Influence of the surface on thrombin generation.

Thrombin generation depends on the surface of the blood vessel or container. With a new ultra-sensitive and -specific thrombin assay the surface-dependent thrombin generation was quantified. Citrated blood or plasma was preincubated for 1 h (37 degrees C). Citrated blood, plasma, or plasma with 0-10 g/l hemoglobin-erythrocyte microparticles (Hb-MP) were preincubated at 23 degrees C or at 37 degrees C. Plasma samples (50 microl) were recalcified in polystyrol (PS) wells and incubated for different coagulation reaction times (CRT). Final supramolar arginine concentrations, 0.1% Triton X 100, and chromogenic thrombin substrate concentrations in the onefold km-range were added and the linear DeltaA/t was measured in the recalcified coagulation activity assay (RECA). Aprotinin or corn trypsin inhibitor were added. (i) Recalcification of plasma (in different monovettes) pre-incubated for 1 h (37 degrees C) generated the following thrombin activities after 7 min (37 degrees C): 0.74 IU/ml (polypropylene (PP)-citrate), 0.39 IU/ml (PP-EDTA), 0.06 IU/ml (PP-heparin), 1.38 IU/ml (PS), 0.63 IU/ml (1 ml volume PP), 0.13 IU/ml (15 ml volume PP), and 3.62 IU/ml (glass). (ii) Recalcification of preincubated whole blood generated up to about fivefold more thrombin. (iii) Thrombin generation is proportional to the plasmatic concentration of Hb-MP, 10 g/l Hb-MP generating about 4 IU/ml thrombin within 20 min CRT. (iv) The IC50 of aprotinin and corn typsin inhibitor on thrombin generation in RECA are about 2 KIU/ml and about 1 U/ml, respectively. The reaction wall, the preincubation temperature, and hemolysis influences thrombin generation. The RECA allows to diagnose the prothrombotic capacity of any material.

Specific determination of plasmatic thrombin activity.

Thrombin is the key enzyme of coagulation. Its activity can be determined via fibrinogen Ø fibrin conversion or via cleavage of a chromogenic substrate. The latter method is easier than the first one, but in plasma it is hampered due to unspecific cleavage of the chromogenic substrate by thrombin-like enzymes of hemostasis, especially those of the contact phase. The concentration of the thrombin substrate (HD-CHG-Ala-Arg-pNA) was optimized, using final substrate concentrations of 0 to 5 mM, a final arginine concentration of 1.13 M, and samples of 10 mIU/mL purified thrombin in 7% human albumin or pooled normal citrated plasma without and with EDTA. Twenty microliters pooled normal citrated plasma (frozen/thawed) or factor II-deficient plasma (lyophilized) were incubated with 10 microL 0% to 0.5% Thromborel S (100% = 162 ng/mL tissue factor [TF]) in 6% BSA or with 10 microL 0% (physiol. NaCl) to 50% Pathromtin SL and with 20 microL 25 mM CaCl(2). After 0 to 22 minutes (37 degrees C), 20 microL 1.7 M arginine, pH 8.7 were added. Fifteen microliters 0.9 mM HD-CHGAla-Arg-pNA in 2.3 M arginine, pH 8.6, were added and the increase in absorbance (deltaA) at 405 nm was determined. Thrombin activity was standardized against the (3)A measured for 1 IU/mL thrombin in 7% human albumin (8.8 mA/min RT). The optimal final chromogenic substrate concentration to detect thrombin in this assay system is less than 0.6 mM. Higher substrate concentrations in a plasma milieu result in unspecific cleavage of the substrate. Using final concentrations of chromogenic substrate less than 0.4 mM (the approximate Km- value for thrombin) and final concentrations of arginine greater than 800 mM, in factor II-depleted plasma, when activated either by TF or by the contact phase, there is no significant thrombin generation. The circulating thrombin activity measured in EDTA plasma of 39 healthy donors is 100 +/- 20% of norm (mean value +/- 1 SD; 100% = 5.5 mIU/mL thrombin). This chromogenic assay detects thrombin activity independent of clotting seconds or fibrin mediated turbidity increases. This technique allows to standardize the thrombin activity generated in any biologic system in international thrombin units.

Thrombin generation by exposure of blood to endotoxin: a simple model to study disseminated intravascular coagulation.

