Reducing hemostatic activation during cardiopulmonary bypass: a combined approach

Interventions such as heparin-coated circuits, epsilon-aminocaproic acid, and reduced shed blood reinfusion have shown mixed results when applied individually for limiting hemostatic activation during cardiopulmonary bypass (CPB). We compared coagulation and fibrinolytic activation during conventional CPB (control) (CTRL) using noncoated circuits, no antifibrinolytics, and open cardiotomy with a combined strategy (HAC) that used heparin-coated circuits, epsilon-aminocaproic acid, and closed cardiotomy. Blood samples were drawn before, during, and after CPB for primary coronary bypass grafting surgery from 9 CTRL patients and 10 HAC patients. Thrombin-antithrombin complex and fibrinopeptide A levels (markers of thrombin and fibrin generation) were reduced in the HAC versus CTRL group after 30 min of CPB (P < 0.05). Average tissue plasminogen activator (tPA) levels were significantly lower in the HAC group by 30 min on CPB (P < 0.05), resulting in preservation of plasminogen activator inhibitor (PAI)-1 during CPB (P < 0.05). D-Dimer, a measure of intravascular fibrin formation and removal, was reduced in the HAC group during and after CPB (P < 0.005). Overall, the combined strategy was associated with a reduction in CPB-induced increases in markers of thrombin generation, fibrin formation, tPA release, and fibrin degradation and better preservation of PAI-1. IMPLICATIONS: A combined approach during cardiopulmonary bypass (CPB) that uses heparin-coated circuits, epsilon-aminocaproic acid, and limited reinfusion of shed pericardial blood is associated with reduced activation of the coagulation and fibrinolytic systems that typically occurs during conventional CPB.     

Does the preparation of heparin influence anticoagulation during cardiopulmonary bypass?

Various preparations of heparin from different manufacturers are commercially available. The influence of bovine lung heparin (BLH) and porcine mucosal heparin (PMH) on anticoagulation and heparin plasma concentration was investigated in four groups of 10 patients undergoing elective aortocoronary bypass grafting either after single dose or repetitive dose (after 60 minutes) of one of these heparin preparations. Heparin plasma concentration increased significantly after injection of heparin (BLH: minimum, 1.67 U/mL; maximum, 2.10 U/mL; PMH: minimum, 1.69 U/mL; maximum, 2.15 U/mL). Sixty minutes after the initial dose, heparin plasma levels were higher in the patients who received PMH. Supplemental heparin doses 60 minutes after the loading dose increased plasma heparin concentration only with porcine mucosal heparin. Elimination of heparin in the urine was not different among the groups. Fibrinogen and antithrombin III concentrations, as well as activated clotting time (ACT; always greater than 400 seconds) and partial thromboplastin time (PTT; always greater than 300 seconds), did not differ among the groups, indicating effective anticoagulation during the bypass period with both types of heparin. It can be concluded that sufficient anticoagulation can be achieved with either kind of heparin. PMH seems to be longer acting and a repeat dose in these patients seems to be necessary only if cardiopulmonary bypass lasts longer than 90 minutes.     

The influence of preoperative anticoagulation on heparin response during cardiopulmonary bypass.

