Inhibition of activated protein C by aprotinin and the use of the insolubilized inhibitor for its purification

Monitoring of plasma levels of activated protein C using a clinically applicable oligonucleotide-based enzyme capture assay

BACKGROUND

Human-activated protein C (APC) is a serine protease with anticoagulant, anti-inflammatory and cytoprotective functions. This feature renders APC to be a promising vascular-inflammatory biomarker.

OBJECTIVE

The aim of the present study was the development and validation of a technique that allows the measurement of APC plasma levels under practical laboratory conditions.

METHODS/PATIENTS

Based on the APC-binding ssDNA aptamer HS02-52G we developed an oligonucleotide-based enzyme capture assay (OECA) that quantifies aptamer-captured APC through hydrolysis rates of a fluorogenic peptide substrate. After optimization of pre-analytical conditions, plasma APC levels were measured in healthy individuals and patients undergoing hip replacement surgery.

RESULTS AND CONCLUSION

A combination of APC-OECA with an aprotinin-based quenching strategy allowed APC analysis with a limit of detection as low as 0.022 ± 0.005 ng mL(-1) (0.39 ± 0.10 pmol L(-1)) and a limit of quantification of 0.116 ± 0.055 ng mL(-1) (2.06 ± 0.98 pmol L(-1)). While APC plasma levels in healthy individuals fell below the quantifiable range of the APC-OECA platform, levels substantially increased in patients undergoing hip replacement surgery reaching peak values of up to 12 ng mL(-1) (214 pmol L(-1)). When normalized to the amount of thrombin generated, interindividual variabilities in the APC generating capacity were observed. In general, with a turn-around time from blood sampling to generation of test results of < 7 h, the APC-OECA platform allows sensitive and rapid determination of circulating APC levels under pathological conditions.

Continuous localized monitoring of plasmin activity identifies differential and regional effects of the serine protease inhibitor aprotinin: relevance to antifibrinolytic therapy

BACKGROUND

Antifibrinolytic therapy, such as the use of the serine protease inhibitor aprotinin, was a mainstay for hemostasis after cardiac surgery. However, aprotinin was empirically dosed, and although the pharmacological target was the inhibition of plasmin activity (PLact), this was never monitored, off-target effects occurred, and led to withdrawn from clinical use. The present study developed a validated fluorogenic microdialysis method to continuously measure PLact and tested the hypothesis that standardized clinical empirical aprotinin dosing would impart differential and regional effects on PLact.

METHODS/RESULTS

Pigs (30 kg) were instrumented with microdialysis probes to continuously measure PLact in myocardial, kidney, and skeletal muscle compartments (deltoid) and then randomized to high-dose aprotinin administration (2 mKIU load/0.5 mKIU/hr infusion; n = 7), low-dose aprotinin administration (1 mKIU load/0.250 mKIU/hr infusion; n = 6). PLact was compared with time-matched vehicle (n = 4), and PLact was also measured in plasma by an in vitro fluorogenic method. Aprotinin suppressed PLact in the myocardium and kidney at both high and low doses, indicative that both doses exceeded a minimal concentration necessary for PLact inhibition. However, differential effects of aprotinin on PLact were observed in the skeletal muscle, indicative of different compartmentalization of aprotinin.

CONCLUSIONS

Using a large animal model and a continuous method to monitor regional PLact, these unique results demonstrated that an empirical aprotinin dosing protocol causes maximal and rapid suppression in the myocardium and kidney and in turn would likely increase the probability of off-target effects and adverse events. Furthermore, this proof of principle study demonstrated that continuous monitoring of determinants of fibrinolysis might provide a novel approach for managing fibrinolytic therapy.

Textilinin-1, an alternative anti-bleeding agent to aprotinin: Importance of plasmin inhibition in controlling blood loss

Aprotinin has been used widely in surgery as an anti-bleeding agent but is associated with a number of side effects. We report that textilinin-1, a serine protease inhibitor from Pseudonaja textilis venom with sequence relatedness to aprotinin, is a potent but reversible plasmin inhibitor and has a narrower range of protease inhibition compared to aprotinin. Like aprotinin, textilinin-1 at 5 micromol/l gave almost complete inhibition of tissue plasminogen activator-induced fibrinolysis of whole blood clots. The activated partial thromboplastin time for plasma was markedly increased by aprotinin but unaffected by textilinin-1. In a mouse tail-vein bleeding model, intravenous textilinin-1 and aprotinin caused similar decreases in blood loss but time to haemostasis in the textilinin-treated animals was significantly shorter than in aprotinin-treated mice. Based on these data, textilinin-1 merits further investigation as a therapeutic alternative to aprotinin.