Pathologic disseminated intravascular coagulation (PDIC) is a serious complication in sepsis. In an in-vitro system consisting of incubation of fresh citrated blood with lipopolysaccharides (LPS) or glucans and subsequent plasma recalcification plasmatic thrombin was quantified. Five hundred microliters of freshly drawn citrated blood of healthy donors were incubated with up to 800 ng/mL LPS (Escherichia coli) or up to 80 microg/mL Zymosan A (ZyA; Candida albicans) for 30 minutes at room temperature (RT). The samples were centrifuged, and 30 microL plasma were recalcified with 1 volume or less of CaCl(2) (25 micromoles Ca(2+)/mL plasma). After 0 to 12 minutes (37 degrees C), 20 microL 2.5 M arginine, pH 8.6, were added. Thirty microliters 0.9 mM HD-CHG-Ala-Arg-pNA in 2.3 M arginine were added, and the absorbance increase at 405 nm was determined. Fifty microliters plasma were also incubated with 5 microL 250 mM CaCl2 for 5, 10, or 15 minutes (37 degrees C). Fifty microliters 2.5 M arginine stops coagulation, and 50 microL 0.77 mM HD-CHG-Ala-Arg-pNA in 2.3 M arginine starts the thrombin detection. The standard was 1 IU/mL thrombin in 7% human albumin instead of plasma. Arginine was also added in the endotoxin exposure time (EET) or in the plasma coagulation reaction time (CRT). Tissue factor (TF)-antigen and soluble CD14 were determined. LPS at blood concentrations greater than 10 ng/mL or ZyA at greater than 1 microg/mL severalfold enhance thrombin generation, when the respective plasmas are recalcified. After 30 minutes EET at RT, the thrombin activity at 12 minutes CRT generated by the addition of 200 ng/mL LPS or 20 microg/mL ZyA is approximately 200 mIU/mL compared to approximately 20 mIU/mL without addition of endotoxin, or compared to about 7 mIU/mL thrombin at 0 minutes CRT. Arginine added to blood or to plasma inhibits thrombin generation; the inhibitory concentration 50% (IC 50) is approximately 15 mM plasma concentration. Endotoxin incubation of blood increases neither TF nor sCD14. This assay allows the study of the hemostasis alteration in PDIC, particularly in PDIC by sepsis. The thrombin generated by blood plus endotoxin incubation and plasma recalcification suggests that the contact phase of coagulation; e.g., triggered by cell components of (phospholipase-) lysed cells such as monocyte or endothelium DNA or phospholipid-vesicles (microparticles), is of primary pathologic importance in sepsis-PDIC. Arginine at plasma concentrations of 10 to 50 mM might be a new therapeutic for sepsis-PDIC.

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.

Functional determination of plasmin in arginine-stabilized plasma.

Reliable data on plasmin activities in blood of patients during fibrinolytic treatment are lacking. This is due to continuing plasminogen activation by plasminogen activators after blood withdrawal. The purpose of this study was to establish a new method for stabilization of blood and to detect plasmin activity in stabilized plasma. For optimization of plasma stabilization by arginine, 50 microL pooled normal citrated plasma was incubated with 50 microL of 0 to 1500 mM arginine, pH 8.7, and 25 microL 100 IU/mL u-PA, 1250 IU/mL t-PA, 10000 U/mL reteplase, 400 U/mL plasminogen-streptokinase-activator complex, 10 microg/mL tenecteplase in 6% BSA-PBS or 25 microL 25 microg/mL plasmin in 20% glycerol. Twenty-five microliters 3 mM HD-Val-Leu-Lys-pNA were added immediately (1 step) or after 90 minutes (room temperature [RT]). The same experiment was performed with pooled normal citrated plasma supplemented with 3.2 mg/mL EDTA, preoxidized with 0 mM or 20 mM chloramine-T for 10 minutes (37 degrees C). For optimization of plasmin activity, the oxidation time of the arginine-stabilized plasma sample containing 0.5 U/mL active plasmin and the chloramine-T amount was varied. Citrated plasma is stabilized against the in vitro action of all six plasminogen activators tested if the final arginine concentration is greater than 500 mM. Neither the addition of EDTA nor the addition of chloramine-T changes this plasma-stabilizing power of arginine. The optimized functional plasmin assay consists of incubation of 10 microL arginine-stabilized plasma with 10 microL 1.5 M arginine, pH 8.7, and 10 microL 100 mM CT in PBS. After 30 minutes (37 degrees C), 75 microL 1.2 M KCl, 1.6 M Arg, 0.75 mM Val-Leu-Lys-pNA (Stop-CS Reagent), and 175 microL 6% BSA-PBS are added and the absorbance increase (DeltaA) at 405 nm is determined. With the present arginine stabilization procedure of plasma and the determination of plasmin activity in arginine-stabilized plasma as described, it is feasible to determine the activity of plasmin in blood of patients receiving fibrinolytic treatment without artefactual in vitro changes in the samples.

