Blood Trauma Induced by Clinically Accepted Oxygenators

Hemolysis remains one of the most serious problems during cardiopulmonary bypass (CPB), extracorporeal membrane oxygenation (ECMO), and percutaneous cardiopulmonary support (PCPS). However, the hemolytic characteristics associated with oxygenators are not well defined. A specialized hemolysis test protocol for oxygenators was developed. A comparative study was performed following this protocol to determine the hemolytic characteristics of the clinically available oxygenators during CPB; pressure drop measurements in the blood chamber were also performed. Four oxygenators (Medtronic Affinity, Cobe Optima, Terumo Capiox SX25, and Bard Quantum) were evaluated. Fresh blood from healthy Dexter calves anticoagulated with citrate phosphate dextrose adenine solution was used. The blood flow was fixed at 5 L/min, similar to that used in CPB. The Normalized Index of Hemolysis for Oxygenators (NIHO) has been modified according to the American Society of Testing and Materials (ASTM) standards. The NIH value, which was obtained from the circuit without an oxygenator, was subtracted from the primary NIH value, obtained from the circuit with an oxygenator to eliminate the effects of a centrifugal pump or other artifacts. The NIHO value was the lowest in the Affinity (0.0116 ± 0.0017) and increased from Affinity < Optima (0.0270 ± 0.0038) < Capiox (0.0335 ± 0.0028) < Quantum (0.0416 ± 0.0015 g/100 L). The Optima and Capiox did not demonstrate a significant difference. In addition, this NIHO value has a close relationship to the pressure drop. In conclusion, this new evaluation method is suitable to compare the biocompatibility performance of different types of clinically available oxygenators for CPB usage.

[1]  Y Nosé,et al.  Hemolysis in different centrifugal pumps. , 2008, Artificial organs.

[2]  J. Linneweber,et al.  Preclinical Evaluation of a Hollow Fiber Silicone Membrane Oxygenator for Extracorporeal Membrane Oxygenator Application , 2000, ASAIO journal.

[3]  J. Hayashi,et al.  Biocompatibility of a silicone-coated polypropylene hollow fiber oxygenator in an in vitro model. , 1999, The Annals of thoracic surgery.

[4]  D. D. de Jong,et al.  Clinical evaluation of six hollow-fibre membrane oxygenators. , 1997, Perfusion.

[5]  Y. Shomura,et al.  Clinical Evaluation of a Silicone Coated Hollow Fiber Oxygenator , 1997, ASAIO journal.

[6]  Y. Niimi,et al.  Protein Adsorption and Platelet Adhesion on the Surface of an Oxygenator Membrane , 1997, ASAIO journal.

[7]  Y. Nosé,et al.  Comparison of the Gyro C1E3 and BioMedicus centrifugal pump performances during cardiopulmonary bypass. , 1997, Artificial organs.

[8]  L. Foubert,et al.  Impact of oxygenator design on hemolysis, shear stress, and white blood cell and platelet counts. , 1996, Journal of cardiothoracic and vascular anesthesia.

[9]  Y. Ohara,et al.  Hemolytic characteristics of a pivot bearing supported Gyro centrifugal pump (C1E3) simulating various clinical applications. , 1996, Artificial organs.

[10]  Y Nosé,et al.  Effect of surface roughness on hemolysis in a centrifugal blood pump. , 1996, ASAIO journal.

[11]  M. G. Bearss The Relationship Between Membrane Oxygenator Blood Path Pressure Drop and Hemolysis: An In-vitro Evaluation , 1993, The Journal of ExtraCorporeal Technology.

[12]  E. Fosse,et al.  Reduced complement activation with heparin-coated oxygenator and tubings in coronary bypass operations. , 1992, The Journal of thoracic and cardiovascular surgery.

[13]  V. Videm,et al.  Biocompatibility of extracorporeal circulation. In vitro comparison of heparin-coated and uncoated oxygenator circuits. , 1991, The Journal of thoracic and cardiovascular surgery.

[14]  T Koller,et al.  Contribution to the in vitro testing of pumps for extracorporeal circulation. , 1967, The Journal of thoracic and cardiovascular surgery.

[15]  Y. Nosé,et al.  Development of an antithrombogenic and antitraumatic blood pump: the Gyro C1E3. , 2000, ASAIO journal.