Masking of heparin activity in the activated coagulation time (ACT) by platelet procoagulant activity

Platelet Function and Cardiopulmonary Bypass

Cardiopulmonary bypass (CPB) is a nonphysiologic state that has many detrimental effects on a patient's hemostatic integrity. Exposure to the extracorporeal circuit and subsequent activation of the coagulation and fibrinolytic systems are factors that contribute to morbidity and mortality in cardiac surgical patients. These effects can be prevented in part or appropriately treated if practitioners understand the basic mecha nisms. This article reviews the effects of CPB on platelet function, the relationship of platelet function to post operative bleeding, the monitors available to measure platelet function, and the impact of antiplatelet therapy on bleeding in cardiac surgery.

Review article: heparin sensitivity and resistance: management during cardiopulmonary bypass

Heparin resistance during cardiac surgery is defined as the inability of an adequate heparin dose to increase the activated clotting time (ACT) to the desired level. Failure to attain the target ACT raises concerns that the patient is not fully anticoagulated and initiating cardiopulmonary bypass may result in excessive activation of the hemostatic system. Although antithrombin deficiency has generally been thought to be the primary mechanism of heparin resistance, the reasons for heparin resistance are both complex and multifactorial. Furthermore, the ACT is not specific to heparin's anticoagulant effect and is affected by multiple variables that are commonly present during cardiac surgery. Due to these many variables, it remains unclear whether decreased heparin responsiveness as measured by the ACT represents inadequate anticoagulation. Nevertheless, many clinicians choose a target ACT to assess anticoagulation, and interventions aimed at achieving the target ACT are routinely performed in the setting of heparin resistance. Treatments for heparin resistance/alterations in heparin responsiveness include additional heparin or antithrombin supplementation. In this review, we discuss the variability of heparin potency, heparin responsiveness as measured by the ACT, and the current management of heparin resistance.

Coagulation Monitoring

Monitoring hemostasis is now possible by different modalities, of which the point of care devices seem most helpful to the clinician in the operating room. Most of these monitors are being used in the cardiac population, and their significance in other fields remains to be assessed.

Monitoring anticoagulation and hemostasis in cardiac surgery

The need to monitor anticoagulation and hemostasis during and after cardiac surgery has led to recognition of the importance of evaluation and use of hemostasis monitors in this setting. Consequently, rapid and accurate identification of abnormal hemostasis has been the major impetus for the development of point-of-care tests and their use in transfusion algorithms for cardiac surgical and other critically ill patients.

Aprotinin restores the adhesive capacity of dysfunctional platelets

The post-operative coagulopathy associated with cardiopulmonary bypass (CPB) is known to be predominantly related to platelet dysfunction. The use of the serine protease inhibitor aprotinin dramatically reduces CPB associated hemorrhage and is thought to act primarily through the inhibition of plasmin without directly influencing platelets. Our data indicate that there is a direct effect of aprotinin on platelet adhesion, which has not been previously reported. We found that when aprotinin was added to blood samples with poorly adhesive platelets, platelet adhesion significantly increased as measured by the percent coverage of denuded arterial segments in the Baumgartner perfusion chamber. In preliminary experiments using expired platelet concentrates or fresh whole blood, the addition of aprotinin induced a positive increase of 22+/-7.5 and 14+/-6.2 percentage point in platelet adhesion, respectively. A simulated CPB model that recirculated a unit of anticoagulated whole blood for 2 h was used (n=14) to induce a platelet adhesion defect similar to that seen in clinical CPB. At initiation of recirculation, platelet adhesion was 55+/-9.5% but dropped to 13+6.5% coverage after 2 h simulated CPB. The addition of aprotinin to the post-recirculation samples induced a significant restoration of platelet adhesion back to 38+/-11% coverage. When epsilon amino-caproic acid with soybean trypsin inhibitor was added to post recirculation samples, there was no similar effect on adhesion scores. To compare these findings with surgical CPB, we collected one blood sample at the beginning and two at the end of CPB from each of seven open-heart patients. Aprotinin was added to one of each of the post-CPB samples. Platelet adhesion at the onset of surgical CPB was only 39+/-11% in this patient group but dropped to 7+/-7% by the end. Similar to the model, the addition of aprotinin post-CPB restored adhesion to 29+/-11%. These results suggest some action of aprotinin other than its antiplasmin effect, and that platelet adhesion in general can be promoted by aprotinin.

