Ultrasonic clot disruption: an in vitro study

We studied in vitro the efficacy of ultrasound in human blood clot disruption, as well as the effects of clot age, wire probe length, and streptokinase on the outcome. The study included sizing the resulting particulate debris. Clot age (1 to 7 days) had no effect on the time required for disruption. Three groups of 1-day-old clots (n = 10 for each) were exposed to the same ultrasonic power source via probes of different lengths. The time required for clot disruption varied approximately as the square of the length for probes of 31, 56, and 105 cm, but was less than 3 minutes even for the longest probe employed. Disrupted whole-blood clot as well as cell-free fibrin clot solutions were analyzed for particulates by the resistive-pulse technique (size range: 2.5 to 80 microns). Debris as large as 80 microns were seen after disruption of whole blood clots, while cell-free fibrin clots contributed little above 40 microns. In all size ranges, whole blood clots produced two orders of magnitude more particulates than cell-free fibrin clots. Addition of streptokinase (7500 U/mL) had little effect on the size distribution of debris, with 99% of all particulates being smaller than 10 microns. D-dimer analysis was performed on the dissolved cell-free fibrin clots with and without streptokinase. While the former had analytically higher D-dimer concentrations than the latter (from eight- to 16-fold), the levels in both cases would be below detectability if measured in vivo. Hence the present study supports the concept that ultrasound can be employed to disrupt human blood clots by mechanisms (mechanical and cavitational) other than fibrinolysis.     

Ultrasound enhancement of thrombolytic therapy: observations and mechanisms

Fibrinolytic therapy is a proven approach for achieving reperfusion of occluded coronary arteries during myocardial infarction, resulting in reduced mortality and preservation of ventricular function. The amount of myocardial muscle loss is proportional to the duration of ischemia. Bleeding complications are not infrequent. Adjuvant therapy by ultrasound might enhance the rate of fibrinolysis and reduce the concentrations of lytic agents required to achieve an equivalent degree of clot lysis. ties and high frequencies, parameters that potentially could be applied and tolerated in vivo, have been proven to significantly accelerate the rate of fibrinolysis in both in vitro and in vivo models, in pure fibrin as well as whole blood clots. Such enhancement is not drug-specific. These effects were achieved by nonthermal mechanism. Ultrasound exposure did not cause mechanical fragmentation of the clot, did not alter the size of plasmatic derivates and degradation products. Ultrasound caused increased flow rate through thrombi, probably by cavitation-induced changes in fibrin ultrastructure; disaggregation of uncrosslinked fibrin fibers into smaller fibers has been shown. This resulted in increased trans-Noninvasive ultrasound at low intensi- port of the lytic agent into the clot, alteration of binding affinity and increased maximum binding. Presence of echo-contrast agent induced further acceleration of thrombolysis by ultrasound. (Int J Cardiovasc Intervent 2000; 3: 81-89)     

Aβ delays fibrin clot lysis by altering fibrin structure and attenuating plasminogen binding to fibrin

Alzheimer disease is characterized by the presence of increased levels of the β-amyloid peptide (Aβ) in the brain parenchyma and cerebral blood vessels. This accumulated Aβ can bind to fibrin(ogen) and render fibrin clots more resistant to degradation. Here, we demonstrate that Aβ(42) specifically binds to fibrin and induces a tighter fibrin network characterized by thinner fibers and increased resistance to lysis. However, Aβ(42)-induced structural changes cannot be the sole mechanism of delayed lysis because Aβ overlaid on normal preformed clots also binds to fibrin and delays lysis without altering clot structure. In this regard, we show that Aβ interferes with the binding of plasminogen to fibrin, which could impair plasmin generation and fibrin degradation. Indeed, plasmin generation by tissue plasminogen activator (tPA), but not streptokinase, is slowed in fibrin clots containing Aβ(42), and clot lysis by plasmin, but not trypsin, is delayed. Notably, plasmin and tPA activities, as well as tPA-dependent generation of plasmin in solution, are not decreased in the presence of Aβ(42). Our results indicate the existence of 2 mechanisms of Aβ(42) involvement in delayed fibrinolysis: (1) through the induction of a tighter fibrin network composed of thinner fibers, and (2) through inhibition of plasmin(ogen)-fibrin binding.     

