Cardiac Surgery: In Vivo Titration of Protamine

Study Description

Brief Summary

Safe use of cardiopulmonary bypass (CPB) requires massive doses of intravenous unfractionated heparin. At end-CPB, residual heparin is neutralized with intravenous injection of protamine sulfate. This prospective, randomized, controlled study will be conducted in 82 voluntary subjects admitted for elective, first intention, cardiac surgery requiring cardiopulmonary bypass. Each will be randomly assigned to one of two groups. The control group will be submitted to a standard protamine infusion of 1.3mg :100U of the total heparin dose given during bypass. The test group will receive an infusion of protamine (over 15 minutes) until activated clotting time (ACT) values (determined every 3 minutes) depict a plateau, sign that the optimal protamine to heparin ratio has been attained. The investigators hypothesize this new in vivo titration method to be as efficient as the standard protocol (adequacy of heparin neutralization, % heparin rebound, bleeding, and transfusion), and potentially safer by its ability to prevent protamine overdose and its deleterious impact on platelet function.15

Principal Objective

Evaluate a new in vivo method of titration of protamine sulfate.

Secondary Objective

Evaluate the impact of this method on the adequacy of heparin neutralization by measuring:

1. platelet count

2. postoperative bleeding

3. transfusion exposure a

4. incidence of heparin rebound

Detailed Description

Protamine sulfate is administered to reverse the anticoagulant effects of heparin upon completion of cardiopulmonary bypass (CPB). In most cases, protamine is given in amounts sufficient to neutralize the total dose of heparin.9 This dose is usually calculated with a ratio of 1.3mg protamine for every 100U heparin given.10 In the literature, reported doses of intraoperatively administered protamine range from 0 to 8mg per 100U of heparin. Given in excess, protamine can, in addition to complement activation and hemodynamic instability,11 induce platelet dysfunctions.12-16 The latter significantly increases both the cost and morbidity of cardiac interventions as it is one of the main causes of postoperative bleeding. The optimal protamine/heparin ratio is difficult to individualize for each patient because of the great interpatient variability in heparin's metabolism4-7 and of the absence of correlation between ACT and heparin's plasma concentration.8 Consumption of heparin may vary from 0.01 to 3.86U/Kg per minute during CPB.30 The exact concentration of remaining circulating heparin at the end of bypass is not easily obtained.

Study Design

Outcome Measures

Primary Outcome Measures

1. Effective heparin neutralization (anti-Xa < 0.3 U/ml) [Pre protamine, 15 min post protamine, 3h post protamine]

Secondary Outcome Measures

1. Frequency of heparin rebound [15 min post protamine and 3 hours post Protamine]

2. Blood losses after surgery and transfusion requirements [discharge]

3. Preservation of the platelet count [Pre operate, Pré Protamine, 15 min post Protamine, 3 hours post Protamine]

Eligibility Criteria

Criteria

Inclusion Criteria:

• First intention, elective, cardiac surgery: either Coronary Artery Bypass Graft (CABG)or valve repair/replacement.

• Patients on preoperative aspirin, clopidogrel or heparin will be included.

Exclusion Criteria:

• Combination of CABG and valve surgery

• Second intention cardiac surgery

• ASA 5 patients

• Pre-existing hemostatic disorder (as evidenced by history)

• Pregnancy

• PLavix < 5 days before de surgery

Contacts and Locations

Locations

Sponsors and Collaborators

• Montreal Heart Institute
• Organon

Investigators

• Principal Investigator: Antoine G Rochon, Montreal Heart Institute

Study Documents (Full-Text)

More Information

Publications

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• Berger RL, Ramaswamy K, Ryan TJ. Reduced protamine dosage for heparin neutralization in open-heart operations. Circulation. 1968 Apr;37(4 Suppl):II154-7.
• Carr ME Jr, Carr SL. At high heparin concentrations, protamine concentrations which reverse heparin anticoagulant effects are insufficient to reverse heparin anti-platelet effects. Thromb Res. 1994 Sep 15;75(6):617-30.
• de Swart CA, Nijmeyer B, Roelofs JM, Sixma JJ. Kinetics of intravenously administered heparin in normal humans. Blood. 1982 Dec;60(6):1251-8.
• Despotis GJ, Gravlee G, Filos K, Levy J. Anticoagulation monitoring during cardiac surgery: a review of current and emerging techniques. Anesthesiology. 1999 Oct;91(4):1122-51. Review.
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• Hardy JF, Bélisle S, Robitaille D, Perrault J, Roy M, Gagnon L. Measurement of heparin concentration in whole blood with the Hepcon/HMS device does not agree with laboratory determination of plasma heparin concentration using a chromogenic substrate for activated factor X. J Thorac Cardiovasc Surg. 1996 Jul;112(1):154-61.
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• Miyashita T, Nakajima T, Hayashi Y, Kuro M. Hemostatic effects of low-dose protamine following cardiopulmonary bypass. Am J Hematol. 2000 Jun;64(2):112-5.
• Mochizuki T, Olson PJ, Szlam F, Ramsay JG, Levy JH. Protamine reversal of heparin affects platelet aggregation and activated clotting time after cardiopulmonary bypass. Anesth Analg. 1998 Oct;87(4):781-5.
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