Is There an Alternative to Potassium Arrest?

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III: New Directions in Surgical Myocardial Protection

Is There an Alternative to Potassium Arrest?

Neri M. Cohen, MD, PhD, Ralph J. Damiano, Jr, MD, Andrew S. Wechsler, MD

Laboratory of Surgical Electrophysiology, Division of Cardiothoracic Surgery, Department of Surgery, Medical College of Virginia, Virginia Commonwealth University, Richmond, Virginia

Abstract

Background. Mounting clinical and experimental evidence suggeststhat postoperative myocardial dysfunction is a frequent consequenceof surgical global ischemia and reperfusion, despite our moderntechniques of myocardial protection. The ubiquitous use of hyperkalemicdepolarizing solutions in all forms of cardioplegia may be partlyresponsible for this phenomenon because of the known ongoingmetabolic processes and damaging transmembrane ionic fluxesthat occur at depolarized membrane potentials. Cardiac arrestat hyperpolarized potentials, the natural resting state of theheart, may avoid the shortcomings of depolarized arrest andprovide an alternative means of myocardial protection.

Methods. An adenosine triphosphate–sensitive potassiumchannel opener, aprikalim, was used to induce hyperpolarizedarrest. Aprikalim was able to produce sustained and reproducibleelectromechanical arrest that was reversible by reperfusion.

Results. In isolated heart models, when compared with depolarizedhyperkalemic arrest, hyperpolarized arrest afforded better protectionfrom global normothermic ischemia and resulted in better postischemicrecovery of function upon reperfusion. Preliminary studies ina porcine cardiopulmonary bypass model also have revealed thathyperpolarized arrest can be achieved in a model more closelyapproximating the clinical setting, and can effectively protectthe heart during normothermic surgical global ischemia.

Conclusions. Hyperpolarized cardiac arrest may offer an effectivealternative to traditional potassium arrest.

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				A. K. Snabaitis, M. J. Shattock, and D. J. Chambers Comparison of Polarized and Depolarized Arrest in the Isolated Rat Heart for Long-term Preservation Circulation, November 4, 1997; 96(9): 3148 - 3156. [Abstract] [Full Text]

				B. H. Dorman, L. Hebbar, R. B. Hinton, R. C. Roy, and F. G. Spinale Preservation of Myocyte Contractile Function After Hypothermic Cardioplegic Arrest by Activation of ATP-Sensitive Potassium Channels Circulation, October 7, 1997; 96(7): 2376 - 2384. [Abstract] [Full Text]

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				U. Acikel, E. Hazan, N. Sariosmanoglu, H. Catalyurek, E. Silistreli, G. Guner, N. Saydam, Y. Tuncok, H. Guven, O. Karabay, et al. Nisoldipine Cardioplegia in the Isolated Rabbit Heart Journal of Cardiovascular Pharmacology and Therapeutics, January 1, 1997; 2(4): 285 - 290. [Abstract] [PDF]

				P. Menasche Blood Cardioplegia: Do We Still Need to Dilute? Ann. Thorac. Surg., October 1, 1996; 62(4): 957 - 960. [Full Text]