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Ann Thorac Surg 2004;78:1389-1396
© 2004 The Society of Thoracic Surgeons

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Original article: cardiovascular

An Analysis of Oxygen Consumption and Oxygen Delivery in Euthermic Infants After Cardiopulmonary Bypass With Modified Ultrafiltration

^a Division of Cardiology, Hospital for Sick Children, Toronto, Ontario, Canada
^b Department of Cardiac Surgery, Toronto, Ontario, Canada
^c Department of Cardiac Intensive Care, Great Ormond Street Hospital, London, United Kingdom

Accepted for publication February 10, 2004.

^* Address reprint requests to Dr Redington, Division of Cardiology, The Hospital for Sick Children, 555 University Ave, Toronto, Ontario, Canada M5G 1X8
andrew.redington{at}sickkids.ca

	Abstract

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
BACKGROUND: The balance between systemic oxygen consumption (O₂) and delivery (DO₂) is impaired after cardiopulmonary bypass (CPB) and is related to systemic inflammatory response syndrome. We sought to assess O₂ and DO₂ and their relationship with proinflammatory cytokines after CPB with the use of modified ultrafiltration (MUF) in infants.

METHODS: Sixteen infants, aged 1–11.5 months (median, 6.3 months), undergoing hypothermic CPB with MUF were studied during the first 12 hours after arrival in the intensive care unit (ICU). The central temperature was maintained at 36.8–37.1°C using external cooling or warming. O₂ was continuously measured using respiratory mass spectrometry. Arterial blood samples for the tumor necrosis factor (TNF), interleukin-6 (IL-6), and interleukin-8 (IL-8) were taken and DO₂ was calculated using the Fick principle on arrival at the ICU, and 2, 4, 8, and 12 hours postoperatively. Cytokines were additionally measured after induction of anesthesia and at the end of MUF.

RESULTS: O₂ significantly decreased by 18.8% during the study period. DO₂ was depressed throughout this period and reached a nadir at 8 hours (357.1 ± 136.2 ml · min^–1 · m^–2). The decrease in cytokines was accompanied with the decrease in O₂ despite varied relationships between the levels of each of the cytokines and O₂ measurements.

CONCLUSIONS: Our data indicate an unusual continuous decrease in O₂ during the first 12 hours after CPB in infants. Control of body temperature to maintain euthermia in addition to the use of MUF may be beneficial to the balance between O₂ and DO₂ in the early postoperative period.

	Introduction

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
Hypothermic cardiopulmonary bypass (CPB) is commonly used during the correction of complex congenital heart disease in infants. The balance between the systemic delivery and consumption of oxygen is critical in the care of these patients. Changes in systemic oxygen balance have been well described in the adults after CPB [1, 2]. Reduction in systemic oxygen delivery (DO₂) is caused by diminished cardiac output, whereas increases in systemic oxygen consumption (O₂) have been indicated as being related to central body temperature [1] and the systemic inflammatory response [2]. We, as well as others, have assessed these changes during the early hours after CPB in children [3, 4]. We previously demonstrated that the uniformly observed increase in O₂ was attributable, in part, to the increase in the central body temperature in children during spontaneously rewarming and fever after CPB [3]. There was an approximate 11% rise in O₂ per °C rise in central temperature. The development of fever occurred in 75%. The technique of modified ultrafiltration (MUF) has become widely adopted for use with hemodilutional CPB primarily for the purpose of reducing the accumulated total body water [5, 6]. MUF has subsequently been established to reduce plasma concentration of the inflammatory mediators such as the tumor necrosis factor (TNF), interleukin-6 (IL-6), and interleukin-8 (IL-8) [7, 8]. Furthermore we have demonstrated that MUF leads to improved left ventricular systolic function [9–11] that may further affect the balance between DO₂ and O_2.

Studies of the effects of cytokines on euthermic O₂ after MUF have yet to be performed. The aim of our study was therefore to assess systemic O₂ and its relationship with DO₂ and cytokine levels in infants under normothermia during the first 12 hours after CPB with the use of MUF.

	Material and Methods

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
This study was approved by the local ethical committee at The Great Ormond Street Hospital for Sick Children (London, UK) and written informed consent was obtained from the parents of 16 infants (9 boys and 7 girls) undergoing cardiac surgery using hypothermic CPB. Their ages ranged from 1–11.5 months (median 6.3 months). The clinical characteristics of the patients are indicated in Table 1. All indicated biventricular repair and none indicated residual intracardiac shunting.