Functional determination of plasminogen activator in arginine-stabilized plasma.

Reliable data on plasminogen activator (PA) activities in blood of patients receiving fibrinolytic treatment are lacking. This is due to the continuing in vitro action of PA after blood withdrawal. We have elaborated a new simple stabilization technique for plasma involving the addition of arginine in final concentrations greater than 500 mM. In this study, new assays for PA in stabilized plasma are developed. The assay was performed with substrate plasma, that is, pooled normal plasma, preoxidized with chloramine-T; oxidant amount and oxidation time were optimized. The chloramine consumption by plasma was assayed with a KJ-assay (absorbance increase at 405 nm by addition of 200 microL 4 M KJ to 25 microL oxidized plasma). The substrate plasma concentration in the PA assay and the PA acting time was optimized. The inhibition of PA by the cations Na(+), K(+), Mg(2+), and Ca(2+) was evaluated. The optimized PA assay consists of incubation of 10 microL arginine-stabilized plasma with 10 microL 1.5 M arginine, pH 8.7 and 10 microL 100 mM CT in PBS. After 30 minutes (37 degrees C), 175 microL 15 mM CT oxidized EDTA plasma are added. After 40 minutes (37 degrees C), 75 microL Stop-CS Reagent is added and DeltaA at 405 nm was determined, giving PA + plasmin activity in plasma. A control value (basal plasmin activity) consists of the addition of Stop-CS Reagent before 175 microL oxidized EDTA plasma. To obtain plasmatic PA activity, the control value has to be subtracted from the PA main value. The assay is matrix-independent and linear up to 1250 IU/mL t-PA, 790 U/mL reteplase, or 199 IU/mL u-PA (37 nM). With arginine stabilization of plasma and the described determination of plasminogen activator activity in arginine-stabilized plasma, it is feasible to determine the activity of plasminogen activators in blood of patients receiving fibrinolytic treatment without artefactual in vitro changes of the samples.

In vitro simulation of therapeutic plasmatic fibrinolysis.

One type of therapy for thromboembolism is plasmatic thrombolysis. Several plasminogen activators (PA) are clinically available, including urokinase (u-PA), tissue plasminogen activator (t-PA), streptokinase (SK), plasminogen-streptokinase-activator-complex (PSAC), or mutants of t-PA such as reteplase (RP) or tenecteplase (TP). Therapeutic plasmatic fibrinolysis was simulated, using the PA at relevant plasma concentrations, and plasmin (Pli) and PA activities were determined. Normal citrated plasma was supplemented with 31 to 1,000 IU/mL u-PA, 0.31 to 20 microg/mL t-PA, 125 to 4,000 IU/mL SK, 12.5 to 400 U/mL PSAC, 125 to 4,000 U/mL RP, or 0.31 to 10 microg/mL TP. Ten IU/mL urokinase was also incubated with pooled plasma of stroke patients, that was previously oxidized with the singlet oxygen (1O2) donor chloramine T (CT), to destroy plasmatic PAI-1 and alpha2-antiplasmin. After 0 to 80 minutes (37 degrees C), 50-microL samples were withdrawn and added to 100 microL 1.5 M arginine, pH 8.7, and oxidized with 50 microL of 20 mM CT. For determination of plasmin activity, 10 microL thereof was incubated with 150 microL 1.5 M arginine, pH 8.7, and 100 microL 20 mM CT preoxidized (15 minutes 37 degrees C) pooled normal citrate buffered EDTA-plasma for 30 minutes (37 degrees C). For determination of [PA+Pli]-activity, arginine was added after this incubation. 25-microL 6 mM Val-Leu-Lys-pNA were added and deltaA/h at room temperature (RT) was monitored, using a microtiterplate reader. [PA+Pli]-Pli = PA. The PA concentration required to induce 25% [ED25] of the maximally inducible Pli-activity in plasma (= 1 U/mL = 45 mg/L = 0.53 micromol/L active Pli; deltaA = 363 +/- 8 mA/h RT) after 10 minutes (37 degrees C) were 320 IU/mL u-PA, 8 microg/mL t-PA, 140 U/mL PSAC, 6,000 IU/mL SK, 720 U/mL RP, and approximately 150 microg/mL TP. The approximate activity half-lives of the PA in plasma were 30 minutes for u-PA, 30 minutes for t-PA, greater than 80 minutes for SK, greater than 80 minutes for PSAC, 50 minutes for RP, and 80 minutes for TP. The present study shows--for the first time--a combined kinetic in vitro simulation of the plasmatic activity of six different PAs. At clinically used concentrations, RP induces the highest plasmatic Pli activity. Due to unselective generation of plasmin in plasma, all PA are of some danger in inducing severe hemorrhagias. Clinical thrombolysis might be improved by usage of more physiologic activators of thrombolysis, such as activators of polymorphonuclear neutrophils.

