Heparin-coated cardiopulmonary bypass circuits reduce blood cell trauma. Experiments in the pig

Blood cell trauma and postoperative bleeding remain important problems in cardiopulmonary bypass (CPB). We compared heparin-coated with non-coated circuits in the pig. Twenty animals were perfused for 2 h at normothermia using membrane oxygenators (Bentley Bos 50). Two groups were studied. In the non-coated group (NC, n = 11) the CPB circuits used were without a heparin coating. This group had systemic heparinization of 400 IU/kg to maintain an ACT (activated clotting time) of over 400 s during CPB. In the coated group (C, n = 9), all surfaces exposed to blood in the CPB circuits were heparin-coated. This group had the heparin dose reduced to 25% (100 IU/kg) without further administration regardless of ACT. During CPB, group C displayed shorter ACT (per definition), higher platelet count, platelet adhesion and lower fibrinolysis and haemolysis (P less than 0.05) as compared to group NC. No thromboembolic events were detected during CPB. Three animals in group NC and 4 animals in group C were weaned from CPB and protaminized. Four hours postoperatively, the leucocyte consumption was two-fold greater and blood loss about four-fold greater in group NC as compared with group C (P less than 0.05). Perfusion with heparin-coated surfaces reduces blood cell trauma. The decreased postoperative blood loss observed in group C is probably explained by the reduced dosages of heparin and protamine.     

Heparin-coated Cardiopulmonary Bypass Circuits in Coronary Bypass Surgery

Abstract: Cardiopulmonary bypass (CPB) is a nonphysiologic environment for an organism. The damage of blood components may also lead to organ dysfunction, sometimes recognized as postperfusion syndrome. One possible way to diminish the risk of these complications would be to reduce the thorombogenicity and to improve the biocompatibility of the artificial surfaces by using a heparin-coated CPB circuit. In this study, we compared a heparin-coated CPB circuit with a noncoated CPB circuit in terms of biocompatibility in 20 patients undergoing elective coronary bypass surgery. We employed a Dura-flo II (n = 10) as a heparin-coated CPB circuit and a Univox IC (n = 10) as control subjects. Ten patients (Group C) were operated on using the heparin-coated CPB circuit. A total of 10 patients were given heparin in a reduced dose (2.0 mg/kg), and additional heparin was given if the activated clotting time (ACT) was below 400 s. The control group also included 10 patients (Group NC), who were operated on with noncoated devices. They received 2.5 mg/kg of heparin, and additional heparin was given if the ACT was below 450 s. All patients had normal coagulation parameters and did not receive blood transfusion. We measured complement activation levels (C3a, C4a), platelet count, thrombin-antithrombin III complex levels, D-dimer levels, and ACT during CPB and respiratory index postoperatively. The concentration of C3a in group NC was significantly higher than that in group C. Platelet reduction in group NC was significantly greater than that in group C. There were no significant differences in the remaining parameters between the 2 groups. We concluded that heparin-coated CPB circuits improved biocompatibility by reducing complement activation and platelet consumption and enabled us to reduce the dose of heparin required for systemic heparinization.     

Low dose systemic heparinization combined with heparin-coated extracorporeal circulation. Effects related to platelets

BACKGROUND: A heparin coated cardiopulmonary bypass system combined with full and low dose systemic heparinization in coronary bypass surgery was investigated in a prospective, randomised study. Roller pumps, coronary suction and an open cardiotomy reservoir were used. METHODS: One hundred and nineteen patients were divided into 3 groups: group A (n=39) had a standard uncoated extracorporeal circulation (ECC)-set and systemic heparin was given in an initial dose of 400 IE/kg body weight. During ECC activated clotting time (ACT) was kept at = or >480 sec. Group B (n=42) had the same ECC-set completely coated with low molecular weight heparin, i.v. heparin was administered in the same dose as in group A, ACT was again kept at = or >480 sec. Group C (n=38) had the same coated ECC set as group B, but i.v. heparin was reduced to 150 IE/kg and during ECC ACT was maintained of = or >240 sec. RESULTS: Platelet decrease was significantly less in both groups utilizing coated circuitry as compared to control group A. Activation of thrombocytes as marked by b-thromboglobulin (not PF4) was significantly decreased in patients treated with coated circuits combined with low dose systemic heparinization and postoperative bleeding was significantly reduced. CONCLUSIONS: We conclude that in heparin coated extracorporeal circulation combined with either full dose or reduced systemic heparinization compared to uncoated circuits platelet count reduction is significantly less. Platelet activation as marked by b-thromboglobulin and postoperative blood loss are decreased with coated equipment and low i.v. heparinization.     