An Analysis of Mechanisms Underlying the Antifibrinolytic Properties of Radiographic Contrast Agents

Background: Radiographic contrast agents inhibit fibrinolysis, although by poorly defined pathways. The purpose of this study was to define specific mechanisms by which contrast agents inhibit clot lysis. Methods and Results: Diatrizoate (high osmolar ionic agent), ioxaglate (low osmolar ionic), and ioversol (nonionic) were studied in vitro. Diatrizoate inhibited clot lysis by 81.3±0.6% vs. control (p<0.001). Ioxaglate inhibited clot lysis by 41.7±11.9%, which was of borderline significance (p=0.07). Ioversol did not significantly inhibit clot lysis (14.9±11.5% decrease vs. control; p>0.3). Inhibition of fibrinolysis was not explained by the high osmolarities of contrast agents, by their iodine content, or by their effects on the amidolytic activities of t-PA, urokinase, or plasmin. However, plasminogen activation by t-PA, urokinase, or streptokinase was significantly inhibited by contrast agents. Diatrizoate, ioxaglate, and ioversol inhibited plasminogen binding to plasma clots by 51±4% (p<0.001), 30.1±4% (p<0.01), and 19.4±7% (p=0.07), respectively. Plasma clots formed in the presence of contrast agents were resistant to lysis by plasmin. Diatrizoate produced the most potent effect, inhibiting clot lysis by 40±5.7% (p<0.03). Contrast agents did not inhibit plasminogen binding to fibrin or plasmin-mediated fibrinolysis if they were added after clot formation. Contrast agents altered clot turbidity, an index of fibrin structure, if present during clot formation, but not if added to preformed clots. Contrast agents did not affect plasminogen activator inhibitor-1 or ₂-antiplasmin function. Conclusions: Contrast agents inhibit clot lysis by inhibiting plasminogen activation and by disrupting interactions of plasminogen and plasmin with fibrin by altering fibrin structure. Significant variation in antifibrinolytic properties exists between different contrast agents. Abbreviated Abstract. The purpose of this study was to define specific mechanisms by which contrast agents inhibit clot lysis. In both a purified clot lysis system and a plasma clot lysis system, diatrizoate, an ionic agent, produced the most potent inhibition of fibrinolysis. Contrast agents did not inhibit the active sites of plasminogen activators or plasmin, but did inhibit plasminogen activation. Binding of plasminogen to fibrin and lysis of fibrin by plasmin were inhibited by contrast agents if they were present during clot formation, but not if they were added after clot formation was complete. Contrast agents altered clot turbidity, an index of fibrin structure, if present during clot formation, but not if added to preformed clots. Contrast agents did not affect plasminogen activator inhibitor-1 or ₂-antiplasmin function. The effects of contrast agents on fibrinolytic parameters were not explained by their high osmolarities. These results suggest that contrast agents inhibit clot lysis by inhibiting plasminogen activation and by disrupting interactions of plasminogen and plasmin with fibrin by altering fibrin structure.     

Whole blood clot lysis in newborns and adults after adding different concentrations of recombinant tissue plasminogen activator (Rt-PA)

Optimal treatment of newborns with thromboembolic complications likely differs from that for adults because of ontogenetic features of both coagulation and fibrinolysis that affect the thrombotic processes and the response to thrombolytic agents. Although there are data on plasma clot lysis in newborns, the potential for dissolution of whole blood clots has not been explored. We investigated whether there is a difference between newborns and adults in sensitivity of whole blood clots to lysis with recombinant tissue plasminogen activator (rt-PA). Blood was obtained from 15 newborns and from 13 adults and anticoagulated with sodium citrate. Whole blood clots were generated by addition of thrombin and calcium. After 3 hours of retraction the clots were put into tubes containing 1.45 mL plasma of the same patient. After 1 hour of incubation, rt-PA was added to result in final concentrations of 3, 1, 0.3, 0.1, and 0 microg/mL. Clots were weighed after 0.5, 1, 2, and 3 hours. At any time point measured, whole blood clot lysis was more efficient in newborns than it was in adults. This was true for spontaneous clot lysis (p <0.05 at 1, 2, and 3 hours) as well as for all concentrations of rt-PA tested (p <0.05 at 1 hour). Whole blood clot lysis in new-borns was most efficient at 1 microg/mL rt-PA, whereas adults showed best lysis at the highest concentration tested (3 microg/mL rt-PA). The rate of plasminogen consumption was similar in newborns and adults. Recommendations for antithrombotic therapy in new-borns have been loosely extrapolated from recommendations for adults. Our data can be helpful in establishing guidelines for thrombolytic therapy in the neonatal period. Retracted whole blood clots mimic better the in vivo situation than previously reported in studies of lysis of nonretracted plasma clots. Based on our data, we think that despite low levels and slower activation kinetics of fetal plasminogen, the dosage of rt-PA should be lower in newborns than in adults.     