The effect of preoperative anticoagulant therapy on intraoperative heparin response in patients undergoing cardiac operations was examined in a prospective study. The study included 45 patients with different preoperative anticoagulant treatments: 10 patients received treatment with phenprocoumon (a warfarin analogue) (group M), 12 patients received treatment with intravenous heparin (group Hiv), and 13 patients received treatment with subcutaneous heparin (group Hsc). The control group consisted of 10 patients who did not receive anticoagulant therapy before operation (group C). Preoperative antithrombin III activity was highest in group M (85% +/- 6%) and lowest in group Hiv (70% +/- 15%, p less than 0.05). The activated clotting time, determined 10 minutes after bolus injection of 250 IU (group M) or 375 IU heparin (all other groups), was 529 +/- 109 seconds in group C, greater than 1000 seconds in group M, 483 +/- 99 seconds in group Hsc, and 406 +/- 63 seconds in group Hiv (p less than 0.05). Heparin consumption during cardiopulmonary bypass varied between 4.6 +/- 1.4 IU/kg.min (group Hiv) and 2.6 +/- 0.9 IU/kg.min (group M) (p less than 0.05). Despite this increased heparin consumption, the patients who had received heparin before operation demonstrated increased activation of coagulation at the end of cardiopulmonary bypass (thrombin-antithrombin III complex, 19 +/- 4.1 ng/ml in group M and 61 +/- 7 ng/ml in group Hsc, p less than 0.05; cross-linked fibrin fragments, 257 +/- 92 ng/ml in group M and 875 +/- 152 ng/ml in group Hiv, p less than 0.05). Increased platelet activation was also found in patients with preoperative heparin therapy (beta-thromboglobulin at the end of cardiopulmonary bypass was 585 +/- 88 ng/ml in group M versus 1341 +/- 190 ng/ml in group Hsc, p less than 0.05). Drainage from the chest tube 24 hours after operation was 815 +/- 305 ml in group C, 644 +/- 238 ml in group M, 1133 +/- 503 ml in group Hsc, and 950 +/- 505 ml in group Hiv (p less than 0.05 for group M versus group Hsc). This study suggests that patients who receive heparin therapy before operation face a high risk of insufficient anticoagulation during cardiopulmonary bypass if standard heparin doses are used. Therefore, for patients who receive preoperative heparin therapy, a larger (500 IU/kg) initial bolus of heparin is recommended before cardiopulmonary bypass. On the other hand, patients who undergo preoperative treatment with phenprocoumon receive sufficient anticoagulative effect with a heparin bolus of 250 IU/kg.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of combined anticoagulation using heparin and bivalirudin on the hemostatic and inflammatory responses to cardiopulmonary bypass in the rat

BACKGROUND: Despite high-dose heparin anticoagulation, cardiopulmonary bypass (CPB) is still associated with marked hemostatic activation. The purpose of this study was to determine whether a reduced dose of bivalirudin, added as an adjunct to heparin, would reduce thrombin generation and circulating markers of inflammatory system activation during CPB as effectively as full-dose bivalirudin, without adversely affecting postoperative hemostasis. METHODS: Using a model of normothermic CPB in rats, the authors prospectively compared markers of thrombin generation (thrombin-antithrombin complexes) and inflammatory markers (tumor necrosis factor alpha, interleukin 1beta, interleukin 6, and interleukin 10) in three groups: conventional high-dose heparin (H), full-dose bivalirudin (B), and a combined group (standard high-dose heparin with the addition of reduced dose bivalirudin or H&B), at baseline, after 60 min of CPB, and 60 min after CPB. Postoperative hemostasis was also assessed. RESULTS: Groups H&B and B showed reduced thrombin-antithrombin complex formation during CPB compared with group H (P = 0.0003), and this persisted after CPB for group B (P = 0.009). Perioperative increases in interleukin 6 and interleukin 10 showed a trend toward being reduced in animals receiving bivalirudin (P = 0.06). Evidence of residual anticoagulation was found in group H&B as measured by activated clotting time (P = 0.04) and activated partial thromboplastin time (P = 0.02), but no intergroup difference in primary hemostasis was found. CONCLUSIONS: Bivalirudin attenuates hemostatic activation during experimental CPB with potential effects on markers of the inflammatory response. However, with this dosing regimen, the combination of heparin and bivalirudin does not seem to confer any measurable advantages over full-dose bivalirudin anticoagulation.     

Activation of the hemostatic system during cardiopulmonary bypass

Cardiopulmonary bypass (CPB) is a unique clinical scenario that results in widespread activation of the hemostatic system. However, surgery also results in normal increases in coagulation activation, platelet activation, and fibrinolysis that are associated with normal wound hemostasis. Conventional CPB interferes with normal hemostasis by diluting hemostatic cells and proteins, through reinfusion of shed blood, and through activation on the bypass circuit surface of multiple systems including platelets, the kallikrein-kinin system, and fibrinolysis. CPB activation of the kallikrein-kinin system increases activated factor XIIa, kallikrein, bradykinin, and tissue plasminogen activator levels, but has little effect on thrombin generation. Increased tissue plasminogen activator and circulating fibrin result in increased plasmin generation, which removes hemostatic fibrin. The nonendothelial surface of the bypass circuit, along with circulating thrombin and plasmin, lead to platelet activation, platelet receptor loss, and reduced platelet response to wounds. In this review, we highlight the major mechanisms responsible for CPB-induced activation of the hemostatic system and examine some of the markers described in the literature. Additionally, strategies used to reduce this activation are discussed, including limiting cardiotomy suction, increasing circuit biocompatibility, antithrombin supplementation, and antifibrinolytic use. Determining which patients will most benefit from specific therapies will ultimately require investigation into genetic phenotypes of coagulation protein expression. Until that time, however, a combination of approaches to reduce the hemostatic activation from CPB seems warranted.     