In vitro effect of fresh frozen plasma on the activated coagulation time in patients undergoing cardiopulmonary bypass

The in vitro effect of fresh frozen plasma (FFP) on the whole blood activated coagulation time (ACT) was examined in 18 patients undergoing cardiopulmonary bypass (CPB) during coronary artery bypass graft surgery. The addition of FFP to whole blood in vitro, after systemic heparinization, significantly prolonged the ACT from 451 +/- 21 seconds (mean +/- SE) to 572 +/- 41 seconds (P less than 0.05). There was no significant correlation between the plasma antithrombin III activity and the prolongation in ACT after systemic heparinization, with or without addition of FFP. The addition of FFP to whole blood in three of the six patients who exhibited heparin resistance (ACT less than 400 seconds after administration of 350 unit/kg heparin) did not prolong the ACT to greater than 400 seconds. These observations suggest that infusion of FFP will further prolong the ACT after heparin administration in most patients including some with initial heparin resistance.     

The relationship between hirudin and activated clotting time: implications for patients with heparin-induced thrombocytopenia undergoing cardiac surgery.

Anticoagulation with recombinant hirudin (r-hirudin) (Refludan) has been suggested as an alternative to heparin for patients with heparin-induced thrombocytopenia requiring cardiac surgery. We sought to develop a modified activated coagulation time (ACT) that would allow quantification of the levels of r-hirudin required during cardiopulmonary bypass (CPB). Twenty-one patients scheduled for elective cardiac surgical procedures requiring CPB were enrolled in this IRB-approved study. R-hirudin was added to blood specimens obtained before heparin administration (before CPB) and 30 min after heparin neutralization with protamine (after CPB) to result in concentrations of 0, 2, 4, 6, 7, or 8 microg/mL. Kaolin/ACT and complete blood count measurements were assayed in native specimens (first 10 patients, Phase I) or in specimens mixed with equal volumes of commercial normal plasma (second 11 patients, Phase II). In Phase I, good (r(2) = 0.83) linear relationships between ACT values and r-hirudin concentrations (< or =4 microg/mL) were observed in specimens obtained before CPB. However, ACT values were markedly prolonged (P < 0.0001) by r-hirudin in specimens obtained after CPB, with ACT values generally exceeding the ACT's detection limit (>999 s) at hirudin concentrations >2 microg/mL. In patient specimens mixed with normal plasma (Phase II), ACT/hirudin relationships (i.e., hirudin/ACT slope values obtained with hirudin concentration < or =4 microg/mL) in the post-CPB period (0.022 +/- 0.004 microg. mL(-1). s(-1)) were similar (P = 0.47) to those (0.019 +/- 0.004 microg. mL(-1). s(-1)) obtained in the pre-CPB period. Accordingly, a significant relationship between normal plasma-supplemented ACT values and predilution hirudin concentration was obtained in the post-CPB (hirudin = 0.039ACT - 4.34, r(2) = 0.91) period. Although our data demonstrate that the ACT test cannot be used to monitor hirudin during CPB, the addition of 50% normal plasma to post-CPB hemodiluted blood specimens yields a consistent linear relationship between hirudin concentration and ACT values up to a predilution concentration of 8 microg/mL. Plasma-modified ACT may be useful in monitoring hirudin anticoagulation during CPB. Implications: A modified activated clotting time test system that may be helpful in monitoring hirudin anticoagulation in patients with heparin-induced thrombocytopenia during cardiac surgery with cardiopulmonary bypass is described.     