The cofactor role of protein S in the acceleration of whole blood clot lysis by activated protein C in vitro

The effect of purified human activated protein C (APC) and protein S on fibrinolysis was studied by using an in vitro blood clot lysis technique. Blood clots were formed from citrated blood (supplemented with 125I-fibrinogen) by adding thrombin and Ca2+-ions; lysis of the clots was achieved by adding tissue-type plasminogen activator. The release of labeled fibrin degradation products from the clots into the supernatant was followed in time. We clearly demonstrated that APC accelerates whole blood clot lysis in vitro. The effect of APC was completely quenched by antiprotein C IgG, pretreatment of APC with diisopropylfluorophosphate, and preincubation of the blood with antiprotein S IgG. This demonstrates that both the active site of APC and the presence of the cofactor, protein S, are essential for the expression of the profibrinolytic properties. At present, the substrate of APC involved in the regulation of fibrinolysis is not yet known. Analysis of the radiolabeled fibrin degradation products demonstrated that APC had no effect on the fibrin cross-linking capacity of factor XIII.     

Direct action on the molecule is one of several mechanisms by which ultrasound enhances the fibrinolytic effects of reteplase.

Enhanced fibrinolytic reperfusion therapy may improve the outcome in embolic stroke, where ultrasound exposure has been shown to be one option. We recently verified that the fibrinolytic properties of streptokinase were modulated following ultrasound exposure of the molecule. We have now explored this possibility following ultrasound exposure of the reteplase molecule. The effects on clot lysis of reteplase and ultrasound both separately and in combination were studied by evaluating cumulated release of haemoglobin from whole blood clots following 1 h of exposure. Specifically, we investigated how clot lysis was modulated following pulsed 1 MHz ultrasound pre-exposure of the reteplase solution at intensities ranging between 0.125 and 4 W/cm2 spatial-average temporal-average intensity (SATA) and the effects of reteplase following 1 h of pre-exposure of clots to ultrasound at high intensity (4 W/cm2SATA). Significant enhancement of clot lysis during concomitant reteplase and pulsed ultrasound exposure were observed in two intensity ranges: 0.125-0.25 and 2-4 W/cm2SATA. Pre-exposing reteplase solution to ultrasound significantly increased clot lysis only in the lower intensity range. At high ranges, pre-exposure of clots to ultrasound was followed by an increased fibrinolytic action of reteplase. Pre-exposing reteplase solution to low-intensity ultrasound induced changes in the reteplase molecule that enhanced its fibrinolytic effects. Although this effect disappeared at moderately higher ultrasound intensity, the pre-exposure of clots to ultrasound of higher intensity induced increased fibrinolytic effects of reteplase solution.     

Effect of ultrasound on tissue-type plasminogen activator-induced thrombolysis.