Effect of additional temporary glycoprotein IIb/IIIa receptor inhibition on troponin release in elective percutaneous coronary interventions after pretreatment with aspirin and clopidogrel (TOPSTAR trial)

OBJECTIVES

The Troponin in Planned PTCA/Stent Implantation With or Without Administration of the Glycoprotein IIb/IIIa Receptor Antagonist Tirofiban (TOPSTAR) trial investigated: 1) the amount of troponin T (TnT) release after nonacute, elective percutaneous coronary intervention (PCI) in patients pretreated with aspirin and clopidogrel; and 2) the effect of additional glycoprotein (GP) IIb/IIIa receptor inhibiton on postinterventional TnT release.

BACKGROUND

No data are available yet as to whether additional administration of a GP IIb/IIIa receptor antagonist might be beneficial in patients undergoing elective PCI already pretreated with aspirin and clopidogrel.

METHODS

After bolus application of the study medication (tirofiban [T] or placebo [P]), PCI was performed followed by an 18-h continuous infusion of T/P. Primary end point of the study was incidence and amount of TnT release after elective PCI after 24 h.

RESULTS

A total of 12 h after PCI troponin release was detected in 63% of the patients receiving P and in 40% of the patients receiving T (p < 0.05), after 24 h in 69% (P) and 48% (T) (p < 0.05) and after 48 h in 74% (P) versus 58% (T) (p < 0.08) of the patients. No differences were observed regarding major bleeding, intracranial bleeding or nonhemorrhagic strokes. After nine months a reduction of combined death/myocardial infarction/target vessel revascularization could be observed in the tirofiban group ([T] 2.3% vs. [P] 13.04%, p < 0.05).

CONCLUSIONS

Troponin T release occurs after successful intervention in 74% of the patients undergoing elective PCI after 48 h even after pretreatment with aspirin and clopidogrel. The GP IIb/IIIa receptor antagonist tirofiban is able to decrease the incidence of troponin release significantly in this patient population.

Monitoring the Hematologic Complications of Cardiopulmonary Bypass

Patients undergoing cardiopulmonary bypass (CPB) procedures have a variety of hemostatic defects that lead to bleeding and the frequent need for transfusion of allogeneic blood products. Dilution of the patient's blood volume by the extracorporeal circuit priming so lution causes depletion of platelets and coagulation factor levels. Contact of blood with the extracorporeal circuit induces a hemorrhagic diathesis through a vari ety of mechanisms. Contact activation causes the for mation of kallikrein, bradykinin, and complement acti vation, leading to a whole-body inflammatory reaction. Intrinsic coagulation is stimulated, leading to subse quent activation of the fibrinolytic system. Platelet dys function caused by the effects of the extracorporeal circuit on platelet membrane integrity and the effects of circulating platelet inhibitors have also been described. The use of high-dose heparin for CPB mitigates these effects but does not completely eliminate them. Prota mine, administered to antagonize heparin's effects, has antiplatelet properties and anticoagulant effects when given in excess. Because of the numerous hemostatic insults incurred during and after CPB, complex moni toring techniques are necessary to ensure adequate anticoagulation, adequate heparin neutralization, and normal platelet function. Coagulation monitoring has allowed more specific identification of particular distur bances of hemostasis and has been linked with a reduc tion in hemorrhagic complications after CPB. Copyright © 2001 by W.B. Saunders Company.