Safety of heparin-coated circuits in primates during deep hypothermic cardiopulmonary bypass

The purpose of this study is to evaluate the biologic impact of heparin-coated circuits without systemic heparinization during deep hypothermia. Baboons (n=6) were placed on a heparin-coated pediatric closed-circuit cardiopulmonary bypass (CPB) system and cooled to 18 degrees C. A control group (n=7) underwent similar protocol with a non heparin-coated circuit and received systemic heparin. Either low flow at 0.5 L/min/m 2 (n=8; 4 in each group) or circulatory arrest (n=5; 2 in experimental group and 3 in control group) was used during deep hypothermia. Samples for complete blood count (CBC), hepatic and renal function tests, activated clotting time (ACT) and thrombelastogram (TEG) were obtained before, during, and after bypass. Cerebral blood flow was measured using Xenon-133 and autopsies were performed to assess end-organ damage. The ACT returned to baseline in both groups, and renal and hepatic function were within normal limits. There was no significant difference between the TEG values between the groups post bypass. Fibrin split products were absent and fibrinogen levels were normal in both groups following bypass. Cerebral blood flows were equivalent in both groups before and after bypass, although in the heparin-coated group cerebral blood flows were significantly higher during CPB. There were no brain histologic changes in the heparin-coated group and one focal cortical infarct in the control group. This study suggests that hypothermia induced a state of anticoagulation that did not result in thrombus formation or end organ dysfunction during CPB with a heparin-coated circuit.(ABSTRACT TRUNCATED AT 250 WORDS)     

Heparin monitoring during cardiopulmonary bypass surgery using the one-step point-of-care whole blood anti-factor-Xa clotting assay heptest-POC-Hi

The activated clotting time (ACT) generally used for monitoring heparinization during cardiopulmonary bypass (CPB) surgery does not specifically measure heparin anticoagulant activities. This may result in heparin over- or under-dose and subsequent severe adverse events. A new point-of-care whole blood clotting assay (Heptest POC-Hi [HPOCH]) for quantifying heparin anticoagulant activity specifically was compared with ACT and anti-factor Xa (anti-Xa) heparin plasma levels (Coatest heparin) in 125 patients undergoing CPB surgery. The analytical reliability of the HPOCH and the influence of preanalytical variables on assay results were also examined. The ACT and HPOCH clotting times determined throughout the entire observation period correlated closely (n=683; r = 0.80; p < .0001). Similarly, there was a significant linear correlation between HPOCH and Coatest anti-Xa levels (n=352; r = 0.87; p < .0001). Pre- and post-CBP values of HPOCH, ACT, and anti-Xa plasma levels correlated closely with each other (correlation coefficients between r = 0.90 and r = 0.99; p < .0001). During CPB, there was no significant relationship between ACT and whole blood or plasma heparin levels determined by HPOCH (n=157; r = 0.19) and the chromogenic anti-Xa assay (n=157; r = 0.04), respectively. In contrast, HPOCH and anti-Xa plasma levels correlated strongly during CPB (n=157; r = 0.57; p < .0001). However, bias analysis showed that the HPOCH and Coatest heparin could not be used interchangeably. The HPOCH was well reproducible and not influenced by aprotinin, hemodilution, or other factors affecting ACT. The HPOCH seems to be a promising new tool for specific on-site measurement of heparin activities in whole blood during CPB.     

Superior hemodynamics in left heart bypass without systemic heparinization

Open-chest left heart bypass was performed in 10 canine experiments (30 +/- 9 kg) by a servo controlled roller pump for 6 h at a pump flow of 50 ml/min per kg bodyweight. The surfaces of the tubing sets were either standard (with systemic heparinization) or with end-point attached heparin (no systemic heparin). Besides continuous monitoring of hemodynamics, a standard battery of blood samples was taken before bypass, after 10 min and every hour thereafter. There is no evidence of increased fibrin production in the group with end-point attached heparin surfaces perfused without systemic heparinization. Superior hemodynamics in left heart bypass performed without systemic heparinization appear to be due to improved hemostasis, reduced blood loss and therefore reduced transfusion requirements. Left heart bypass with heparin-coated equipment has been successfully used for resection of a thoracoabdominal aneurysm in six patients.     

Effects of acute arginine loading on renal and systemic hemodynamics in dogs.