Fresh frozen plasma: a solution to heparin resistance during cardiopulmonary bypass

The reasons for the highly variable response of patients to heparin remain incompletely understood. Empirical maintenance of the activated clotting time (ACT) at levels of 400 to 480 seconds appears to be safe for cardiopulmonary bypass (CPB). For patients with ACT responses lower than predicted for initial heparin doses, titration with additional heparin has been customary. In 44 patients undergoing cardiopulmonary bypass, 20 patients were identified as having initial ACTs of 300 seconds or less after receiving 300 units per kilogram of heparin. In 11 of them, ACTs were titrated to 400 to 480 seconds with additional heparin. Nine were given 2 units of fresh frozen plasma shortly after institution of CPB. In this group, there was significant augmentation of the ACT immediately after infusion of plasma. No differences in total heparin dosages given during CPB were found between 24 control patients with initially acceptable ACTs and the group receiving fresh frozen plasma. In contrast, more heparin was necessary in the patients with a low ACT titrated with heparin alone. Data also indicated that protamine sulfate requirements were substantially lower after administration of plasma than were those in either the control or the heparin-titrated, low ACT group. Fresh frozen plasma appears to "normalize" the heparin-ACT dose-response curve in heparin-resistant patients and to lessen total heparin requirements during CPB.     

Hemostatic activation and inflammatory response during cardiopulmonary bypass: impact of heparin management

BACKGROUND: Cardiac surgery involving cardiopulmonary bypass (CPB) leads to fulminant activation of the hemostatic-inflammatory system. The authors hypothesized that heparin concentration-based anticoagulation management compared with activated clotting time-based heparin management during CPB leads to more effective attenuation of hemostatic activation and inflammatory response. In a randomized prospective study, the authors compared the influence of anticoagulation with a heparin concentration-based system (Hepcon HMS; Medtronic, Minneapolis, MN) to that of activated clotting time-based management on the activation of the hemostatic-inflammatory system during CPB. METHODS: Two hundred elective patients (100 in each group) undergoing standard cardiac surgery in normothermia were enrolled. No antifibrinolytic agents or aprotinin and no heparin-coated CPB systems were used. Samples were collected after administration of the heparin bolus before initiation of CPB and after conclusion of CPB before protamine infusion. RESULTS: There were no differences in the pre-CPB values between both groups. After CPB there were significantly higher concentrations ( < 0.05) for heparin and a significant reduction in thrombin generation (25.2 +/- 21.0 SD vs. 34.6 +/- 25.1), d-dimers (1.94 +/- 1.74 SD vs. 2.58 +/- 2.1 SD), and neutrophil elastase (715.5 +/- 412 SD vs. 856.8 +/- 428 SD), and a trend toward lower beta-thromboglobulin, C5b-9, and soluble P-selectin in the Hepcon HMS group. There were no differences in the post-CPB values for platelet count, adenosine diphosphate-stimulated platelet aggregation, antithrombin III, soluble fibrin, Factor XIIa, or postoperative blood loss. CONCLUSION: Compared with heparin management with the activated clotting time, heparin concentration-based anticoagulation management during CPB leads to a significant reduction of thrombin generation, fibrinolysis, and neutrophil activation, whereas there is no difference in the effect on platelet activation. The generation of fibrin even in the presence of high heparin concentrations most likely has to be attributed to the reduced antithrombin III concentrations or reduced inhibition of clot-bound thrombin. Therefore, in addition to maintenance of higher heparin concentrations, monitoring and substitution of antithrombin III should be considered to ensure more efficient antithrombin activity during CPB.     