BACKGROUND. The efficacy of fibrinolytic therapy is limited by the small surface area of the clot that is available for the binding of the thrombolytic agent, such as tissue-type plasminogen activator (t-PA). We hypothesized that exposure of the clot to ultrasound during thrombolytic treatment could enhance lysis through perturbation of the thrombus, which would expose additional fibrin binding sites for t-PA. METHODS AND RESULTS. Whole human blood clots containing radiolabeled fibrinogen were incubated in vitro for 200 minutes with Tris-albumin buffer containing t-PA at concentrations ranging from 3 to 3,000 IU/ml. In paired experiments, one of the clots also was exposed to intermittent ultrasound (1 MHz, 1.75 W/cm2) throughout the experiment. The ultrasound was delivered as a 2-second exposure followed by a 2-second rest interval. The overall difference in mean clot lysis between thrombi receiving ultrasound and those receiving no ultrasound was significant (p less than 0.001) at all concentrations of t-PA. For clots incubated with t-PA at a concentration of 300 IU/ml, ultrasound increased the percent lysis at 200 minutes from 42 +/- 5% (mean +/- SEM) to 64 +/- 10%. In six paired experiments in a rabbit jugular vein thrombosis model, rabbits received 1 mg t-PA alone or t-PA and intermittent ultrasound (1 MHz, 1.75 W/cm2) for 200 minutes. For rabbits receiving ultrasound and t-PA, lysis was 55 +/- 11% at 100 minutes compared with 30 +/- 12% for rabbits receiving only t-PA. Lysis was 6 +/- 10% for rabbits (n = 4) receiving ultrasound alone. No evidence for tissue damage was noted in rabbits exposed to intermittent ultrasound. CONCLUSIONS. Exposure of whole blood clots in vitro to intermittent ultrasound combined with t-PA caused a significant enhancement of thrombolysis compared with t-PA alone. Intermittent ultrasound also showed a trend toward enhancement of t-PA-induced clot lysis in an animal thrombosis model. These data suggest that noninvasive intermittent ultrasound may be a useful adjunct to thrombolytic therapy.     

Platelets inhibit fibrinolysis in vitro by both plasminogen activator inhibitor-1-dependent and -independent mechanisms

Platelet-rich thrombi are resistant to lysis by tissue-type plasminogen activator (t-PA). Although platelet alpha-granules contain plasminogen activator inhibitor-1 (PAI-1), a fast-acting inhibitor of t-PA, the contribution of PAI-1 to the antifibrinolytic effect of platelets has remained a subject of controversy. We recently reported a patient with a homozygous mutation within the PAI-1 gene that results in complete loss of PAI-1 expression. Platelets from this individual constitute a unique reagent with which to probe the role of platelet PAI-1 in the regulation of fibrinolysis. The effects of PAI-1-deficient platelets were compared with those of normal platelets in an in vitro clot lysis assay. Although the incorporation of PAI-1-deficient platelets into clots resulted in a moderate inhibition of t-PA-mediated fibrinolysis, normal platelets markedly inhibited clot lysis under the same conditions. However, no difference between PAI-1-deficient platelets and platelets with normal PAI-1 content was observed when streptokinase or a PAI-1-resistant t-PA mutant were used to initiate fibrinolysis. In addition, PAI-1-resistant t-PA was significantly more efficient in lysing clots containing normal platelets than wild-type t-PA. We conclude that platelets inhibit t-PA-mediated fibrinolysis by both PAI- 1-dependent and PAI-1-independent mechanisms. These results have important implications for the role of PAI-1 in the resistance of platelet-rich thrombi to lysis in vivo.     

Plasminogen activator inhibitor-1 suppresses endogenous fibrinolysis in a canine model of pulmonary embolism

BACKGROUND. Plasminogen activator inhibitor-1 (PAI-1), the specific, fast-acting inhibitor of tissue-type plasminogen activator (t-PA), binds to fibrin and has been found in high concentrations within arterial thrombi. These findings suggest that the localization of PAI-1 to a thrombus protects that same thrombus from fibrinolysis. In this study, clot-bound PAI-1 was assessed for its ability to suppress clot lysis in vivo. METHODS AND RESULTS. Autologous, canine whole blood clots were formed in the presence of increasing amounts of activated PAI-1 (0-30 micrograms/ml). Approximately 6-8% of the PAI-1 bound to the clots under the experimental conditions. Control and PAI-1-enriched clots containing iodine-125-labeled fibrin (ogen) were homogenized, washed to remove nonbound elements, and delivered to the lungs of anesthetized dogs where the homogenates subsequently underwent lysis by the endogeneous fibrinolytic system. 125I-labeled fibrin degradation products appeared in the blood of control animals within 10 minutes and were maximal by 90 minutes. PAI-1 reduced fibrin degradation product release in a dose-responsive manner at all times between 30 minutes and 5 hours (greater than or equal to 76% inhibition at 30 minutes, PAI-1 greater than or equal to 6 micrograms/ml). PAI-1 also suppressed D-dimer release from clots containing small amounts of human fibrin (ogen). t-PA administration attenuated the effects of PAI-1, whereas latent PAI-1 (20 micrograms/ml) had no effect on clot lysis. Blood levels of PA and PAI activity remained unaltered during these experiments. CONCLUSIONS. The results indicate that PAI-1 markedly inhibits endogenous fibrinolysis in vivo and, moreover, suggest that the localization of PAI-1 to a forming thrombus is an important physiological mechanism for subsequent thrombus stabilization.     