Effects of L-arginine (ARG) infusion on renal and systemic hemodynamics were studied in 12 anesthetized dogs. The experiment was performed in two groups of dogs. The dogs of group 1 (n = 6) received intravenous ARG at 2.5 mmol/kg followed by indomethacin (IND) injection (10 mg/kg) and were rechallenged with ARG at the same amount. The dogs of group 2 (n = 6) received intravenous ARG at 5 mmol/kg followed by IND injection (10 mg/kg) and were later infused with ARG at the same dose. In group 1, the first ARG infusion caused no significant changes in renal and systemic hemodynamics. During the second ARG infusion, glomerular filtration rate (GFR) and renal plasma flow (RPF) were significantly increased when compared with the IND-treated period. In group 2, the first ARG infusion increased cardiac output (CO) and decreased total peripheral resistance (TPR) without significant changes in GFR and RPF. The second ARG infusion induced acute rise of both GFR and RPF approximately twofold, compared with the IND-treated period. CO was also increased significantly. Plasma glucagon levels determined in 2 dogs showed an increase following both ARG infusions. These results indicate that an acute ARG loading induces renal and systemic vasodilatation in a dose-dependent manner despite IND effect, and would indicate that increased renal hemodynamics are not prostaglandin-mediated.     

Safety and efficacy of a heparin removal device: a prospective randomized preclinical outcomes study

BACKGROUND: Systemic protamine sulfate for heparin reversal after cardiopulmonary bypass (CPB) is associated with uncommon, but life-threatening adverse reactions. METHODS: In a prospective randomized 3-day outcomes study, a heparin removal device (HRD) group (n = 12; 60-, 80-, 100-kg subgroups) was compared with a matched systemic Protamine group (Protamine; n = 6) for safety and efficacy using an adult swine model of CPB (60 minutes, 28 degrees C). RESULTS: HRD run time was 25 to 38 minutes depending on weight without complications. After HRD, heparin concentration decreased from 4.77 +/- 0.17 to 0.45 +/- 0.06 U/mL (activated clotting time [ACT] 776 +/- 83 to 180 +/- 12 seconds), and in Protamine, 3.94 +/- 0.63 to 0.13 +/- 0.02 U/mL (ACT 694 +/- 132 to 101 +/- 5 seconds) (p = 0.01 between groups, but no significant differences 60 minutes later). No significant difference between HRD and Protamine to 72 hours was seen in plasma-free hemoglobin C3a, heparin concentration, thromboelastogram index, platelet count, activated partial thromboplastin time, anti-thrombin III, fibrinogen, ACT, and tissue histology. CONCLUSIONS: In a prospective randomized outcomes study, HRD achieved predictable reversal of systemic heparinization after CPB with no difference in safety or outcomes compared with protamine.     

Argatroban as a potential anticoagulant in cardiopulmonary bypass-studies in a dog model.

Argatroban is a selective thrombin inhibitor synthesized in Japan. Argatroban, which has a high affinity for thrombin, and markedly inhibits thrombin-induced reactions, has been used in patients with artherosclerosis obliterans. The efficiency of argatroban, instead of heparin, as an anticoagulant in dog models of cardiopulmonary bypass was explored. In the first study, argatroban was administered as a bolus plus infusion for 1 h during cardiopulmonary bypass at doses of 1.0 mg + 10 microg/kg per min, 2.0 mg + 10 microg/kg per min and 3.0 mg + 10 microg/kg per min (n = 2 per group). Activated clotting time and arterial gas analyses were performed beforehand and 10 min thereafter. In the second study, there were four groups. In the first group (n = 5), no coated extracorporeal circuit was used and heparin (2 mg/kg) was used as an anticoagulant. In the second group (n = 5), a coated extracorporeal circuit was used and heparin was used (2 mg/kg) as an anticoagulant. In the third group (n = 3), no coated extracorporeal circuit was used and argatroban (2.0 mg + 10 microg/kg per min) was used as an anticoagulant. In the fourth group (n = 5), a coated extracorporeal circuit was used and argatroban was used (2.0 mg + 10 microg/kg per min) as an anticoagulant. All animals were perfused for 120 min at 40 ml/kg per minute. Platelet count, activated clotting time, thrombin-antithrombin III complex, antithrombin III, fibrinogen, fibrinogen degradation products and C3a were measured to evaluate platelet, coagulofibrinolytic and the complement system. Activated clotting time values and the effect of argatroban during cardiopulmonary bypass indicated a dose-dependent response. The next highest dosing group (2.0 mg + 10 microg/kg per minute) had activated clotting time values of 250-300 seconds during cardiopulmonary bypass, and fell after reaching near-normal levels within 60 minutes. No clots were noted in the extracorporeal circuit. The argatroban group showed lower levels in their coagulofibrinolytic system compared with the heparin group. The platelet count remained at a high level in the argatroban group. It is concluded that the combination of heparinized cardiopulmonary bypass circuits, and the use of argatroban as an anticoagulant, is safe and reduces the activation of coagulation and fibrinolytic systems and preserves platelet count.     