Effects of aprotinin on hemostatic mechanisms during cardiopulmonary bypass

Cardiopulmonary bypass (CPB) is associated with activation of humoral systems, which results in the release of proteases. These proteases may affect platelets and stimulate granulocytes. In the present study, the protease inhibitor aprotinin was given in high doses to 11 patients to achieve plasma concentrations of more than 150 kallikrein inactivator units per milliliter during CPB. At such concentrations, kallikrein and plasmin are effectively inhibited. This treatment resulted in platelet preservation during CPB. Platelet numbers were virtually unaffected, and thromboxane release was prevented in the aprotinin-treated group in contrast to the control group. Postoperatively, hemostasis was significantly better preserved after aprotinin treatment (blood loss of 357 ml in the treated group versus 674 ml in the untreated group; p less than 0.01). Since tissue-plasminogen activator activity was similar in both groups, the improved hemostasis most likely should be attributed to platelet preservation. Furthermore, aprotinin lessened neutrophilic elastase release, which might contribute to decreased pulmonary dysfunction in patients at risk.     

Leukocyte activation during cardiopulmonary bypass: limitations of the inhibitory mechanisms and strategies

Cardiopulmonary bypass, initiates a generalised response, which is primarily defensive in nature. This response is self regulated and terminated spontaneously. Obvious problems are complement and leucocyte activation, but several other cascades are also stimulated, which interact, accentuate or modulate this response. These supporting cascades include, release of inflammatory cytokines, an activation of kallikrein system, clotting and fibrinolytic mechanisms, and arachidonic acid metabolism. Because of an effective autoregulatory mechanism, only a small proportion of patients (<3%), undergoing cardiopulmonary bypass are adversely effected by this process. Prognosis of these patients is often unpredictable, but in general, high risk patients are likely to suffer most. A number of specific and non specific artificial measures have been introduced to control postperfusion problems, resulting from this process. These control measures are usually effective against a specific component of this generalised problem, and often fail to achieve desired effects. Efficacy of control measures is further limited by a continued activation of complement and leucocytes, via interactions between the mentioned inflammatory cascades. In view of these limitations, we have introduced certain modifications in our previously reported control strategy. These include an early identification of high risk and susceptible individuals and using specific inhibitors of complement activation for both initial and terminal stages.     

Heparin-level-based anticoagulation management during cardiopulmonary bypass: a pilot investigation on the effects of a half-dose aprotinin protocol on postoperative blood loss and hemostatic activation and inflammatory response

Cardiac surgery involving cardiopulmonary bypass (CPB) leads to activation of the hemostatic/inflammatory system. We compared the influence of a half-dose aprotinin regimen on postoperative blood loss and the activation of the hemostatic/inflammatory system during CPB, when used during a heparin-level-based heparin management for cardiac surgery. Two-hundred patients (n = 100 in each group) were enrolled in this randomized prospective study. In Group I only heparin was given according to the results of the Hepcon HMS Plus. In Group II aprotinin was added with a bolus of 1 x 10(6) kallikrein inhibiting units (KIU) for the patient immediately before initiation of CPB, 1 x 10(6) KIU in the priming solution of the CPB, and a continuous infusion of 250,000 KIU/h during CPB. Postoperative blood loss was determined after 12 h. Heparin and antithrombin activity were evaluated by an anti-Xa assay and measurement of antithrombin III activity. Hemostatic activation was evaluated by adenosine diphosphate-stimulated platelet aggregometry and by measurements of the generation/release of beta-thromboglobulin (beta-TG), soluble P-selectin (sPS), thrombin (TAT), prothrombin 1 and 2 fragments (PTF1+2), factor XIIa (FXIIa), plasmin (PAP), and D-dimers. Inflammatory response was evaluated by measuring complement factors 5b-9 (C5b-9), interleukin (IL)-6, and neutrophil elastase (NE). There were no differences in the pre-CPB values or duration of CPB between the two groups. There were no differences in the post-CPB values for platelet count, platelet aggregation, beta-TG, sPS, TAT, PTF1+2, C5b-9, NE, or IL-6. The additional use of aprotinin resulted in a significant decrease of PAP, D-dimers, and 12 h postoperative blood loss, whereas generation of the contact factor XIIa was increased. The administration of aprotinin significantly reduced postoperative blood loss after cardiac surgery and CPB. This most likely has to be attributed to the antifibrinolytic effects of aprotinin. No effects on thrombin generation, platelet activation, inflammatory response, or clinical outcome were noted. IMPLICATIONS: The use of half-dose aprotinin and heparin-level-based anticoagulation management during cardiopulmonary bypass leads to a significant reduction of postoperative blood loss after cardiac surgery. This effect can most likely be attributed to the antifibrinolytic effects of aprotinin, as we did not observe effects on other variables of activation of the hemostatic/inflammatory system.     