CPB was performed with moderate-to-deep hypothermia with the lowest nasopharyngeal temperature between 16° and 32°C (median 25°C). The priming solution was a mixture of whole blood and Hartmann's solution in a ratio calculated to achieve a hemoglobin concentration of 8–9 g/dl. Each patient received cold crystalloid cardioplegia (St. Thomas' solution 120 ml/kg) delivered into the aortic root at 40 mm Hg after aortic cross-clamping (ACC). Nonpulsatile flow on CPB was maintained at 150 ml/kg per minute and mean perfusion pressure was adjusted between 40–50 mm Hg using isoflurane to vasodilate and metaraminol to vasoconstrict when required. CPB was maintained for 50–187 minutes (median 86 minutes) and ACC for 19–125 minutes (median 48 minutes) (Table 1). All patients were weaned from CPB after the nasopharygeal temperature reached 35°C and hemodynamic stability was achieved. A pulmonary arterial line was inserted before the termination of CPB. Positive pressure ventilation was recommenced after the discontinuation of CPB.

MUF was performed for 10 minutes within 5–10 minutes of cessation of CPB using the Great Ormond Street Hospital protocol [5] with a pediatric hemofilter (Pediatric Filtral 66; Gambro, Engstrom, Sweden). Flow through the filter was maintained at 200 ml/min by an inlet roller pump and outlet resistance varied to maintain a filtration rate of 100–150 ml/min. The previously optimized left atrial pressure was maintained during filtration by transfusion from the venous reservoir through the filter. Filtration was performed for 10 minutes aiming to achieve a hematocrit of 35%–40%.

The time between termination of CPB and returning to the ICU was less than 2 hours for all patients. Upon return to the ICU patients were mechanically ventilated using volume cycled intermittent positive pressure ventilation (Servo ventilator 900C; Siemens Medical Systems, Solna, Sweden). All received continuous intravenous infusions of vecuronium (1–3 µg · kg^–1 · h^–1), morphine (20–40 µg · kg^–1 · h^–1), and midazolam (1–3 µg · kg^–1 · h^–1) until weaning of mechanical ventilation occurred. The minute volume was adjusted to give an arterial carbon dioxide tension of 4–6 kPa. The FiO₂ was less than 60% in all patients.

The central body temperature was maintained at around 37°C using a cooling mattress or warming blanket and overhead radiant heater. Dopamine, dobutamine, and glyceryl trinitrate with diuretics (usually frusemide) were used as clinically indicated. Volume infusions (usually packed red blood cells or 5% albumin) were given to maintain adequate filling pressures with systemic perfusion pressures. The patient was extubated upon clinical judgment and the duration of mechanical ventilation was recorded.

All patients underwent continuous invasive monitoring of systemic and pulmonary arterial and central venous pressures. Heart rate was continuously monitored and the central body temperature (rectal) was monitored with standard temperature probe (Hewlett Packard, Bracknell, UK).

O₂ was measured continuously with our previously described method [3] using on-line respiratory mass spectrometry. This is a highly sensitive and accurate method for continuous gas analysis that allows simultaneous measurements of multiple gas fractions within a mixture. An AMIS 2000 quadrupole mass spectrometer (Innovision A/S, Odense, Denmark) was adapted for use in patients ventilated with the Servo 900C ventilator. O₂ was measured using the mixed expirate inert gas (argon) dilution method [12]. This requires analysis of inspired and expired gases together with the collection of all expired gas. Before beginning the study the cuff of the endotracheal tube was inflated to prevent leakage. The pressure within the cuff was measured with a manometer to prevent hypoperfusion of the airway mucosa and it was maintained below arterial diastolic pressure. A two-point calibration of the mass spectrometer was performed exposing the distal inlet both to a four-gas calibration mixture (nitrogen, oxygen, carbon dioxide, and argon) and to zero gas (closed inlet). This calibration was repeated at 30-minute intervals throughout the study period to avoid any measurement drift. The calibration of tracer gas flow (argon) was achieved using a designated flow meter (CT Platon, Basingstoke, UK, accuracy ± 1.25%). Ambient humidity, temperature, and atmospheric pressure were recorded from an electronic barometer (BA-888; Oregon Scientific, Portland, OR).