Monitoring activated clotting time for combined heparin and aprotinin application: in vivo evaluation of a new aprotinin-insensitive test using Sonoclot.

OBJECTIVE: Kaolin-based activated clotting time assessed by HEMOCHRON (HkACT) is a clinical standard for heparin monitoring alone and combined with aprotinin during cardiopulmonary bypass (CPB). However, aprotinin is known to prolong not only celite-based but also kaolin-based activated clotting time. Overestimation of activated clotting times implies a potential hazardous risk of subtherapeutic heparin anticoagulation. Recently, a novel 'aprotinin-insensitive' activated clotting time test has been developed for the SONOCLOT analyzer (SaiACT). The aim of our study was to evaluate SaiACT in patients undergoing CPB in presence of heparin and aprotinin. METHODS: Blood samples were taken from 44 elective cardiac surgery patients at the following measurement time points: baseline (T0); before CPB after heparinization (T1 and T2); on CPB, before administration of aprotinin (T3); 15, 30, and 60 min on CPB after administration of aprotinin (T4, T5, and T6); after protamine infusion (T7). On each measurement time point, activated clotting time was assessed with HkACT and SaiACT, both in duplicate. Furthermore, the rate of factor Xa inhibition and antithrombin concentration were measured. Statistical analysis was done using Bland and Altman analysis, Pearson's correlation, and ANOVA with post hoc Bonferroni-Dunn correction. RESULTS: Monitoring anticoagulation with SaiACT showed reliable readings. Compared to the established HkACT, SaiACT values were lower at all measurement time points. On CPB but before administration of aprotinin (T3), SaiACT values (mean+/-SD) were 44+/-118 s lower compared to HkACT. However, the difference between the two measurement techniques increased significantly on CPB after aprotinin administration (T4-T6; 89+/-152 s, P=0.032). Correlation of ACT measurements with anti-Xa activity was unchanged for SaiACT before and after aprotinin administration (r2=0.473 and 0.487, respectively; P=0.794), but was lower for HkACT after aprotinin administration (r2=0.481 and 0.361, respectively; P=0.041). On CPB after administration of aprotinin, 96% of all ACT values were classified as therapeutic by HkACT, but only 86% of all values were classified therapeutic if ACT was determined by SaiACT. Test variability was comparable for SaiACT and HkACT. CONCLUSIONS: The use of SaiACT may result in more consistent heparin management that is less affected by aprotinin and a corresponding increase in heparin administration for patients receiving aprotinin.     

The Use of Bivalirudin for Cardiopulmonary Bypass Anticoagulation in Pediatric Heparin‐Induced Thrombocytopenia Patients

Infants with heparin‐induced thrombocytopenia (HIT) represent a challenging and high‐risk group of patients when they require cardiopulmonary bypass (CPB). Bivalirudin offers many potential pharmacologic advantages over other nonheparin anticoagulants for such patients. We describe our protocol for the use of bivalirudin in a 5‐month‐old infant undergoing stage 2 Norwood for hypoplastic left heart syndrome. The patient was a 5‐ month‐old, 6‐kg infant who developed HIT after a bowel resection complicating initial Norwood stage 1. After sternotomy and dissection had been redone, the child received an initial dose of bivalirudin of 1.0 mg/kg and 0.5 mg/kg 5 min later. The CPB circuit was primed with 50 mg/kg bivalirudn/400 cc volume. With the initiation of CPB, a continuous infusion of 2.5 mg/kg bivalirudin was begun. Activated clotting time (ACT) was targeted for over 400 s, with an examination prior to bypass and each 15 min thereafter. Bivalirudin was discontinued with separation from bypass and during modified ultrafiltration (MUF). The ACT was 286 s after the initial 1 mg/kg bolus and 597 s after the second 0.5 mg/kg bolus and initiation of CPB. At a rate of 2.5 mg/kg/min, ACT ranged between 461 and 597 s. At the completion of MUF, the ACT was 316 s. The ACT was 214 s 20 min after MUF. No clots were noted in the CPB circuit, and good hemostasis was achieved within 10 min after MUF was completed. Incision to closure time was 160 min; time from completion of MUF to sternal closure was 30 min. Post‐MUF, 60 cc of processed cell saver blood was reinfused, and no clotting factors were required. Chest tube output was 10, 10, 3, and 4 ccs, respectively, at hours 1–4 post operation. Bivalirudin provides effective anticoagulation in infants requiring CPB in the presence of HIT. Bivalirudin's efficacy is effectively monitored by ACT, and, after CPB, its short half‐life and ability to be ultrafiltered facilitate the ability to achieve hemostasis in a timely fashion.     