Assessment of hemostatic activation during cardiopulmonary bypass for coronary artery bypass grafting with bivalirudin: results of a pilot study

OBJECTIVE: Bivalirudin has been successfully used as a replacement for heparin during on-pump coronary artery bypass grafting. This study was conducted to assess the effects of the currently suggested protocol for bivalirudin on hemostatic activation during cardiopulmonary bypass with and without cardiotomy suction. METHODS: Ten patients scheduled for coronary artery bypass grafting were enrolled. Bivalirudin was given with a bolus of 50 mg in the priming solution and 1.0 mg/kg for the patient, followed by an infusion of 2.5 mg . kg(-1) . h(-1) until 15 minutes before the conclusion of cardiopulmonary bypass. Cardiopulmonary bypass was performed with a closed system in 5 patients with and in 5 patients without the use of cardiotomy suction. Blood samples were obtained before and after cardiopulmonary bypass. D-dimers, fibrinopeptide A, prothrombin 1 and 2 fragments, thrombin-antithrombin, and factor XIIa were determined. RESULTS: Values for factor XIIa remained almost unchanged in both groups, indicating a minor effect of contact activation. In patients without cardiotomy suction, post-cardiopulmonary bypass values for D-dimers, fibrinopeptide A, prothrombin 1 and 2 fragments, and thrombin-antithrombin were not significantly increased compared with pre-cardiopulmonary bypass values. In patients with cardiotomy suction, values obtained for these parameters had significantly increased compared with pre-cardiopulmonary bypass values and the values obtained in the group without cardiotomy suction after cardiopulmonary bypass. CONCLUSIONS: With this protocol, hemostatic activation during cardiopulmonary bypass was almost completely attenuated when cardiotomy suction was avoided. Cardiotomy suction results in considerable activation of the coagulation system and should therefore be restricted and replaced by cell saving whenever possible.     

Decreased concentration of antithrombin after preoperative therapeutic heparin does not cause heparin resistance during cardiopulmonary bypass

OBJECTIVE: To determine if preoperative heparin therapy causes an increase in the incidence of intraoperative heparin resistance by reducing the concentration of antithrombin in plasma. DESIGN: Prospective laboratory investigation of clinical samples. SETTING: Public tertiary care hospital and public pathology service. PARTICIPANTS: Forty-six patients undergoing cardiac surgery involving cardiopulmonary bypass. INTERVENTIONS: Fourteen patients received preoperative heparin therapy (POHI group) and 32 patients were controls (CONT group). MEASUREMENTS AND MAIN RESULTS: The concentration of antithrombin, activated coagulation time (ACT), and clinical parameters were measured at intervals. More POHI patients had on-bypass heparin resistance than CONT (43% and 3%, respectively, p < 0.01). The POHI group had a lower concentration of antithrombin than the CONT group before (80.9% and 92.6%, respectively, p < 0.01) and while on cardiopulmonary bypass (51.6% and 57.5%, respectively, p = 0.04). Comparison of heparin-resistant and heparin-responsive POHI patients showed that the concentration of antithrombin did not differ before bypass (82.4% and 79.8%, respectively, p = 0.53) or during bypass (51.8% and 51.4%, respectively, p = 0.91). In fact, antithrombin concentrations were slightly higher in the heparin-resistant POHI patients (not significant). POHI patients received more heparin than CONT patients (medians 787 U/kg and 600 U/kg, respectively, p = 0.01) and were transfused with more fresh frozen plasma on bypass (p = 0.03). CONCLUSIONS: Preoperative heparin causes an increased incidence of heparin resistance and reduced antithrombin concentrations. However, heparin resistance was not causally related to reduced antithrombin because antithrombin concentrations were not different between heparin-resistant and heparin-responsive patients in the POHI group.     

