Steven Schultz

Cerebral and somatic oxygen saturation decrease after delayed sternal closure in children after cardiac surgery

OBJECTIVES Delayed sternal closure after pediatric cardiac surgery can temporarily impair cardiac output. Cerebral and somatic regional oxygen saturation measured by using near-infrared spectroscopy (NIRS) have been used as potential surrogates of cerebral and somatic mixed venous oxygen saturation. We hypothesized that cerebral and somatic regional oxygen saturation correlate with indicators of hemodynamic compromise after delayed sternal closure in children undergoing cardiac surgery. METHODS We studied 36 postoperative children (median age, 10 days; range, 1-510 days) undergoing delayed sternal closure 3.7 +/- 2 days after cardiac surgery. Twenty-five had biventricular physiology, whereas 11 had single-ventricle physiology. Cerebral regional oxygen saturation, somatic regional oxygen saturation, and other physiologic parameters (hemodynamic data, respiratory data, blood gas analysis, lactate levels, and inotrope scores) were analyzed at 16 different time points 24 hours before and after sternal closure. One-way analysis of variance and the paired t test were used for statistical comparisons. RESULTS Cerebral and somatic regional oxygen saturation decreased after delayed sternal closure compared with preclosure levels (P = .02 and P = .01, respectively). Higher heart rate (P = .03), lactate levels (P = .02), and left atrial pressure (P = .001) were also noted, suggesting mild hemodynamic compromise. Arterial pressure and inotrope score were unchanged. Somatic regional oxygen saturation returned to preclosure levels earlier in the biventricular group than in the single-ventricle group, whereas cerebral regional oxygen saturation remained decreased after sternal closure with no evidence of return to preclosure levels during the observation period. Oxygen saturation, Pao(2), and Paco(2) levels were unaffected by sternal closure, although greater positive-pressure ventilation was required (P < .01), suggesting reduced lung compliance. CONCLUSION Cerebral and somatic regional oxygen saturation decrease after delayed sternal closure in children recovering from congenital cardiac surgery. These indices are in agreement with other physiologic indicators of cardiac performance, suggesting mild and transient hemodynamic compromise after sternal closure. Cerebral and somatic regional oxygen saturation monitoring might be a useful adjunct during delayed sternal closure.

Effect of perfusion flow rate on tissue oxygenation in newborn piglets during cardiopulmonary bypass.

BACKGROUND Our knowledge of the best perfusion flow rate to use during cardiopulmonary bypass (CPB) in order to maintain tissue oxygenation remains incomplete. The present study examined the effects of perfusion flow rate and patent ductus arteriosus (PDA) during normothermic CPB on oxygenation in several organ tissues of newborn piglets. METHODS The experiments were performed on 12 newborn piglets: 6 with PDA ligation (PDA-L), and 6 without PDA ligation (PDA-NL). CPB was performed through the chest at 37 degrees C. During CPB, the flow rate was changed at 15-minute intervals, ranging from 100 to 250 ml/kg/min. Tissue oxygenation was measured by quenching of phosphorescence. RESULTS For the PDA-L group, oxygen in the brain did not change significantly with changes in flow rate. In contrast, for the PDA-NL group, oxygen was dependent upon the flow rate. Statistically significant decreases in cortical oxygen were observed with flow rates below 175 ml/kg/min. Within the myocardium, liver, and intestine, there were no significant differences in the oxygen levels between the PDA-L and PDA-NL groups. In these tissues, the oxygen decreased significantly as the flow rate decreased below 150 ml/kg/min, 125 ml/kg/min, and 175 ml/kg/min, respectively. Oxygen pressure in skeletal muscle was not dependent on either PDA ligation or flow rate. CONCLUSIONS In newborn piglets undergoing CPB, the presence of a PDA results in reduced tissue oxygenation to the brain but not to other organs. In general, perfusion flow rates of 175 ml/kg/min or greater are required in order to maintain normal oxygenation of all organs except muscle.

Cerebral Oxygenation During Repetitive Apnea in Newborn Piglets

This study examined the effect of repetitive apnea on brain oxygen pressure in newborn piglets. Each animal was given 10 episodes of apnea, initiated by disconnecting them from the ventilator and completed by reconnecting them to the ventilation circuit. The apneic episodes were ended 30 sec after the heart rate reached the bradycardic threshold of 60 beats per min. The oxygen pressure in the microvasculature of the cortex was measured by oxygen-dependent quenching of the phosphorescence. In all experiments, the blood pressure, body temperature, and heart rate were continuously monitored. Arterial blood samples were taken throughout the experiment and the blood pH, PaO2 and PaCO2 were measured. During pre-apnea, cortical oxygen was 55.1 +/- 6.4 (SEM, n = 7) mm Hg and decreased during each apnea to 8.1 +/- 2.8 mm Hg. However, the values of cortical oxygen varied during recovery periods. Maximal oxygen levels during recovery from the first two apneic episodes were 76.8 +/- 12 mm Hg and 69.6 +/- 9 mm Hg, respectively, values higher than pre-apnea. Cortical oxygen pressure then progressively decreased following consequent apnea. In conclusion, the data show that repetitive apnea caused a progressive decrease in cortical oxygen levels in the brain of newborn piglets. This deficit in brain oxygenation can be at least partly responsible for the neurological side effects of repetitive apnea.

Brain Oxygenation and Metabolism During Repetitive Apnea with Resuscitation of 21% and 100% Oxygen in Newborn Piglets

The oxygen distribution in the microcirculation of the piglet’s brain and striatal extracellular dopamine were determined during repetitive apnea and resuscitation with 21% or 100% oxygen. Pre-apnea cortical oxygen was 49.5 ± 10.4 mm Hg and during each apnea decreased to 8 ± 0.9 mm Hg. After ten apneic episodes followed by resuscitation with 21% or 100% oxygen, 7.48 ± 1.6% or 2.6 ± 0.5% of the tissue volume was below 10 mm Hg, respectively. Extracellular dopamine increased progressively with an increase in the number of apneas with resuscitation of 21% oxygen and at the end of ten apneic episodes it was up to 59,500 ± 11,320% of control. There was no increase in extracellular dopamine during apnea resuscitated with 100% oxygen. Repetitive apnea caused progressive increase in fraction of hypoxic brain tissue in newborn. The magnitude of the increase is dependent on whether the animals were resuscitated with room air or 100% oxygen.