Influence of fibrin network conformation and fibrin fiber diameter on fibrinolysis speed: dynamic and structural approaches by confocal microscopy

Abnormal fibrin architecture is thought to be a determinant factor of hypofibrinolysis. However, because of the lack of structural knowledge of the process of fibrin digestion, relationships between fibrin architecture and hypofibrinolysis remain controversial. To elucidate further structural and dynamic changes occurring during fibrinolysis, cross-linked plasma fibrin was labeled with colloidal gold particles, and fibrinolysis was followed by confocal microscopy. Morphological changes were characterized at fibrin network and fiber levels. The observation of a progressive disaggregation of the fibrin fibers emphasizes that fibrinolysis proceeds by transverse cutting rather than by progressive cleavage uniformly around the fiber. Plasma fibrin clots with a tight fibrin conformation made of thin fibers were dissolved at a slower rate than those with a loose fibrin conformation made of thicker (coarse) fibers, although the overall fibrin content remained constant. Unexpectedly, thin fibers were cleaved at a faster rate than thick ones. A dynamic study of FITC-recombinant tissue plasminogen activator distribution within the fibrin matrix during the course of fibrinolysis showed that the binding front was broader in coarse fibrin clots and moved more rapidly than that of fine plasma fibrin clots. These dynamic and structural approaches to fibrin digestion at the network and the fiber levels reveal aspects of the physical process of clot lysis. Furthermore, these results provide a clear explanation for the hypofibrinolysis related to a defective fibrin architecture as described in venous thromboembolism and in premature coronary artery disease.     

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.     

Synergistic fibrinolysis: combined effects of plasminogen activators and an antibody that inhibits alpha 2-antiplasmin.

To improve the efficacy of plasminogen activators, we produced a monoclonal antibody (RWR) that inhibits human alpha 2-antiplasmin (alpha 2AP). In addition to inhibiting alpha 2AP in plasma, RWR binds to and inhibits fibrin cross-linked alpha 2AP and reproduces the "spontaneous" clot lysis that is the hallmark of human alpha 2AP deficiency. By inhibiting the inactivation of plasmin by alpha 2AP, RWR interacts synergistically with plasminogen activators to increase the potency (for 50% clot lysis) of urokinase by 80-fold, tissue plasminogen activator by 27-fold, and streptokinase by 20-fold. Yet, for a given amount of fibrinolysis, the combination of RWR and lower doses of plasminogen activator leads to less fibrinogen consumption than is obtained with higher, equipotent doses of plasminogen activator alone. These results suggest a strategy for increasing the efficacy of plasminogen activators. More generally, this approach to amplifying enzymatic activity by immunoneutralizing an inhibitor may be useful in other biologic processes that are rigidly governed by inhibitors.     

A novel simultaneous clot-fibrinolysis waveform analysis for assessing fibrin formation and clot lysis in haemorrhagic disorders

Simultaneous evaluation of coagulation and fibrinolysis facilitates an overall understanding of normal and pathological haemostasis. We established an assay for assessing clot formation and fibrinolysis simultaneously using clot waveform analysis by the trigger of a mixture of activated partial thromboplastin time reagent and an optimized concentration of tissue-type plasminogen activator (0·63 μg/ml) to examine the temporal reactions in a short monitoring time (<500 s). The interplay between clot formation and fibrinolysis was confirmed by analysing the effects of argatroban, tranexamic acid and thrombomodulin. Fibrinogen levels positively correlated with coagulation and fibrinolytic potential and initial fibrin clot formation was independent of plasminogen concentration. Plasminogen activator inhibitor-1-deficient (-def) and α2-antiplasmin-def plasmas demonstrated different characteristic hyper-fibrinolytic patterns. For the specificity of individual clotting factor-def plasmas, factor (F)VIII-def and FIX-def plasmas in particular demonstrated shortened fibrinolysis lag-times (FLT) and enhanced endogenous fibrinolysis potential in addition to decreased maximum coagulation velocity, possibly reflecting the fragile formation of fibrin clots. Tranexamic acid depressed fibrinolysis to a similar extent in FVIII-def and FIX-def plasmas. We concluded that the clot-fibrinolysis waveform analysis technique could sensitively monitor both sides of fibrin clot formation and fibrinolysis, and could provide an easy-to-use assay to help clarify the underlying pathogenesis of bleeding disorders in routine clinical practice.     