Singlet oxygen (1O(2)) disrupts platelet aggregates.

INTRODUCTION: Important mediators of activated polymorphonuclear leukocytes (PMN) are the oxidants HOCl and chloramine, which generate the nonradical photon-emitting oxidant singlet oxygen (1O(2)). Since 1O(2) inhibits platelet aggregation, we became interested in a possible oxidant mediated reversibility of platelet aggregation. METHODS: Chloramine T (CT) is a stable 1O(2) generator that mimics the natural chloramine N-chloro-taurine. Platelet-rich plasma (PRP) was incubated with CT 0-8 min after addition of the aggregation agonist (10 microM adenosine-5'-diphosphate, ADP, or 5 microg/ml collagen) and the aggregation was monitored. Platelet function was also analyzed by the platelet function analyzer, PFA-100. Fifty microliters of 200 micromol/l ADP was added to 400 microl PRP. After 1 min at 37 degrees C, 50 microl of 0 or 30 mmol/l CT was added, and after an incubation for 3 min at 37 degrees C, 50 microl of 25% glutaraldehyde was added. The samples were analyzed in a transmission microscope at x3000 and x7000 magnification. RESULTS: Chloramines inhibit platelet function in PRP: about 1 mM CT suppresses 50% of the aggregatory capacity of thrombocytes in normal PRP (effective dose 50%, ED(50)=1 mM chloramine), which is identical to the ED(50) for CT in whole blood. The ADP- or collagen-induced platelet aggregation can be reversed by addition of CT: up to 2 min after the addition of ADP as the aggregation inducer, the aggregation is reversible to more than 70% by addition of a 1O(2) release-inducer (3 mM CT). In contrast, addition of CT 8 min after the addition of ADP results only in about 50% reversal of platelet aggregation. The electron microscopic images of platelets before ADP, after incubation for 4 min at 20 micromol/l ADP, after incubation for 1 min at 20 micromol/l ADP, and a further incubation for 3 min at 3 mmol/l CT demonstrate an ADP-dependent formation of platelet aggregates, which are disrupted by 1O(2) into the single platelets; a phenomenon comparable to the decomposition of a puzzle or the continental drift of the major earth plates. The morphology of oxidized and unoxidized platelets is similar. CONCLUSION: This study demonstrates that 1O(2) inhibits and reverses platelet aggregation. The physiologic signal action and the direct anticoagulant action of 1O(2) might be a new principle for pharmacologic intervention in atherothrombosis.

Arginine inhibits hemostasis activation.

