M A Portman1, G E Eyster. 1. Department of Pediatrics, University of Washington School of Medicine, Seattle 98195.
Abstract
UNLABELLED: The purpose of this study was to measure myocardial buffering capacity and adenosine triphosphate utilization rates in the newborn animal in vivo during hypothermic circulatory arrest and recovery. METHODS: These studies were performed with 31P magnetic resonance spectroscopic techniques, which supplied a 12- to 16-second time resolution, to monitor intracellular pH and phosphocreatine and adenosine triphosphate levels. All experiments were performed with a radiofrequency surface coil on the pericardium with the sheep centered inside a 4.7 T magnet. Newborn sheep (n = 5, aged 16 days +/- 2.4 standard error) were supported by cardiopulmonary bypass, cooled to 20 degrees C, and subjected to 20 minutes of circulatory arrest. RESULTS: During early ischemia, phosphocreatine hydrolysis progressed at a linear rate, 1.2 +/- 0.05 mumol/gm per minute, and was accompanied by intracellular alkalinization. Myocardial buffering capacity calculated from delta pH/delta phosphocreatine equals 25 +/- 3 mueq gm-1 delta pH-1, a value similar to that obtained from perfused heart studies. After the initial 4 minutes in ischemia, the decrease in phosphocreatine hydrolysis was accompanied by intracellular acidification, which is likely due to late induction of anaerobic metabolism. CONCLUSIONS: In these studies, early phosphocreatine hydrolysis rate is nearly equivalent to adenosine triphosphate utilization rate. During the early period of ischemia phosphocreatine hydrolysis serves a buffering function and is associated with intracellular alkalinization. These techniques and measurements can be used to compare effects of myocardial preservation techniques on intracellular pH and adenosine triphosphate kinetics.
UNLABELLED: The purpose of this study was to measure myocardial buffering capacity and adenosine triphosphate utilization rates in the newborn animal in vivo during hypothermic circulatory arrest and recovery. METHODS: These studies were performed with 31P magnetic resonance spectroscopic techniques, which supplied a 12- to 16-second time resolution, to monitor intracellular pH and phosphocreatine and adenosine triphosphate levels. All experiments were performed with a radiofrequency surface coil on the pericardium with the sheep centered inside a 4.7 T magnet. Newborn sheep (n = 5, aged 16 days +/- 2.4 standard error) were supported by cardiopulmonary bypass, cooled to 20 degrees C, and subjected to 20 minutes of circulatory arrest. RESULTS: During early ischemia, phosphocreatine hydrolysis progressed at a linear rate, 1.2 +/- 0.05 mumol/gm per minute, and was accompanied by intracellular alkalinization. Myocardial buffering capacity calculated from delta pH/delta phosphocreatine equals 25 +/- 3 mueq gm-1 delta pH-1, a value similar to that obtained from perfused heart studies. After the initial 4 minutes in ischemia, the decrease in phosphocreatine hydrolysis was accompanied by intracellular acidification, which is likely due to late induction of anaerobic metabolism. CONCLUSIONS: In these studies, early phosphocreatine hydrolysis rate is nearly equivalent to adenosine triphosphate utilization rate. During the early period of ischemia phosphocreatine hydrolysis serves a buffering function and is associated with intracellular alkalinization. These techniques and measurements can be used to compare effects of myocardial preservation techniques on intracellular pH and adenosine triphosphate kinetics.