Uncoupling fibrin from integrin receptors hastens fibrinolysis at the platelet-fibrin interface

A well-characterized in vitro model system composed of thrombin- stimulated gel-filtered human platelets, fibrin-(ogen), plasminogen, and recombinant tissue plasminogen activator (rt-PA) was used to examine the relationship between platelet-fibrin adhesive interactions and the lytic resistance of a platelet-rich thrombus. Laser light scattering kinetic experiments demonstrated that the ligand-mimetic peptide D-RGDW and an anti-alpha IIb beta 3 monoclonal antibody both inhibited clot retraction, but neither integrin-targeted reagent affected the overall delay in lysis of "bulk" fibrin caused by thrombin- stimulated platelets. However, lysis of the model platelet-rich thrombus did proceed some 30% more quickly when treated with a plasminogen activator inhibitor (PAI)-resistant t-PA variant. Taken together, these results confirm that platelet-released PAI-1 is a major determinant of global lytic resistance. Next events occurring during fibrinolysis in the unique microenvironment near the platelet surface were monitored by scanning electron microscopy and quantitative fluorescence microscopy. Scanning electron micrographs of the partially lysed model thrombus in the presence of 200 mumol/L of D-RGDW showed no platelet aggregates, and fibrin was attached by fewer strands to the platelets. Quantitative fluorescence microscopy, using fluorescein- labeled fibrin, showed that fibrin adherent to the surface of thrombin- stimulated platelets lysed 20% to 50% more slowly than bulk fibrin (monitored in parallel by laser light scattering). Furthermore, this microspectroscopic technique showed that D-RGDW reduced the quantity of platelet-bound fibrin, and accelerated lysis near the platelet surface with both native rt-PA and the PAI-resistant variant. These observations suggest that the dense network of fibrin bound to the platelet surface is protected from fibrinolysis by tissue-type plasminogen activators. Further, uncoupling fibrin from its platelet receptors uniquely hastens fibrinolysis at the cell/fibrin interface.     

The influence of fibrin crosslinking on the kinetics of urokinase-induced clot lysis

Summary . The effect of fibrin crosslinking on the lysis of plasma clots was investigated with plasma from a patient congenitally deficient in plasma factor XIII (fibrin stabilizing factor). The thrombin-activated plasma factor XIII was found to render clots more resistant to fibrinolysis when urokinase (UK) was used to induce plasminogen activation. Incorporation of UK in the clot by addition to plasma immediately before clotting resulted in a log-log relationship when lysis time was plotted against UK concentration, with greater differences between normal and factor-XIII deficient clots at lower UK concentrations. Addition of UK to the clot externally, after preincubation of the clot, gave linear plots on rectangular coordinates when either plasma or euglobulin fraction was used; and the difference in lysis time between factor-XIII deficient and normal clots was nearly constant over the range of UK concentrations tested. When the fluorescent amine, dansylcadaverine, was used to measure factor-XIII activity quantitatively, plasma clot lysis times were found to be directly proportional to amine-incorporating activity over a wide range of activities at low UK concentrations. The range of proportionality was reduced when UK concentration was increased. Addition of purified factor XIII to the patient's plasma restored the resistance of these clots to within the normal range.     

Prevention of coronary thrombosis with subthrombolytic doses of tissue-type plasminogen activator