BACKGROUND: The diagnosis and the therapy of in vivo hemostasis activation is of great clinical importance. Artefactual changes of the hemostasis (i.e., coagulation or fibrinolysis) in vitro have to be prevented. Usual in vitro anticoagulation by sodium citrate does not fully inhibit coagulation--or fibrinolysis--activation. Therefore, there is need for a simple physiologic inhibitor of hemostasis activation both in diagnosis and therapy of hemostasis activation. METHODS: Whole blood clotting time (WBCT), prothrombin time (PT), activated partial thromboplastin time (APTT), in vitro bleeding test closure time (IVBT-CT), and whole blood aggregometry (WBA) were determined in normal human blood or plasma, supplemented with increasing concentrations of L-arginine or guanidine. RESULTS: Arginine in concentrations of 5-100 mM inhibited the WBCT, PT, APTT, IVBT-CT, and WBA. Arginine (50 mM) resulted in a two-fold prolongation of WBCT, PT, or IVBT-CT (the anti-epinephrine action is superior to the anti-ADP action), a four-fold prolongation of APTT or a 60% inhibition of WBA. CONCLUSION: L-Arginine (or guanidine) inhibited the activation of hemostasis. Arginine might be used as hemostasis stabilizer both in the diagnosis and therapy of hemostasis activation. The usage of arginine as an in vitro hemostasis inhibitor might be indicated in the diagnosis of hemostasis activation, as occurring in pharmacological thrombolysis or disseminated intravascular coagulation (DIC). The storage of blood or blood products might be improved by arginine stabilization. The amino acid (and nitric oxide precursor) L-arginine could be an interesting new pharmacologic agent to inhibit a pathologic hemostasis activation.

Singlet oxygen inhibits agonist-induced P-selectin expression and formation of platelet aggregates.

Major mediators of activated polymorphonuclear leukocytes (PMN) are the oxidants HOCl and chloramine, which are a source for the nonradical photon-emitting oxidant singlet oxygen (1O2). We were interested in a possible platelet-modulating activity of 1O2. As a stable 1O2 source we chose the mild oxidant chloramine T (CT), which mimics the natural chloramine N-chloro-taurine. Freshly drawn native whole blood from donors (n = 5) was incubated at 0 to 3 mM CT for 1 minute at 37 degrees C. Then saline. 10 microM adenosine diphosphate (ADP), 5 microg/mL collagen, or 6.25 microM thrombin receptor activator peptide (TRAP) were added and the mixtures were allowed to incubate for 3 minutes at 37 degrees C. Aliquots of activated blood were fixed in 1% para-formaldehyde. After removal of the fixative, platelets were labeled with anti-CD61-FITC and anti-CD62P-PE antibodies and analyzed by flow cytometry. An oxidant concentration-dependent decrease in the expression of P-selectin appeared (at 3 mM CT to 39, 23, and 20% of the 100% saline control level for ADP, collagen, and TRAP, respectively). There was also an oxidant concentration-dependent decrease in the formation of platelet aggregates (at 3 mM CT to 8, 12, and 13% of the 100% saline control level for ADP, collagen, and TRAP, respectively; the 50% effective dose was 1.0 to 1.5 mM chloramine). In ADP- and TRAP-stimulated platelets, an oxidant-mediated increase in platelet fragments appeared (at 3 mM CT: three- to fourfold of the initial value). The addition to the blood of 30 mM of the oxyradical scavenger mannitol in contrast to excess methionine did not antagonize these oxidative modulations of platelet activation. The results were confirmed using equimolar concentrations of NaOCI and N-chloro-taurine. This study shows that 1O2 inhibits platelets, decreasing the expression of CD62P and the formation of platelet aggregates. Activated PMN might modulate hemostasis, shifting it into an antithrombotic state. The physiologic signal action and the direct anticoagulant action of 1O2 (released by chloramines such as vancomycin) might be a new principle for pharmacologic intervention in atherothrombosis.

Thrombin converts singlet oxygen (1O2)-oxidized fibrinogen into a soluble t-PA cofactor. A new method for preparing a stimulator for functional t-PA assays.

Activated phagocytes, particularly polymorphonuclear leukocytes (neutrophils), by means of oxidative photonic burst, i.e., the combined activation of NADPH-oxidase and myeloperoxidase, generate large amounts of oxidants of the hypochlorite/chloramine type that are an important physiologic source for the nonradical, photon-emitting oxidant singlet oxygen (1O2), which (in the dark blood stream) is both a signal and an agent of defense against bacteria or fibrin. 1O2-oxidized fibrinogen or oxidized fibrin monomer has previously been shown to be unpolymerizable, and methionine to methionine sulfoxide-oxidized fibrinogen occurs in circulating blood. The present study demonstrates that thrombin converts oxidized fibrinogen into a soluble stimulator of tissue-type plasminogen activator (t-PA). After addition of 0.1 IU thrombin to 25 microl oxidized normal human plasma and an incubation time of 10 min (room temperature), t-PA activity increases about 20-fold when compared with oxidized plasma without the addition of thrombin. Thus, since oxidized fibrin monomer is a t-PA cofactor, thrombin-degraded oxidized fibrinogen can be used as a stimulator in functional t-PA assays.