High dose thrombin time versus the activated clotting time during cardiopulmonary bypass

In this study we compared the High Dose Thrombin Time (HiTT) with the Activated Clotting Time (ACT) during cardiopulmonary bypass (CPB) in non-aprotinin treated patients. On the advice of the HiTT test manufacturer each institution should perform comparative ACT/HiTT assays in the cardiac surgery population. In previous tests our target ACT value of 480 seconds corresponds with a mean HiTT value of 190 seconds. Our results showed that after heparinization (300-400 IU/kg body weight) 8 out of 20 patients did not reach the target ACT of 480 seconds, while the HiTT results in those 8 patients were higher than our target time of 190 seconds. Four heparin pretreated patients who received 400 IU/kg heparin, had relatively low ACT values (467 +/- 14 sec.) and high HiTT values (324 +/- 47 sec.). Before and during CPB there was a poor correlation between the HiTT and ACT (r = 0.38). The results of this study show that for the individual patient the target HiTT of 190 seconds is no guarantee for reaching an adequate ACT of 480 seconds. Although the HiTT may be a very useful assay for monitoring heparin effects during CPB, the determination of the target time can be a point of discussion. In contrast of the advice of the manufacturer we therefore suggest that comparative ACT/HiTT assay should be done in every individual patient to determine a safe target HiTT time, instead of the whole group of patients.     

The plasma supplemented modified activated clotting time for monitoring of heparinization during cardiopulmonary bypass: a pilot investigation

The standard celite or kaolin activated clotting time (ACT) correlates poorly with heparin levels during cardiopulmonary bypass (CPB). We compared a modified kaolin ACT, in which plasma was supplemented, to a standard undiluted kaolin ACT for monitoring heparin levels during CPB. Fifteen patients undergoing normothermic CPB were enrolled in this prospective study. Heparin management was performed according to the Hepcon HMS results (Medtronic, Minneapolis, MN). The ACTs were performed with the ACT II device (Medtronic). Hepcon HMS calculations, standard kaolin ACTs, and plasma supplemented modified ACTs (mACTs), prepared by diluting blood samples 1:1 with human plasma (Behring, Marburg, Germany), were measured every 30 min during CPB. The data obtained were correlated to the plasma chromogenic anti-Xa activity as a reference assay for heparin levels. A total of 64 samples were evaluated. The chromogenic anti-Xa activity ranged from 0.2 to 5.5 IU/mL. The Hepcon HMS calculations ranged from 2.7-8.2 IU/mL of heparin, the standard ACT ranged from 424 to >999 s, and the mACT ranged from 210 to 801 s. The correlation to the chromogenic anti-Xa method was r = 0.43 for the standard kaolin ACT and r = 0.69 for the plasma mACT. The plasma mACT provided an improved correlation to chromogenically measured levels of anti-Xa activity during CPB. The improved correlation most likely results from a correction of the effects of the impairment of the coagulation system caused by hemodilution and consumption of procoagulants on extracorporeal surfaces. IMPLICATIONS: During cardiopulmonary bypass, the plasma modified kaolin activated clotting time (ACT) provides a better correlation with heparin levels than the standard kaolin ACT.     

