibrinolytic activity. By 125I-fibrin assay, activities of mini-plasmin and plasmin (12 nmole/liter) were 38 and 20 ng fibrin lysed/min, respectively. Lysis times of fibrin clots containing urokinase, and mini-plasminogen or plasminogen (800 nmole/liter), were 282 and 290 sec, respectively. Mini-plasmin and plasmin were inhibited similarly by epsilon-aminocaproic acid and normal plasma, but differed in responses to gel filtration fractions of plasma containing alpha 2-antiplasmin and alpha 2-macroglobulin, the primary and secondary plasmin inhibitors. With purified inhibitors, mini-plasmin required higher concentrations of, or longer preincubation with, alpha 2-antiplasmin, and lower concentrations of, or shorter preincubation with, alpha 2- macroglobulin, to produce inhibition equivalent to that observed with plasmin. Leukocyte elastase digests plasminogen to generate a mini- plasminogen which, when activated by urokinase, has a novel pattern of response to the major plasmin inhibitors in plasma.     

Activation of the fibrinolytic system during intracoronary streptokinase administration

Serial biochemical studies were performed in 12 patients treated with intracoronary streptokinase infusion for acute myocardial infarction, in order to study the method of activation of the fibrinolytic system during local administration of a relatively low dose of this drug and to determine correlations between systemic effects and reperfusion. Plasma samples were obtained before and every 15 minutes during the infusion of streptokinase and after completion of the therapy. Streptokinase dosage in this study was 211,000 +/- 88,000 IU (+/- SD). The average time from the onset of symptoms to the start of infusion was 2 hours 50 minutes (range 1 hour 10 minutes to 3 hours 30 minutes). Reperfusion occurred in six patients and temporary recanalization in three; in three patients no recanalization was achieved. Fibrinolytic assays of pretreatment plasma samples revealed elevated levels of plasminogen activators, presumably caused by the release of tissue-type plasminogen activator after a condition of stress. Plasminogen concentrations decreased from 94 +/- 17% to 44 +/- 30%. Alpha 2-antiplasmin fell from 84 +/- 27% to 12 +/- 19%; in seven patients no plasmin inhibitor activity was measurable at the completion of the infusion. Free plasmin occurred in samples only when this inhibitor had disappeared. This resulted in a lytic state leading to degradation of fibrinogen, the levels of which fell from 2.9 +/- 0.7% to 1.5 +/- 1.1%. Fibrinogen degradation products, measured in plasma with monoclonal antibodies, increased exponentially during streptokinase infusion in at least four patients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fibrin monomer protects thrombin from inactivation by heparin-antithrombin III: implications for heparin efficacy.

Fibrin II monomer has a dramatic inhibitory effect on the rate of heparin-catalyzed inactivation of human alpha-thrombin by antithrombin III. At 6 microM fibrin II monomer, equivalent to the concentration of fibrinogen in plasma, the second-order rate constant was reduced by a factor of 308--from 2.05 x 10(8) M-1.s-1 to 6.65 x 10(5) M-1.s-1. Fibrin II monomer minimally affected the uncatalyzed rate of thrombin inactivation showing a reduction in the second-order rate constant by a factor of only 1.6. Fibrinogen and the product of plasmin degradation of fibrinogen, fragment E, at 6 microM concentrations also decreased the second-order rate constant for heparin-catalyzed thrombin inactivation, but by factors of only 2.7 and 1.9, respectively. On the basis of these observations it is proposed that protection of thrombin from inactivation by heparin-antithrombin III by fibrin II monomer can explain the limited efficacy of heparin in preventing coronary reocclusion in patients treated with tissue plasminogen activator and other fibrinolytic agents.     

Potential thrombolysis under selective infusion of autologous plasmin (AP) solution

Thrombolytic therapy with plasminogen activators, urokinase (UK) and streptokinase (SK), can produce serious complications such as systemic bleeding. We have developed an autologous plasmin (AP) solution as a new potential thrombolytic agent and evaluated its efficacy in animal experiments. The AP solution was prepared by the addition of UK to autologous plasma separated by centrifugation (4 degrees C, 3,000 rpm, 10 min). The plasmin activity in the AP solution was measured by the plasminogen-free fibrin plate method and spectrophotometric assay with the chromogenic substrate S-2251. In animal experiments, the femoral artery of anesthetized mongrel dogs (n = 20) was constricted by ligation (1 mm in diameter) and a fibrin clot was embolized into this site. Either AP solution (n = 8), UK solution (n = 6) or saline (n = 6) was selectively infused for 3 min. Prior to the infusion, a temporary flow obstruction was made by inflation of a balloon tip catheter located proximal to the embolized site. The thrombolytic effect was sequentially observed with an ultrasound flow meter for up to 60 min. The total dose of UK was 120,000 IU in both AP and UK solutions. The results showed that the plasmin activity of AP solution was maintained up to 90 min at 22 degrees C with an additional dose of more than 6,000 IU/ml of UK. In animal experiments, a restoration of the flow was observed more frequently with the AP solution than the UK solution within 15 min of the infusion (p less than 0.01). Thus, a high thrombolytic efficacy was observed with a selective infusion of rich, activated plasmin (AP) solution. This treatment could be applied as a new approach for arterial thrombolysis.