A novel method for the direct determination of heparin concentration during cardiopulmonary bypass surgery.

BACKGROUND: Heparin is the standard drug for anticoagulation treatment and is used in many cardiac surgical interventions to prevent blood clotting. The anticoagulation status is controlled by various clotting tests. However, these tests depend on parameters like temperature, hemodilution etc. and are thus not applicable for a direct monitoring of the heparin concentration. The aim of this prospective study was to test a novel light scattering assay (LiSA) for the direct determination of heparin concentration during cardiopulmonary bypass (CPB) surgery and to compare the heparin concentrations with routinely determined activated clotting time (ACT). METHODS: The patient group consisted of 50 patients undergoing coronary bypass surgery with CPB. The coagulation status was monitored by the measurement of ACT, which was performed approximately every 30 min during surgery. Parallel to each ACT measurement, the heparin concentration was measured by LiSA. RESULTS: For 70% of the patients, ACT and heparin concentration measured by LiSA correlated reasonably over the entire time course of the intervention. For 30% of the patients, an insufficient correlation or even no correlation at all was observed. CONCLUSIONS: This study showed that LiSA enables the determination of intra-operative heparin levels. The lack of correlation between ACT and heparin concentration in a substantial group of patients shows that monitoring of heparin concentration is important. A more precise blood coagulation management, in particular, a precise administration of heparin and protamine, should be based on a combination of the measurement of heparin concentration and of ACT, but not on ACT alone.

Analysis of the complex formation of heparin with protamine by light scattering and analytical ultracentrifugation: implications for blood coagulation management.

Heparin, a linear glycosaminoglycan, is used in different forms in anticoagulation treatment. Protamine, a highly positive charged peptide containing about 32 amino acids, acts as an antagonist for heparin to restore normal blood coagulation. The complex formation of protamine with heparin was analyzed by a combination of analytical ultracentrifugation and light scattering. Titration of heparin with protamine in blood plasma preparations results in a drastic increase of turbidity, indicating the formation of nanoscale particles. A similar increase of turbidity was observed in physiological saline solution with or without human serum albumin (HSA). Particle size analysis by analytical ultracentrifugation revealed a particle radius of approximately 30 nm for unfractionated heparin and of approximately 60 nm for low molecular weight heparin upon complexation with excess protamine, in agreement with atomic force microscopy data. In the absence of HSA, larger and more heterogeneous particles were observed. The particles obtained were found to be stable for hours. The particle formation kinetics was analyzed by light scattering at different scattering angles and was found to be complete within several minutes. The time course of particle formation suggests a condensation reaction, with sigmoidal traces for low heparin concentrations and quasi-first-order reaction for high heparin concentrations. Under all conditions, the final scattering intensity reached after several minutes was found to be proportional to the amount of heparin in the blood plasma or buffer solution, provided that excess protamine was available and no multiple scattering occurred. On the basis of a direct relation between particle concentration and the heparin concentration present before protaminization, a light scattering assay was developed which permits the quantitative analysis of the heparin concentration in blood plasma and which could complement or even replace the activated clotting time test, which is currently the most commonly used method for blood coagulation management.