Effect of heparin, platelets, activated platelets, platelet fragments, and hematocrit on activated clotting time

Activated clotting time (ACT) is the most commonly used laboratory test to control the heparin effect during extracorporeal techniques. The study was undertaken in order to test in vitro the influence of heparin, platelet count, hematocrit, platelet fragmentation, and platelet activation on ACT. Blood was drawn from volunteer donors into syringes containing citrate. Platelet counts and hematocrit were modified. Platelets were fragmented by sonifier or activated by collagen and adenosine diphosphate (ADP). Different heparin final concentrations were created. Increasing concentrations of heparin had a significant effect on ACT. However, it was not predictable in every case in concentrations lower than 1.0 U/ml. Platelet count generally had no significant effect on ACT. The effect of hematocrit was detectable in a group but not in single cases. Fragmented platelets significantly shortened ACT only without addition of heparin, and the effect was only partly predictable. Activation of platelets by collagen and ADP induced no significant changes. Our results show that heparin is reflected by ACT but that effect is not predictable in every specific patient. Our results also show that other variables that may be altered during extracorporeal techniques such as platelet count, hematocrit, activation, and fragmentation of platelets do not severely influence the ACT.

Assessment of heparin anticoagulation: comparison of two commercially available methods

BACKGROUND

The activated clotting time is a bedside method routinely used to monitor heparin anticoagulation during operations requiring cardiopulmonary bypass. The thrombolytic assessment system heparin management test is a new bedside method for monitoring heparin effect. We compared these methods with respect to their ability to reflect the actual heparin concentration in plasma determined by an anti-FXa method.

METHODS

Two studies were done, an ex vivo study on ten patients who had coronary artery bypass using non-heparin-coated cardiopulmonary bypass circuits and full systemic heparinization and an in vitro study on single donor plasma spiked with heparin 0 to 10 IU/mL.

RESULTS

Ex vivo study correlation coefficients of activated clotting time and the thrombolytic assessment system heparin management test clotting times versus anti-FXa-based heparin assay were low (r = 0.53, p = 0.002/r = 0.64, p<0.001) in contrast with the corresponding correlation coefficients for the in vitro study (r = 0.98, p<0.001/r = 0.99, p<0.001). A substantial variability in duplicate activated clotting time determinations was noted, which was less pronounced with the thrombolytic assessment system heparin management test.

CONCLUSIONS

The thrombolytic assessment system method does not correlate better to the actual amount of heparin during cardiopulmonary bypass procedures than the activated clotting time method, which should be performed in duplicate.

Comparison of the effects of red cell separation and ultrafiltration on heparin concentration during pediatric cardiac surgery

OBJECTIVE

To determine the effects of red cell separation and ultrafiltration on heparin concentration.

DESIGN

Prospective study.

SETTING

University-affiliated, pediatric medical center.

PARTICIPANTS

Thirty-one children undergoing cardiac surgery.

INTERVENTIONS

Blood sampled for heparin concentration and coagulation tests.

MEASUREMENTS AND MAIN RESULTS

Thirteen infants under-went modified veno-venous ultrafiltration (UF) after cardiopulmonary bypass (CPB). In addition, residual blood in the CPB circuit was hemoconcentrated by UF and reinfused (UF group). Heparin concentration increased from 2.0 +/- 0.6 to 2.5 +/- 0.8 U/mL, following modified UF; while activated coagulation time (ACT) decreased from 701 +/- 177 to 627 +/- 107 seconds. Heparin concentration of CPB circuit residual increased from 1.9 +/- 0.7 to 3.1 +/- 1.0 U/mL. In 18 children (older than 1 year old), the residual blood in the CPB circuit was hemoconcentrated by cell separation (CS) and reinfused (CS group). Heparin concentration of CPB circuit residual decreased from 2.6 +/- 0.6 to 0.3 +/- 0.2 U/mL. After reinfusion, patient heparin concentration remained unchanged at < 0.05 U/mL. Thrombin time increased from 28 +/- 6 to 48 +/- 29 seconds and did not correlate with H.

CONCLUSIONS

The plasma concentration of heparin increased after veno-venous modified UF of the patient. Heparin concentration also increased after UF of residual CPB circuit blood. In contrast, circuit blood hemoconcentrated by CS contained minimal heparin, and, when infused, did not increase patient's heparin concentration. ACT and thrombin time did not correlate with heparin concentration.