Aprotinin in Cardiac Surgery: A Review of Conventional and Novel Mechanisms of Action

Induction of the coagulation and inflammatory cascades can cause multiorgan dysfunction after cardiopulmonary bypass (CPB). In light of these observations, strategies that can stabilize the coagulation process as well as attenuate the inflammatory response during and after cardiac surgery are important. Aprotinin has effects on hemostasis. In addition, aprotinin may exert multiple biologically relevant effects in the context of cardiac surgery and CPB. For example, it decreases neutrophil and macrophage activation and chemotaxis, attenuates release and activation of proinflammatory cytokines, and reduces oxidative stress. Despite these perceived benefits, the routine use of aprotinin in cardiac surgery with CPB has been called into question. In this review, we examined this controversial drug by discussing the classical and novel pathways in which aprotinin may be operative in the context of cardiac surgery.

Peptidomimetic inhibitors for activated protein C: implications for hemophilia management

BACKGROUND

Several clinical studies and experiments with transgenic mice have suggested that the severity of the bleeding phenotype in hemophilic patients is substantially reduced in association with impaired inactivation of factor (F) Va by activated protein C (APC) in the presence of the FV Leiden mutation. Experiments using a synthetic coagulation proteome model showed that the presence of FV Leiden significantly increased thrombin generation in the absence of FVIII or FIX.

OBJECTIVE

To test the effect of APC inhibition on thrombin generation in hemophilia.

METHODS

Prothrombinase and a synthetic coagulation proteome model of tissue factor-triggered thrombin generation were used.

RESULTS

Peptide-based APC inhibitors, which mimic the P4-P4' residues surrounding the APC cleavage site at Arg306 of FVa, were synthesized. These compounds are specific and reversible inhibitors of APC, with Ki values as low as 1-2 microM; most have insignificant affinity for FXa or thrombin. The affinity for APC is dependent upon the location and character of the protecting groups. Representatives of this group of compounds inhibit FVa inactivation by APC and prolong FVa functional activity in the prothrombinase complex. When evaluated in a synthetic coagulation proteome model, one inhibitor partially compensated for the absence of FVIII.

CONCLUSIONS

Synthetic APC inhibitors may be useful as adjuvants for hemophilia treatment.

Factor V Leiden and perioperative risk

Factor V Leiden (FVL) is the most common known inherited cause of thrombophilia; it is present in approximately 5% of the Caucasian population. Although the risk of venous thrombosis associated with this polymorphism in various medical settings is well described, its effect on perioperative risk is only beginning to be explored. Specifically, there are few studies addressing the potential risks of FVL in the surgical population, in which both hemorrhagic and thrombotic complications convey substantial clinical and economic significance. There are speculations and unproven hypotheses regarding FVL in this population, and these therefore highlight the need to comprehensively address this issue. This review will describe the physiology of the FVL mutation, briefly clarify its risk in the nonsurgical setting, and assess current data regarding FVL in noncardiac and cardiac surgery. Finally, a summary of current clinical evidence and a plan for more detailed investigation of this potentially significant risk factor will be proposed.

Factor V(LEIDEN) and cardiopulmonary bypass: investigation of haemostatic parameters and the effect of aprotinin using an ex vivo model

It has been suggested that aprotinin results in significantly increased risk for perioperative thrombotic complications in patients with Factor V(LEIDEN) (F5L) due to its ability to competitively inhibit activated protein C (APC) function in vitro. No clinical studies have been performed to assess the effect of aprotinin on APC function of F5L in vivo. We developed an ex vivo model to mimic the effects of cardiopulmonary bypass with the exclusion of the patient in order to assess APC function. Blood from normal (n = 2) and F5L heterozygous donors (n = 2) was treated with aprotinin or placebo (saline). The blood was heparinized, added to the prime and circulated at 2 l/min through a modified cardiopulmonary bypass circuit. After 60 min of circulation, the heparin was neutralized with protamine sulfate. Blood samples, drawn at specific time points, were analysed for APC ratio. Results showed a decrease in APC ratio for both F5L and normal bloods with the addition of aprotinin (18% and 40%, respectively). APC ratios also decreased with the commencement of extracorporeal circulation for all bloods, resulting in an APC ratio of 1.35 in normal placebo-treated blood and 0.67 in F5L placebo-treated blood. The combined effect of aprotinin and extracorporeal circulation resulted in APC ratios of 0.90 for normal blood and 0.63 for F5L blood, corresponding to a severe dysfunction of APC intraoperatively (reference range 1.9-4.0). The data from this model predict an increased risk of perioperative thrombosis due to inhibition of APC function in cardiac surgical patients heterozygous for the F5L mutation. Aprotinin further compounds the severity of APC dysfunction, though the effect is more severe in normal blood. The ex vivo model employed was an effective tool for the investigation of the haemostatic effect of aprotinin. This model may be exploited for other applications such as the investigation of novel or emerging haemostatic agents prior to clinical trial.