Singlet oxygen ((1)O2) inactivates plasmatic free and complexed alpha2-macroglobulin.

alpha2-macroglobulin (alpha2M) is a broad-spectrum proteinase inhibitor and one of the major plasma proteins in humans. Activated phagocytes (especially granulocytes) generate large amounts of oxidants of the HOCI- and chloramine-type that release the mild nonradical, excited (light-emitting) oxidant singlet oxygen ((1)O2). These oxidants have been shown to inactivate several specific serine protease inhibitors in human blood [e.g., alpha1-antitrypsin or alpha2-antiplasmin (plasmin inhibitor)]. The studies reported here demonstrate that nonradical oxidants also inactivate plasmatic alpha2M. The effective dose for 50% inactivation (ED50) of plasmatic alpha2M is similar to that for plasmatic alpha2-antiplasmin. Chloramines are about 1,000-fold more effective than hydrogen peroxide (ED50)=0.75 micromol chloramine T/50 microl plasma). Serine protease-serine protease inhibitor complexes are resistant to oxidants. In contrast, here it is shown that alpha2-macroglobulin, even after binding to serine proteases is sensitive to oxidation, the captured protease is released from the protease/alpha2M complex. This is the first time that oxidative inactivation of a complexed (i.e., bound to a target protease) human protease inhibitor has be shown. The (1)O2 inhibitors methionine, cysteine, cystine, or ascorbate-in contrast to the oxy-radical scavengers mannitol, superoxide dismutase, or catalase-antagonize the chloramine/NaOCl-mediated inactivation of both uncomplexed and complexed alpha2M. Thus, the oxidant involved here is of nonradicalic nature and has reaction characteristics of (1)O2. For the inhibitory function, critical oxidizable methionines or the internal thiol-ester might be targets for (1)O2. Consequently, alpha2M can also be considered a carrier for proteases, since the alpha2M-complexed proteases regain full activity in an oxidative environment. In local areas of inflammation or thrombolysis, activated phagocytes could create microenvironments of uncontrolled protease activity by generation of (1)O2.

Singlet oxygen inactivates fibrinogen, factor V, factor VIII, factor X, and platelet aggregation of human blood.

Activated polymorphonuclear leukocytes participate in hemostasis. These phagocytes generate up to 5 mmol/l of oxidants of the HOCl- and chloramine-type. The present study shows, for the first time, that physiological concentrations of NaOCl or chloramines act as anticoagulants in human plasma. Prothrombin time, activated partial thromboplastin time, and thrombin time at chloramine concentrations greater than 1 mmol/l are prolonged proportional to the oxidant concentration. Plasmatic coagulation factors sensible to oxidation are fibrinogen, factor V, factor VIII, and factor X with a 50% effective dose of 2-3 mmol/l NaOCl or taurine-chloramine. Chloramines or chloramine-like agents (e.g., chloramine T(R) or vancomycin) also inactivate platelet aggregation (in whole blood or platelet-rich plasma) at an 50% effective dose of about 1.0 mmol. This irreversible oxidation of the hemostasis components is inhibited by addition of methionine, cysteine, ascorbic acid, or azide in 10-fold molar excess prior to oxidation. The oxy-radical inhibitors mannitol, superoxide dismutase, or catalase do not antagonize the action of NaOCl or chloramines. Therefore, the oxidant here involved has reaction characteristics of singlet oxygen (1O(2)), a nonradical, excited (i.e., light-emitting) oxidant. The hemostasis factors sensible to oxidation might dispose of oxidizable, for their function critical, methionine or cysteine residues. In conclusion, blood coagulation factors I, V, VIII, X and thrombocytes are sensible to nonradical oxidants of activated phagocytes. Via 1O(2) generation, polymorphonuclear leukocytes can generate a local pericellular zone of anticoagulation. The data suggest that the cell signal 1O(2) in physiological amounts is an antithrombotic agent.