The effects of thrombocytopenia on the activated coagulation time

The activated coagulation (clotting) time (ACT) is widely used to monitor heparin therapy during cardiopulmonary bypass (CPB). Since thrombocytopenia occurs during and for some time after CPB, we considered the possibility that thrombocytopenia may affect the ACT. Blood samples were obtained from 12 healthy volunteers. Thrombocytopenic samples were created by a differential centrifugation technique. Blood samples from five thrombocytopenic patients were also studied. The platelet counts of the control citrated whole blood samples were 254,000 +/- 35,000/microL (mean +/- SD), whereas the platelet counts of the thrombocytopenic citrated samples were 49,000 +/- 8000/microL. There were no significant differences in the ACTs between these two groups (143 +/- 8 vs 145 +/- 9 s, respectively, P = 0.16). There were also no significant differences in the ACTs of the heparinized control samples compared with the ACTs of the heparinized thrombocytopenic samples. The platelet counts of the five thrombocytopenic patients were 43,000, 18,000, 16,000, 8000, and 7000/microL, and the ACTs of the unanticoagulated samples were 162, 240, 191, 210, and 215s, respectively. We conclude that the ACT is not affected by moderate thrombocytopenia and therefore this test may be used in patients who are moderately thrombocytopenic.

Comparison of bedside and hospital laboratory coagulation studies during and after coronary intervention

The activated clotting time is routinely used to monitor anticoagulation during coronary intervention, whereas the hospital laboratory APTT guides pre- and postprocedure heparin therapy. An optimal coagulation test for patients undergoing percutaneous revascularization would provide a rapid and accurate assessment of anticoagulation throughout a broad range of heparin therapy. We studied the relationships of the bedside whole blood APTT, ACT, and the laboratory APTT in 166 patients undergoing coronary intervation. The whole blood APTT correlated closely with the laboratory APTT (range 18-80 sec) (r = .75), whereas the ACT and laboratory APTT had only a fair correlation (r = .42). Also, the whole blood APTT demonstrated a strong correlation with the ACT throughout the range of heparin therapy for intervention (r = .81). The diagnostic accuracy of the whole blood APTT, based on the receiver operating characteristic curve, was significantly better than that for the ACT in determining the anticoagulation status. The whole blood APTT obtained by bedside monitoring provides a rapid and accurate assessment of anticoagulation throughout the range of heparin dosing associated with coronary intervention. In situations in which an adequate assessment of residual anticoagulation is necessary, the whole blood APTT is superior to the ACT and probably should be the method of choice.

Activated clotting time as an appropriate test to compare heparin and direct thrombin inhibitors such as hirudin or Ro 46-6240 in experimental arterial thrombosis

BACKGROUND

Specific thrombin inhibitors are considered to be more potent antithrombotics than heparin. However, the relation between the systemic anticoagulation generated by thrombin inhibitors and their antithrombotic effect is not well defined. In a guinea pig carotid thrombosis model, the activated clotting time (ACT), the activated partial thromboplastin time (aPTT), and thrombin-generation tests were evaluated for their ability to predict the arterial antithrombotic effect of direct thrombin inhibitors such as hirudin and Ro 46-6240 compared with heparin.

METHODS AND RESULTS

Thrombosis of the carotid artery was induced by subendothelial damage in guinea pigs, and the subsequent cyclic flow variations were monitored. The effects of pretreatment with intravenous heparin, hirudin, and Ro 46-6240 were tested. After doubling the baseline aPTT, 1 IU.kg-1.min-1 heparin was inactive, whereas either hirudin or Ro 46-6240 (30 micrograms.kg-1.min-1) prevented thrombus formation by 80%. Heparin (10 IU.kg-1.min-1) induced the same antithrombotic effect but with indefinite aPTT prolongation. However, for similar prolongation of the ACT, the three compounds had equivalent antithrombotic effects. Thrombin generation was predictive of the antithrombotic effect of the thrombin inhibitors but not of heparin.

CONCLUSIONS

The arterial antithrombotic effect of direct thrombin inhibitors, when compared with those of heparin, should be evaluated by the ACT and not the aPTT or thrombin-generation assays. For a "therapeutic" aPTT prolongation, thrombin inhibitors induce higher systemic anticoagulation than does heparin and thus might unduly have higher bleeding liability.