Arterial and mixed venous blood samples were taken from the peripheral arterial and pulmonary arterial catheters. Sampling was avoided if a change in ventilatory or hemodynamic support was assessed within 15 minutes. Blood samples were analyzed for oxygen, carbon dioxide, and lactate levels using the I-STAT Portable Clinical Analyzer (Hewlett-Packard, GmbH Bolingen, Germany; Chiron Diagnostics, Halstead, UK). Cardiac output (CO) was then calculated using the direct Fick method according to the following equation:

where CaO₂ and CvO₂ are arterial and mixed venous oxygen contents, respectively.

The cardiac index (CI) was calculated according to body surface area (BSA):

DO₂ and ERO₂ were then calculated using the following equations:

and

Plasma, obtained by centrifugation, was placed in aliquots and stored at –70°C for the measurement of IL-6, IL-8, and TNF using commercially available enzyme-linked immunosorbant assay (ELISA) antibody pairs (Cytoset; Biosource International, Camarillo, CA). Preliminary experiments optimized manufacturer's guidelines to achieve a lower detection limit of 3 pg/mL for IL-6, IL-8, and TNF. All samples were analyzed in duplicate by an individual who was blinded to the treatment protocol.

Values of hemodynamics, O₂, and central body temperature were obtained and blood samples were taken at the following time: upon admission to the ICU and after 2, 4, 8, and 12 hours during mechanical ventilation. Blood samples for the cytokines were additionally taken after induction of anesthesia and at the end of MUF.

View larger version (27K): [in this window] [in a new window]   Fig 1. Mean ± standard deviation values of central temperature, oxygen consumption (O2), cardiac index (CI), oxygen delivery (DO2), oxygen extraction ratio (ERO2), and arterial blood lactate levels during the first 12 hours after admission to the pediatric intensive care unit (ICU) succeeding cardiopulmonary bypass operations with the use of modified ultrafiltration in 16 infants.

	Results

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
All but 2 of the patients were extubated within 24 hours. One (patient 7) was mechanically ventilated for 16 days during recovery from left ventricular dysfunction secondary to anomalous left coronary artery from pulmonary trunk. This patient was placed on a left ventricular assist device after 22 hours in the ICU and subsequently recovered. The other patient (patient 5) exhibited an unexplained cerebral hemorrhage 9 hours after ICU admission and died 15 hours later. In 4 patients the study was stopped at 8 hours when weaning of mechanical ventilation was commenced.

Table 2 indicates the mean ± SD values of central temperature, oxygen transport, and arterial lactate and cytokine levels during the study period. Upon arrival to the ICU, arterial blood lactate was less than 2.0 mmol/L in 12 patients, between 2.0–3.0 mmol/L in 2 patients, and 10.4 mmol/L in one patient. This latter patient (patient 11) had a low body weight (2.7 kg), the longest duration of CPB and ACC, the lowest central temperature (34.6°C), the lowest levels of O₂ (83.6 ml · min^–1 · m^–2), CI (1.1 L · min^–1 · m^–2), DO₂ (132.4 ml · min^–1 · m^–2), and the highest levels of ERO₂ (0.63). In the remainder the initial O₂ indicated no correlation with the duration of CPB (r = –0.06), ACC (r = –0.16), the depth of hypothermia (r = 0.04), and the central temperature (r = –0.11). The duration of CPB and ACC were negatively correlated with DO₂ (r = –0.41 and –0.43, respectively), being weaker with CI (r = –0.25 and –0.21, respectively), and were positively correlated with ERO₂ (r = 0.45 and 0.42, respectively). The duration of CPB was positively correlated with the blood lactate levels (r = 0.46, p = 0.04) but not that of ACC (r = 0.06). None of the correlations was significant (p > 0.05 for all).

When individual patients were reviewed, CI and DO₂ were more varied relative to O₂ at each time point of measurement during the study period, as was ERO₂, therefore no consistent correlations were determined between O₂ and DO₂ or O₂ and ERO₂ in individual patients (r = –0.60–0.91). The lowest CI and DO₂ were variably recorded between arrival up to 12 hours differently in individuals. CI was less than 2.0 L · min^–1 · m^–2 at least once in 11 patients. Dopamine was given in 9 patients among whom 8 patients indicated CI lower than 2 L · min^–1 · m^–2 at least once. Dobutamine was given in 4 patients and glyceryl trinitrate was given to all patients. Blood lactate returned to below 2 mmol/L in all of the patients by the end of the study period including the one (patient 11) with an initial lactate level of 10.4 mmol/L who was extubated 24 hours after admission to the ICU.