The antithrombotic factor singlet oxygen/light (1O2/h nu).

Activated phagocytes (especially polymorphonuclear granulocytes (PMNs)) by respiratory oxidative/photonic burst (activation of NADPH-oxidase and myeloper-oxidase) generate large amounts of oxidants of the hypochlorite-/chloramine-type, which are physiologic sources for singlet oxygen (1O2), a nonradical-excited (photon (h nu) emitting) oxygen species [Weiss SJ, NEJM 1989;320:365-376]. In vitro experiments show that 1O2 (1) inhibits coagulation by inactivation of thrombocytes, fibrinogen, factor V, factor VIII, and factor X and (2) activates fibrinolysis by inactivation of the main fibrinolysis inhibitors plasminogen activator inhibitor (PAI)-1 and alpha-2-antiplasmin, and by activation of single-chain urokinase by plasmin and oxidized fibrin. Additionally, this work suggests that 1O2/h nu acts antithrombotically, inducing selective thrombolysis in vivo (i.e., thrombolysis induced by 0.1 to 0.5 mmol/l chloramine within 30 to 60 minutes without changes of the plasmatic hemostasis system). 1O2 might activate flowing to (on the endothelium) rolling PMN, increasing their chance to get in contact with fibrin/platelet aggregates deposited on the endothelial layer. Via 1O2 generation, the thrombus-activated phagocytes might call for (acute, physiologic) inflammation/fibrinolysis amplification, resulting in the "moving front" of PMN, which infiltrates and destroys the thrombus. 1O2 seems to (partially) participate in the reactivity of nitric oxide, another prooxidative agent. The inhibition of physiologic amounts of 1O2 by blood cholesterol might be involved in the pathogenesis of atherothrombosis. Consequently, it is suggested that activated PMNs modulate hemostasis, shifting it into an antithrombotic state; this cellular part of fibrinolysis seems to be of greater physiologic importance than the plasmatic one. Impaired PMN function (e.g., as occurring in patients with antineutrophil cytoplasmic antibodies or under cytostatic treatments) often results in serious thrombotic complications. Light is the only signal whose origin can be immediately recognized by a fast moving cell in the (dark) blood stream. The cell signal action of 1O2/h nu (e.g., released by chloramines such as taurine-chloramine or vancomycin, by fiberoptic, by photodynamic therapy, or by so-called redox-cycling drugs such as quinones or tetracyclines) might be a new and physiologic principle for pharmacologic intervention in atherothrombosis.

A simple screening assay for certain fibrinolysis parameters (FIPA).

Hemostasis, the system of generation and degradation of thrombi, consists of coagulation and fibrinolysis. Whereas global assays to study coagulation have existed for many years, there has been no simple, rapid, and economic routine test for the plasmatic fibrinolysis parameters plasminogen activator inhibitor-1, alpha2-antiplasmin, plasminogen, and aprotinin. Here a fast functional global assay for these plasmatic fibrinolytic parameters is presented. However, the present assay is not sensitive to physiological concentrations of prourokinase or tissue-type plasminogen activator. The following assay conditions have been found to be optimal: 50 microL of citrated plasma is incubated with 50 microL of 10 IU urinary-type plasminogen activator (urokinase)/mL, 1.1 mmol/L tranexamic acid, 1% polygelin, 0.1% Triton X-100, phosphate-buffered saline, pH 7.4, for 20 min at 37 degrees C (plasmin generation phase). Then 50 microL of 3 mmol/L HD-Nva-CHA-Lys-pNA, 1.05 mol/L KCl is added, and deltaA (405 nm)/10 min (37 degrees C) is determined, by using a microtiterplate reader (plasmin detection phase). The results are calibrated against pooled normal plasma (100% plasmatic fibrinolytic parameters activity). The intra- and interassay coefficients of variation have been found to be less than 5%. The detection limit (sensitivity) of the functional fibrinolysis assay is 5 % of the normal plasmatic fibrinolysis parameters activity. The normal plasmatic fibrinolysis parameters activity is 100%, sigma = 25%. The plasmatic fibrinolysis parameters activity correlates negatively (r = -0.684) with the plasminogen activator inhibitor-1 activity of patient samples. The plasmatic fibrinolysis parameters assay is a simple, rapid, and economic functional test for several clinical relevant fibrinolysis parameters.