Intrinsic Anticoagulation: Protein C, Protein S, and Thrombomodulin

The protein C anticoagulant system provides important control over the blood coagulation cascade. Any alteration in this pathway, either hereditary, iatrogenic, or otherwise, may interfere with normal coagulation. In this review, current concepts and understanding of surface-dependent hemostatis are reviewed, effects of deficiencies in the intrinsic anticoagulant system are described, and potentially useful therapeutic strategies are proposed. The importance of protein C, protein S, and thrombomodulin in patients undergoing cardiac surgery is specifically addressed. Further work is required before complex interactions of individual components of the intrinsic anticoagulation pathway are fully understood.

Hemostatic Drugs in Prothrombotic or Hypercoagulable States

Certain drug therapies, such as heparin, warfarin, and aspirin, are associated with prothrombotic or hypercoagulable states. If these agents that are administered to prevent thrombosis have been associated with its opposite effect, then agents that are specifically given to inhibit bleeding may produce a deleterious hypocoagulable effect. This article evaluates the risks presented by serine protease inhibitors (ie, aprotinin), lysine analog antifibrinolyics (ie, epsilon aminocaproic acid [Amicar, Wyeth-Ayerst, Philadelphia, PA] and tranexamic acid), and desmopressin acetate (DDAVP, Rhone-Poulenc Rorer, Collegeville, PA). It focuses on their mechanisms of action, particularly their effect on microvascular tone and endothelial function, coagulation factors, platelet function, and the fibrinolytic pathway. It discusses their use in the presence of known thrombin production or fibrinogen conversion and whether certain vascular beds are more prone to drug-related thrombosis.

Restoration of the normal coagulation process: advances in therapies to antagonize heparin

A number of naturally occurring anticoagulants exist that preserve normal blood fluidity and limit blood clot formation to vascular injury sites, thus acting as regulators of hemostasis. The protein C/protein S pathway is one system that acts to modulate thrombin formation. The activation of protein C by thrombin is accelerated more than 1,000-fold at the endothelial surface by thrombomodulin localized on the endothelial cell. Activated protein C then binds to its co-factor, protein S, and the protein C/protein S complex exerts its antithrombotic function by inactivating the coagulation factors Va and VIIIa. Patients deficient in protein C and protein S may be particularly vulnerable to thrombotic events after cardiac surgery. In addition, several studies suggest that reductions in protein C and protein S concentrations, as well as thrombomodulin, occur during cardiopulmonary bypass (CPB). The possibility of a low anticoagulant potential when heparinization is reversed may be an important factor in the subsequent morbidity associated with thrombotic complications. Aprotinin is a serine protease inhibitor that in vitro binds competitively with the serine protease-activated protein C. However, aprotinin in the clinical setting has not been reported to alter levels of protein C in patients undergoing CPB. Reversal of the heparinization needed for CPB is almost universally performed with protamine. However, protamine has many deleterious effects. Recombinant platelet factor 4 (rPF4) has been proposed as an alternative to protamine. We investigated the effective heparin neutralization dose of rPF4 vs. the standard agent protamine in human blood activated through exposure to the CPB circuit. Activated clotting time (ACT) measurements suggested a 2:1 (w/w) reversal ratio for rPF4 and protamine. The first human open-label phase 1 trial of rPF4 reported no serious side effects and no important hemodynamic effects. Doses of 2.5 and 5.0 mg/kg were uniformly effective in reversing the anticoagulant effect of heparin and reducing the ACT to <200 s by 5 min after administration. Repeated monitoring of the ACT did not detect a rebound effect of heparin.

Does aprotinin increase the myocardial damage in the setting of ischemia and preconditioning?

BACKGROUND

Aprotinin reduces postoperative bleeding in cardiac operations, but its association with perioperative myocardial infarction remains controversial. Ischemic preconditioning is a novel method of myocardial protection.

METHODS

To answer whether aprotinin increases postischemic myocardial damage and also to characterize the effect of aprotinin on ischemic preconditioning, four groups of sheep were fully heparinized to keep activated clotting time readings greater than 750 seconds and subjected to 60 minutes of normothermic regional ischemia (diagonal artery occlusion) with 3 hours of reperfusion. Group I was the control with no treatment, group II received aprotinin (1 million KIU load followed by 250,000 KIU/h), group III underwent ischemic preconditioning (three 5-minute intervals of ischemia and reperfusion) before prolonged 1-hour ischemia, and group IV underwent similar ischemic preconditioning and received aprotinin. Area at risk was delineated by monastryl blue pigment, and infarction size by tetrazolium staining.