The concentrations of all the cytokines, TNF, IL-8, and IL-6, increased after CPB and peaked at ICU admission (Fig 2). TNF concentrations were low preoperatively and remained so throughout the study period without substantial differences regarding the sampling time. IL-8 concentrations, although also not being statistically different, increased noticeably after CPB and peaked at ICU admission, which was followed by a significant decrease (p = 0.009). The mean IL-6 concentrations increased insignificantly at the end of CPB (p = 0.051) peaking upon admission to the ICU (p = 0.002 as compared with the preoperative baseline concentrations) and then decreasing slightly (p = 0.170). In individual patients the peak time of IL-6 concentrations indicated wide variations, whereas that of IL-8 and TNF indicated a more consistent profile of peaking upon ICU admission. Large individual variations were also determined regarding the concentrations of the three cytokines. General linear multiple regression analysis indicates different relationships between the levels of O₂ and the levels of each of the cytokines during the study period being not significantly related to TNF (p = 0.138), positively related to IL-8 (p = 0.021), and negatively related to IL-6 (p = 0.003). The patient (patient 11) who exhibited the longest CPB and ACC time associated with the lowest levels of CI, DO₂, and O₂ indicated the highest levels of the three cytokines at all the sampling times with TNF being 281 pg/ml, IL-8 being 533 pg/ml, and IL-6 being 788 pg/ml upon ICU admission. In the rest of the patients no correlations were indicated between the durations of ACC and CPB with any of the cytokine levels (r < 0.30 and p > 0.05 for all patients).

View larger version (16K): [in this window] [in a new window]   Fig 2. Mean ± standard deviation values of (A) arterial tumor necrosis factor, (B) interleukin-8, and (C) interleukin-6 after induction of anesthesia, at the end of modified ultrafiltration, and during the first 12 hours after admission to the pediatric intensive care unit (ICU) in 16 infants. (CPB = cardiopulmonary bypass; MUF = modified ultrafiltration.)

	Comment

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

In our previous study of O₂ in children during spontaneously rewarming during the first 4 hours after CPB [3], there was an 11.3% ± 8.0% increase in O₂ per 1°C rise in central temperature. The postoperative increase in central body temperature may be attributed to two factors: normal homeostatic rewarming and fever induced by the inflammatory response after hypothermic CPB. Therefore the external warming and cooling for the maintenance of central temperature as used in our infants may have avoided the "metabolic cost" of temperature rise, which leads to an increase in O₂.

Although not previously described in children the provision of external heat supply has been reported to reduce the O₂ in adults during the rewarming period [15, 16]. External heat supply is a common clinical practice with regard to the care of infants during rewarming after hypothermia CPB surgery and our data suggests that it may also exhibit similar effects to reduce O₂ in children. Conversely external cooling to prevent fever may play a similar role in the attenuation of the associated rise in O₂. Maintenance of euthermia is part of the routine clinical management of patients after cardiac surgery in some centers. Our data may provide some support for its potential benefits in terms of O₂. However other factors than just temperature, such as the application of MUF with its possible effect on cytokine levels, may also contribute in part to the decreased O₂ in the current study.