心肺转流围术期血浆肝素浓度的变化

目的　心肺转流 (CPB)围术期血浆肝素浓度的变化及其与抗凝监测、肝素中和及肝素反跳的关系。方法　 10例成人CPB心脏手术病人 ,于麻醉后肝素前、肝素 1、2、3、4、5、10min、CPB前、CPB后 5、10、30min、停机、中和 1∶0 5、1∶0 75、1∶1、中和结束及术后 1～ 6h采血。分别测定血浆肝素浓度 (应用发色底物抗Xa方法 ) ,激活部分凝血致活酶时间 (APTT)、凝血酶时间 (TT)及激活全血凝固时间 (ACT)。结果　静注肝素 (4 0 0U/kg)后 1min血浆浓度达高峰为 (6 4 6± 1 0 5 )U/ml,到CPB开始时为 (4 2 8± 0 30 )U/ml,停机时为 (2 82± 0 4 1)U/ml。CPB前血浆肝素浓度与ACT显著相关 (r =0 896 ,P <0 0 1)。首次中和 (比值为 1∶0 5 )后肝素浓度为 (0 12± 0 10 )U/ml。术后 3～ 4h肝素浓度重新升高 (与基础值相比P <0 0 1) ,但与ACT、APTT及TT均无相关性 (P >0 0 5 )。结论　CPB前ACT能可靠监测肝素抗凝 ;CPB后鱼精蛋白首次按 1∶0 5已基本能中和游离的肝素 ;总比例 1∶1 5后 ,无肝素反跳     

两种氧合器对心肺转流炎症反应的影响

目的动态监测室间隔缺损修补术患者在心肺转流(CPB)各时段血清可溶性细胞间粘附分子(sICAM-1)、可溶性E-选择素(sE-selection)及肿瘤坏死因子α(TNF-α)的变化规律,并比较西京-90鼓泡式氧合器和希健-Ⅱ膜式氧合器对其的影响。方法选择择期行室间隔缺损修补术的患者30例,随机均分为鼓泡式氧合器组(B组)和膜式氧合器组(M组)。所有患者分别在麻醉后CPB开始前(T1)、主动脉阻断开放前(T2)、CPB结束时(T3)、术后2h(T4)、6h(T5)、24h(T6)及48h(T7)取静脉血5ml用ELISA法测定sICAM-1、sE-selection及TNF-α的浓度。结果两组患者血清中的TNF-α于T2时开始显著升高,T4时达到峰值(P<0·01)。sICAM-1于T5时开始升高,T6时达峰值。sE-selection于T4时开始升高,T5时达峰值(P<0·01)。M组大部分时点TNF-α、sICAM-1、sE-selection的浓度均低于B组。结论希健-Ⅱ膜式氧合器引起的炎症反应较轻。     

Real time measurement of heparin concentration during cardiopulmonary bypass

BACKGROUND: A heparin/protamine titration system for measurement of heparin levels (Hepcon) is promising for efficient anticoagulation during cardiopulmonary bypass (CPB). METHODS: Fifty-seven patients subjected to CPB were divided into two groups, control (n = 24) and Hepcon groups (n = 33). The Hepcon group was further divided into three subgroups according to perfusion temperature. For the control group, conventional administration of an anticoagulant (300 IU/kg of heparin) and reversal protocol (heparin 1: protamine 1) was performed. For the Hepcon group, a heparin dose-response assay directed the initial dose of heparin. Hepcon also determined the dose of protamine by the titration. The initial dose of heparin in the control group (300 IU/kg) was statistically less than that of Hepcon group (360+/-80 IU/kg). RESULTS: In the Hepcon group, the sensitivity to heparin was correlated with coagulation time (r = -0.78) and antithrombin III levels (r = 0.70), and individual difference of sensitivity resulted in a wide range of dosage (160 to 490 IU/kg). A strong correlation was observed between plasma and whole blood concentration of heparin (r = 0.86). However, they did not correlate with ACT values. Perfusion temperature didn't affect the heparin level, but did the ACT value. In the Hepcon group, the dose of protamine was significantly less and adverse events were rare. CONCLUSIONS: In conclusion, whole blood heparin measurements correlated well with plasma heparin concentration. Protamine titration of heparin reduced the dose of protamine and decreased the chance of adverse reactions.