Polarized arrest with warm or cold adenosine/lidocaine blood cardioplegia is equivalent to hypothermic potassium blood cardioplegia

Joel S Corvera; Hajime Kin; Geoffrey P Dobson; Faraz Kerendi; Michael E Halkos; Sara Katzmark; Christopher S Payne; Zhi-Qing Zhao; Robert A Guyton; Jakob Vinten-Johansen

doi:10.1016/j.jtcvs.2004.07.021

Polarized arrest with warm or cold adenosine/lidocaine blood cardioplegia is equivalent to hypothermic potassium blood cardioplegia

J Thorac Cardiovasc Surg. 2005 Mar;129(3):599-606. doi: 10.1016/j.jtcvs.2004.07.021.

Authors

Joel S Corvera¹, Hajime Kin, Geoffrey P Dobson, Faraz Kerendi, Michael E Halkos, Sara Katzmark, Christopher S Payne, Zhi-Qing Zhao, Robert A Guyton, Jakob Vinten-Johansen

Affiliation

¹ Cardiothoracic Research Laboratory and Carlyle Fraser Heart Center, Emory University School of Medicine, Altanta, GA 30308, USA.

PMID: 15746744
DOI: 10.1016/j.jtcvs.2004.07.021

Abstract

Background: Hypothermic depolarizing hyperkalemic (K + 20 mEq/L) blood cardioplegia is the "gold standard" in cardiac surgery. K + has been associated with deleterious consequences, eg, intracellular calcium overload. This study tested the hypothesis that elective arrest in a polarized state with adenosine (400 micromol/L via adenosine triphosphate-sensitive potassium channel opening) and the Na + channel blocker lidocaine (750 micromol/L) as the arresting agents in blood cardioplegia provides cardioprotection comparable to standard hypothermic K + -blood cardioplegia.

Methods: Anesthetized dogs were placed on cardiopulmonary bypass and assigned to 1 of 3 groups receiving antegrade cardioplegia delivered every 20 minutes for 1 hour of arrest: cold (10 degrees C) K + -blood cardioplegia (n = 6), cold (10 degrees C) adenosine/lidocaine blood cardioplegia (n = 6), or warm (37 degrees C) adenosine/lidocaine blood cardioplegia (n = 6). After an hour of arrest, cardiopulmonary bypass was discontinued, and reperfusion was continued for 120 minutes.

Results: Time to arrest was longer with cold and warm adenosine/lidocaine blood cardioplegia (175 +/- 19 seconds and 143 +/- 19 seconds, respectively) compared with K + -blood cardioplegia (27 +/- 2 seconds; P < .001). Postcardioplegia left ventricular systolic function (slope of the end-systolic pressure/dimension relationship) was comparable among the 3 groups (K + -blood cardioplegia, 15.2 +/- 2.1 mm Hg/mm; cold adenosine/lidocaine blood cardioplegia, 15.9 +/- 3.4 mm Hg/mm; warm adenosine/lidocaine blood cardioplegia, 14.1 +/- 2.8 mm Hg/mm; P = .90). Plasma creatine kinase activity in cold and warm adenosine/lidocaine blood cardioplegia was similar to that in K + -blood cardioplegia at 120 minutes of reperfusion (cold adenosine/lidocaine blood cardioplegia, 11.5 +/- 2.1 IU/g protein; warm adenosine/lidocaine blood cardioplegia, 10.1 +/- 0.9 IU/g protein; K + -blood cardioplegia, 7.6 +/- 0.8 IU/g protein; P = .17). Postcardioplegia coronary artery endothelial function was preserved in all groups.

Conclusions: Intermittent polarized arrest with warm or cold adenosine/lidocaine blood cardioplegia provided the same degree of myocardial protection as intermittent hypothermic K + -blood cardioplegia in normal hearts.

Publication types

Comparative Study

MeSH terms

Adenosine*
Animals
Cardioplegic Solutions*
Creatine Kinase / blood
Dogs
Endothelium, Vascular / physiopathology
Heart Arrest, Induced / methods*
Lidocaine*
Potassium

Substances

Cardioplegic Solutions
Lidocaine
Creatine Kinase
Adenosine
Potassium