MUF, which is commonly used for reducing the accumulated tissue water with hypothermic hemodilutional CPB [5, 6], has also been revealed to filter at least some cytokines including TNF, IL-6, and IL-8 [7, 8, 11]. The increased levels of cytokines are now believed to be the key factors during the systemic inflammatory response induced by hypothermic CPB [17–19]. Oudemans-van Straaten and associates demonstrated that higher circulating levels of cytokines including TNF and IL-6 were associated with a higher O₂ after CPB surgery and concluded that the systemic inflammatory response may explain 50% of the increase of O₂ [2]. It has been reported that the increased levels of cytokines are related to the duration of ACC and CPB [17, 18]. The longest duration of ACC and CPB was related to the highest levels of cytokines in one of the patients, but there was no correlation between the duration of ACC and CPB with cytokine levels in the remaining patients. Nonetheless this relationship may have been altered by the generally attenuated levels of cytokines after the use of MUF in our patients. The TNF levels in the current study were low throughout the study period including preoperatively. This is consistent with some pediatric studies [17] but different from others that describe a substantial increase after CPB [20]. Compared with other studies in children undergoing CPB without the use of MUF, postoperative IL-8 levels in our infants were considerably lower [17, 21]. Postoperative IL-6 levels were much more variable being similar to some [17, 21] and considerably lower than some others [19, 22]. When compared with a study of children regarding the use of MUF [23] TNF was considerably lower and IL-6 higher in our infants. The comparison of data in other reports is difficult however. It has been well documented that the cytokine response to CPB in children is characterized by large variations in the pattern of release and plasma concentrations [21, 23] in contrast to adults [24]. Indeed there was large interindividual variability between patients in our study despite a very rigid management protocol. Furthermore different assay sensitivities for the measurements of cytokines and different degrees of hemodilution may contribute to the varied results among studies [22]. Nonetheless the cytokine levels subsequently decreased further continuously after admission to the ICU, which accompanied the decrease in O_2. The role of cytokines in the modulation of O₂ is further supported by Oudemans-van Straaten's other study in which a nonsignificant increase in O₂ during the early hours after CPB was attributed to the prevention of the TNF-related inflammatory response with the prophylactic use of dexamethasone [25]. This study and our current study demonstrate a lack of increase in O₂ in the first hours after CPB. Our data indicated different relationships between the O₂ values and the levels of the different cytokines during the study period, not being notably related with TNF, positively related with IL-8, and negatively related with IL-6. The overall factors including the attenuated levels of cytokines with wide interindividual variations together with the absence of the increase in O₂ may help to explain the varied relationships between cytokine levels and O₂ in our patients.

DO₂, as well as CI, in our patients was depressed during the early hours after CPB reaching a nadir at 8 hours after ICU admission. This typical profile of cardiac function after CPB surgery has been generally described in children [26, 27] and in adults [28]. This sequence is related to ischemia-reperfusion injury and the secondary effects of the systemic inflammatory response [17, 28]. Although MUF has been reported to improve left ventricular systolic function [9, 10] the overall CI was low in our patients; values were similar to those in previously reported studies for neonates and infants after cardiac surgery [17, 26, 27, 29] Most infants exhibit more complex congenital heart disease requiring earlier surgical correction with longer duration of CPB and ACC time. Indeed the longer duration of CPB and ACC in our patients illustrated a tendency toward association with lower initial CI and DO₂ levels and the lowest levels at 8 hours resulting in a poorer balance between O₂ and DO₂ as indicated by the higher lactate levels. Thus this continuous decrease in O₂ in our patients demonstrates a beneficial effect toward improving the balance of oxygen transport in children experiencing more profound depression of DO₂.

It is a necessity to mention that there were considerable variations of DO₂ relative to O₂ in individual patients from time to time over the study period. The clinicians caring for these patients may have been likely to respond to the hemodynamic changes by unnecessary augmentation to obtain "normal" hemodynamic values with no regard for O₂. The potential complications of the unnecessary augmentation of CI and DO₂ under these circumstances are well understood [21, 30] but guidelines for "appropriate" hemodynamic values remain lacking and may only be obtained with improved insights of O₂. For example an uneventful recovery of patient 11 occurred despite the lowest CI and DO₂ throughout the study period allowing for a stable, as well as the lowest, O_2. Treatment aiming to correct hemodynamic imbalance should be guided by information regarding the balance between O₂ and DO₂.

One of the major limitations of our study was the lack of a control group. MUF with postoperative euthermia has become a standard of care in our institution and it was not impossible to justify a control group without MUF with or without the development of postoperative pyrexia. Another limitation was that neonates were not studied. This was because of methodological issues concerning the use of cuffed endotracheal tubes in small infants. Nonetheless we cannot exclude different responses of oxygen transport to CPB because of the possibly different profiles of hormonal and inflammatory responses in younger patients [31, 32]

The hitherto unreported continuous decrease in O₂ during the first 12 hours after CPB with the use of MUF in this study suggests improved balance between oxygen consumption (O₂) and delivery (DO₂) in these euthermic infants with depressed cardiac function. Thus despite a falling CI and DO₂ the fall in O₂ obviated the considerable imbalance in oxygen transport. Indeed the more direct manipulation of O₂ under circumstances of reduced CI and DO₂ warrants further investigation into the management of postoperative low cardiac output syndrome.

	Acknowledgments

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
We thank Sally Cai, data manager (Congenital Heart Surgeons' Society), for her statistical advice.

	References

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 

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