Heparin-Coated Extracorporeal Circulation with Full and Low Dose Heparinization: Comparison of Thrombin Related Coagulatory Effects

Thrombin related coagulatory effects of a heparin-coated cardiopulmonary bypass system combined with full and low dose systemic heparinization were investigated in a prospective, randomized study in coronary bypass surgery patients. One hundred nineteen patients were divided into 3 groups. Group A (n = 39) had a standard uncoated extracorporeal circulation (ECC) set, and systemic heparin was administered in an initial dose of 400 IU/kg body weight. During ECC activated clotting time (ACT) was maintained at > or =480 s. Group B (n = 42) had the same ECC set completely coated with low molecular weight heparin. Intravenous heparin was given in the same dose as in Group A, and ACT was kept at the same level. Group C (n = 38) had the same coated ECC set as Group B, but intravenous heparin was reduced to 150 IU/kg, and during ECC, ACT was set to be > or =240 s. The same ECC components were used in all 3 groups including roller pumps, coronary suction, and an open cardiotomy reservoir. Thrombin generation as indicated by F1/F2 was significantly elevated at an ECC duration >60 min if heparin-coated ECC combined with low dose systemic heparinization was employed. Complexed thrombin (TAT) was significantly elevated after administration of protamine. Release of D-dimers indicating fibrinolysis was not significantly different between groups. Signs of clinical thromboembolism, i.e., postoperative neurological deficit, occurred in 2 patients in Group A and 1 patient in Group C. We conclude that heparin-coated extracorporeal circulation combined with reduced systemic heparinization intraoperatively leads to significantly increased thrombin generation, but not to increased fibrinolysis.     

A prospective,double-blind study on the efficacy of the bioline surface-heparinized extracorporeal perfusion circuit

BACKGROUND: We evaluated the newly introduced Bioline heparin coating and tested the hypothesis that surface heparinization limited to the oxygenator and the arterial filter will ameliorate systemic inflammation and preserve platelets during cardiopulmonary bypass (CPB). METHODS: In a prospective double-blind study, 159 patients underwent coronary revascularization using closed-system CPB with systemic heparinization, mild hypothermia (33 degrees C), a hollow-fiber oxygenator, and an arterial filter. The patients were randomly divided in three groups. In group A (controls, n = 51), surface heparinization was not used. In group B (n = 52), the extracorporeal circuits were totally surface-heparinized with Bioline coating. In group C (n = 56), surface heparinization was limited to oxygenator and arterial filter. RESULTS: No significant difference was noted in patient characteristics and operative data between groups. Operative (30-day) mortality was zero. Platelet counts dropped by 12.3% of pre-CPB value among controls at 15 minutes of CPB, but were preserved in groups B and C throughout perfusion (p = 0.0127). Platelet factor 4, plasmin-antiplasmin levels, and tumor necrosis factor-alpha increased more in controls during CPB than in groups B or C (p = 0.0443, p = 0.0238 and p = 0.0154 respectively). Beta-thromboglobulin, fibrinopeptide-A, prothrombin fragments 1 + 2, factor XIIa levels, bleeding times, blood loss, and transfusion requirements were similar between groups. Intensive care unit stay was shorter in groups B and C than in controls (p = 0.037). CONCLUSIONS: Surface heparinization with Bioline coating preserves platelets, ameliorates the inflammatory response and is associated with a reduced fibrinolytic activity during CPB. Surface heparinization limited to the oxygenator and the arterial filter had similar results as totally surface-heparinized circuits.     

Pharmacokinetics of epsilon-aminocaproic acid in patients undergoing aortocoronary bypass surgery.

BACKGROUND: Epsilon-aminocaproic acid (EACA) is commonly infused during cardiac surgery using empiric dosing schemes. The authors developed a pharmacokinetic model for EACA elimination in surgical patients, tested whether adjustments for cardiopulmonary bypass (CPB) would improve the model, and then used the model to develop an EACA dosing schedule that would yield nearly constant EACA blood concentrations. METHODS: Consenting patients undergoing elective coronary artery surgery received one of two loading doses of EACA, 30 mg/kg (group I, n = 7) or 100 mg/kg (group II, n = 6) after CPB, or (group III) a 100 mg/kg loading dose before CPB and a 10 mg x kg(-1) x h(-1) maintenance infusion continued for 4 h during and after CPB (n = 7). Two patients with renal failure received EACA in the manner of group III. Blood concentrations of EACA, measured by high-performance liquid chromatography, were subjected to mixed-effects pharmacokinetic modeling. RESULTS: The EACA concentration data were best fit by a model with two compartments and corrections for CPB. The elimination rate constant k10 fell from 0.011 before CPB to 0.0006 during CPB, returning to 0.011 after CPB. V1 increased 3.8 l with CPB and remained at that value thereafter. Cl1 varied from 0.08 l/min before CPB to 0.007 l/min during CPB and 0.13 l/min after CPB. Cl2 increased from 0.09 l/min before CPB to 0.14 l/min during and after CPB. Two patients with renal failure demonstrated markedly reduced clearance. Using their model, the authors predict that an EACA loading infusion of 50 mg/kg given over 20 min and a maintenance infusion of 25 mg x kg(-1) x h(-1) would maintain a nearly constant target concentration of 260 microg/ml. CONCLUSIONS: EACA clearance declines and volume of distribution increases during CPB. The authors' model predicts that more stable perioperative EACA concentrations would be obtained with a smaller loading dose (50 mg/kg given over 20 min) and a more rapid maintenance infusion (25 mg x kg(-1) x h(-1)) than are typically employed.     