To determine whether tissue-type plasminogen activator (t-PA) may prevent coronary thrombosis or accelerate the lysis of clot formed under conditions in which increased concentration of the activator is present before thrombosis, clot lysis studies were undertaken in vitro and in vivo. In vitro, exogenous t-PA (6 to 100,000 ng/ml) accelerated the lysis of clot in a dose-dependent fashion when the clot was formed either from whole plasma or from euglobulin fractions (n = 316 determinations). Adding t-PA before clot formation shortened the time to lysis by at least threefold with euglobulin fractions and by at least 10-fold with whole plasma clots, which is consistent with the presence of inhibitors of fibrinolysis in whole plasma and with the binding of t-PA to nascent fibrin. In an intact dog preparation of coronary thrombosis (n = 25), occlusive thrombus formation was prevented when t-PA was present in subthrombolytic concentrations (430 to 1200 ng/ml, n = 5). Occlusive thrombus formation occurred after only discontinuation of the t-PA infusion and clearance of t-PA. Lower concentrations of t-PA (147 to 427 ng/ml, n = 6) significantly delayed occlusion (26 +/- 6.5 vs 7.8 +/- 2.8 min for controls). In animals with t-PA concentrations of less than 140 ng/ml (n = 4), the time to occlusion was unaltered (7.7 +/- 4.5 min). The present study demonstrates that t-PA present before clot formation inhibits thrombosis or accelerates thrombolysis depending on concentration, and that subthrombolytic doses of t-PA can prevent thrombus formation in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thrombolytic versus fibrinogenolytic activity of rt-PA and streptokinase in patients with acute myocardial infarction

In this study the concentration of plasma breakdown products of cross-linked fibrin (XDP), serum fibrinogen-fibrin degradation products (FDP), and plasma fibrinogen were measured before and at the end of the administration of single-chain recombinant tissue-type plasminogen activator (rt-PA, 100 mg IV over three hours) or streptokinase (1.5 million units over one hour), respectively, in two groups, each composed of 22 patients with acute myocardial infarction. The XDP concentration was not statistically different between the two groups at the end of thrombolytic treatment, whereas FDP and fibrinogen concentrations were significantly different (FDP: streptokinase 396 +/- 287 vs rt-PA 177 +/- 222 micrograms/mL, p less than 0.01; fibrinogen: streptokinase 71 +/- 43 vs rt-PA 181 +/- 49 mg/dL, p less than 0.001). These results indicate that the two drugs have equipotent thrombolytic activity at this administration regimen but that rt-PA causes a markedly more selective lysis of fibrin in comparison with streptokinase.     

Polyphosphate enhances fibrin clot structure

Polyphosphate, a linear polymer of inorganic phosphate, is present in platelet dense granules and is secreted on platelet activation. We recently reported that polyphosphate is a potent hemostatic regulator, serving to activate the contact pathway of blood clotting and accelerate factor V activation. Because polyphosphate did not alter thrombin clotting times, it appeared to exert all its procoagulant actions upstream of thrombin. We now report that polyphosphate enhances fibrin clot structure in a calcium-dependent manner. Fibrin clots formed in the presence of polyphosphate had up to 3-fold higher turbidity, had higher mass-length ratios, and exhibited thicker fibers in scanning electron micrographs. The ability of polyphosphate to enhance fibrin clot turbidity was independent of factor XIIIa activity. When plasmin or a combination of plasminogen and tissue plasminogen activators were included in clotting reactions, fibrin clots formed in the presence of polyphosphate exhibited prolonged clot lysis times. Release of polyphosphate from activated platelets or infectious microorganisms may play an important role in modulating fibrin clot structure and increasing its resistance to fibrinolysis. Polyphosphate may also be useful in enhancing the structure of surgical fibrin sealants.     

A faster-acting and more potent form of tissue plasminogen activator.

Current treatment with tissue plasminogen activator (tPA) requires an intravenous infusion (1.5-3 h) because the clearance of tPA from the circulation is rapid (t 1/2 approximately 6 min). We have developed a tPA variant, T103N,N117Q, KHRR(296-299)AAAA (TNK-tPA) that has substantially slower in vivo clearance (1.9 vs. 16.1 ml per min per kg for tPA in rabbits) and near-normal fibrin binding and plasma clot lysis activity (87% and 82% compared with wild-type tPA). TNK-tPA exhibits 80-fold higher resistance to plasminogen activator inhibitor 1 than tPA and 14-fold enhanced relative fibrin specificity. In vitro, TNK-tPA is 10-fold more effective at conserving fibrinogen in plasma compared to tPA. Arterial venous shunt models of fibrinolysis in rabbits indicate that TNK-tPA (by bolus) induces 50% lysis in one-third the time required by tPA (by infusion). TNK-tPA is 8- and 13-fold more potent in rabbits than tPA toward whole blood clots and platelet-enriched clots, respectively. TNK-tPA conserves fibrinogen and, because of its slower clearance and normal clot lysis activity, is effective as a thrombolytic agent when given as a bolus at a relatively low dose.