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Ann Thorac Surg 2000;70:756-764
© 2000 The Society of Thoracic Surgeons

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Original articles: cardiovascular

The role of cardioplegia induction temperature and amino acid enrichment in neonatal myocardial protection

^a Division of Cardiovascular Surgery, The Heart Institute for Children, Hope Children’s Hospital, Oak Lawn, Illinois, USA
^b The University of Illinois at Chicago, Chicago, Illinois, USA

Address reprint requests to Dr Allen, Heart Institute for Children, Hope Children’s Hospital, 4440 W 95th St, Oak Lawn, IL 60453

Background. Warm cardioplegic induction improves the ischemically "stressed" adult heart. However, it is rarely used in infants, despite the fact that many newborn hearts are stressed by other factors such as hypoxia. The need for amino acids as well as their mechanism of action has also not been studied.

Methods. We first assessed the role of cardioplegic induction temperature in 10 nonhypoxic neonatal piglets undergoing 70 minutes of multidose blood cardioplegic arrest. Five piglets (group 1) received a cold (4°C) induction, and 5 (group 2) a warm (37°C) induction. Twenty-six other piglets underwent ventilator hypoxia (fraction of inspired oxygen, 8% to 10%) for 60 minutes before cardiopulmonary bypass (stress). Six piglets (group 3) then underwent 70 minutes of cardiopulmonary bypass without ischemia (hypoxia controls), and 20 underwent 70 minutes of cardioplegic arrest. Five of these (group 4) received cold cardioplegic induction, and 15 received warm induction; in 5 of these (group 5), the warm cardioplegic solution contained amino acids, in 5 others (group 6), it was unsupplemented, and in the remaining 5 (group 7), nitroglycerin was added to determine the role of vasodilation. Myocardial function was assessed by pressure-volume loops (expressed as a percent of control), and coronary vascular resistance was measured with cardioplegic infusions.

Results. In nonhypoxic (normal) piglets, cold (group 1) and warm (group 2) induction completely preserved systolic function (end-systolic elastance, 100% versus 104%) and preload recruitable stroke work (100% versus 102%), with minimal increase in diastolic compliance (162% versus 156%). Hypoxia–reoxygenation alone (group 3) depressed systolic function (end-systolic elastance, 51% ± 2%) and preload recruitable stroke work (54% ± 3%), and raised diastolic stiffness (260% ± 15%). The detrimental effects of reoxygenation persisted (unchanged from reoxygenation alone) with cold induction (group 4) or warm induction without amino acids (groups 6 and 7). In contrast, warm induction with amino acids (group 5) restored systolic function (end-systolic elastance, 105% ± 3%; p < 0.001 versus groups 3, 4, 6, and 7) and preload recruitable stroke work (103% ± 2%; p < 0.001 versus groups 3, 4, 6, and 7), and decreased diastolic stiffness (154% ± 7%; p < 0.001 versus groups 3, 4, 6, and 7). However, there was no difference in myocardial oxygen consumption in hypoxic hearts receiving a warm induction (6.9 versus 6.5 versus 7.3 mL/g per 5 minutes) (groups 5, 6, 7), and coronary vascular resistance was lowest with nitroglycerin (group 7).

Conclusions. Cardioplegic induction can be given either warm or cold in nonhypoxic neonatal hearts. In contrast, only warm induction with amino acids repairs the hypoxic injury, but the primary mechanism of action is not related to increased metabolic activity or vasodilation.

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