The treatment of heparin resistance with Antithrombin III in cardiac surgery

PURPOSE: To report three patients who developed heparin resistance during cardiac surgery which was successfully managed with 1000 U Antithrombin III (AT III). CLINICAL FEATURES: We observed heparin resistance prior to cardiopulmonary bypass (CPB) in one patient and during the CPB in two patients. In the first patient who was scheduled for mitral valve replacement, although heparin was administered sequentially up to 500 U x kg(-1) prior the CPB, the ACT value was 354 sec. After 1,000 U ATIII were administered the ACT was 395 sec and CPB was initiated. The ACT remained between 496 and 599 sec throughout CPB and a total of 260 mg protamine sulfate was given. In the other two patients following 300 U x kg(-1) heparin, the ACT was up to 400 sec and CPB was initiated. During CPB, ACT were decreased 360 sec and 295 sec in patients II and III respectively. Although heparin was added 1,500 U, ACT increased to > or = 400 sec could not be achieved. In the second patient ATIII activity was found 10%. After the administration of 1,000 U ATIII, ATIII activity was found to be 67% 40 min later and ACT were increased up to 400 sec. There was no thrombosis within the extracorporeal circuit, additional heparin was not required, less protamine was administered (< or = 3 mg x kg(-1)) and no excessive postoperative bleeding was observed in all patients. CONCLUSION: We recommend that AT III supplementation should be considered to manage heparin resistance prior or during CPB in patients undergoing open heart surgery.     

Heparin-coated circuits reduce myocardial injury in heart or heart-lung transplantation: a prospective, randomized study.

BACKGROUND: The effects of heparin-coated (HC) circuits have been primarily investigated in routine cardiac operations with limited duration of cardiopulmonary bypass (CPB) and ischemia. Their benefits have not been conclusively proven but could be more significant when CPB and ischemic times are longer, such as during heart transplantation (HTx) or heart-lung transplantation (HLTx). METHODS: In a 22-month period, 29 patients undergoing HTx and HLTx were randomly divided into two groups using HC (Duraflo II, n = 14, 10 HTx and 4 HLTx) or uncoated but identical circuits (NHC group, n = 15, 10 HTx and 5 HLTx). All patients received full systemic heparinization (3 mg/kg) during CPB. Plasma endotoxin, interleukin (IL)-6, IL-8, IL-10, IL-12, and cardiac troponin-I were measured before heparin administration, immediately after aortic cross-clamping, 5, 30, 60, 90, 120 minutes, and 12 and 24 hours after aortic declamping. The intensive care unit (ICU) staff and the laboratory technologists were blinded as to the use of HC circuits. RESULTS: No statistically significant differences between groups were found with respect to all baseline values, duration of CPB and aortic cross-clamping, graft ischemic time, doses of heparin, postoperative blood loss and transfusion, peak lactate and creatine kinase-MB isoenzyme values, duration of mechanical ventilation, or length of ICU stay. One patient in each group died during the hospital stay. Patients in the HC group needed more protamine sulfate after CPB. Although endotoxin levels were similar in the two groups, significantly lower IL-6, IL-8, and IL-10 levels were observed 1 hour after aortic declamping in the HC group. The release of cardiac troponin-I was also significantly reduced in the HC group 12 and 24 hours after reperfusion. CONCLUSIONS: The use of HC circuit limits both pro- and anti-inflammatory responses to CPB. It may also reduce myocardial injury after prolonged duration of CPB and ischemia.