RESULTS

The ratios of weight of area at risk to left ventricular weight and left ventricular weight to body weight were constant between groups. Infarction size to area at risk ratio data demonstrated that aprotinin increases infarction size by 60% (infarction size to area at risk ratio from 52% +/- 10% to 84% +/- 10% for I versus II; p < 0.001). Aprotinin also attenuates the protective effect of ischemic preconditioning (infarction size to area at risk ratio from 25% +/- 4% to 41% +/- 6%; p < 0.001).

CONCLUSIONS

In the setting of ischemia, aprotinin increases myocardial damage. If, however, the heart is provided with protective preconditioning, then the deleterious effect of aprotinin may be neutralized. From these data we suggest that aprotinin should not be used routinely in cardiac operations unless extensive blood loss is anticipated, such as in redo open heart operations.

Aprotinin is a competitive inhibitor of the factor VIIa-tissue factor complex

A highly purified preparation of human plasma factor VIIa was submitted to chromogenic assays with S-2288 factors IXa, Xa, activated protein C and thrombin being absent. Factor VIIa alone or in the presence of calcium, kept its activity even in the presence of high concentrations of aprotinin, inhibition appeared only in the presence of a factor VIIa-tissue factor complex. A two-stage amidolytic assay using activation of purified factor X and hydrolysis of S-2765 chromogenic substrate by the generated Xa was used to show a competitive inhibition with a Ki value of 30 microM. Aprotinin had no effect on factor Xa amidolytic activity per se. The factor VIIa-tissue factor complex could be adsorbed to immobilized aprotinin and removed by a chaotropic ion like KSCN 3 M. The assays with the DFP inactivated VIIa-tissue factor complex proved that the interaction involved the active site of factor VIIa. The inhibition of the VIIa-tissue factor complex was demonstrated in a clotting assay using aprotinin enriched normal or factor VIII deficient plasma.

Inhibition of activated protein C by benzamidine derivatives

In studies on the inhibition of activated protein C (APC) by benzamidine derivatives potent inhibitors of APC were found among anilides of 4-amidinophenyl-alpha-aminobutyric acid (Ki = 0.58 mumol/l). Several bis-benzamidine derivatives containing a cycloalkanone linking bridge inhibit APC with Ki values near the micromolar range. Potent and selective inhibitors of thrombin derived from 3- and 4-amidinophenylalanine do not inhibit APC. This is of great importance for further development of these inhibitors as potential anticoagulant drugs.

Aprotinin can inhibit the proteolytic activity of thrombin. A fluorescence and an enzymatic study

Aprotinin has been shown to reduce blood loss and blood requirement when administered prior to surgery and this therapeutic benefit appears to be related to its specificity as a protease inhibitor. The inhibition of plasmin by aprotinin is well characterized, but little is known of its effect on thrombin. In preliminary experiments, we showed that aprotinin can prevent platelet aggregation induced by thrombin. Follow-up studies have now been performed in order to clarify the effect of aprotinin on thrombin. A fluorescence study of the direct binding of aprotinin to human alpha-thrombin was analysed according to the Michaelis-Menten model and a dissociation constant of 30 x 10(-6) mol.l-1 was determined. Aprotinin can displace p-aminobenzamidine, a fluorescent-probe molecule which binds to the active site of serine proteases, showing that the active site of thrombin was involved. Aprotinin also inhibited the ability of thrombin to induce a fibrin clot from purified fibrinogen and to induce the hydrolysis of the chromogenic substrate H-D-phenylalanylpipecolylarginine-p-nitroanalidehydrochloride++ + (S-2238). With S-2238, double-reciprocal plots show that the inhibition is competitive with a Ki of 61 microM and a Km of 1.72 microM. Aprotinin was a potent inhibitor of thrombin-induced aggregation. A Schild plot of the aggregation data yielded a slope of 0.97 +/- 0.12 and an apparent dissociation constant of 57.0 +/- 13.1 microM (mean +/- SEM). Thus, the inhibition of thrombin-induced platelet aggregation by aprotinin fits a model of competitive inhibition. Conclusions are that, in addition to a possible direct effect of aprotinin on platelets, the inhibition of thrombin-induced platelet activation by aprotinin can be also explained, in part, by a direct effect of the inhibitor on the thrombin molecule itself. This supports the concept that a proteolytic step is involved in the platelet response to thrombin. Finally, evidence is in favour of the participation of Trp245 in the fluorescence response of thrombin on binding to aprotinin.