HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Author home page(s): Robert E. Anderson Thomas A. Orszulak Richard C. Daly Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Cook, D. J. Articles by Bryce, R. D. Search for Related Content PubMed PubMed Citation Articles by Cook, D. J. Articles by Bryce, R. D. Related Collections Related Article

Ann Thorac Surg 1995;59:614-620
© 1995 The Society of Thoracic Surgeons

Cerebral Blood Flow During Cardiac Operations: Comparison of Kety-Schmidt and Xenon-133 Clearance Methods

Department of Anesthesiology and the Section of Cardiothoracic Surgery, Department of Surgery, and Department of Neurosurgical Research, Mayo Clinic, Rochester, Minnesota

Accepted for publication November 4, 1994.

	Abstract

Top Footnotes Abstract Introduction Methods Results Comment Acknowledgments References

 
This study simultaneously compared the standard Kety-Schmidt and the modified xenon-133 (¹³³Xe) clearance techniques for measuring cerebral blood flow (CBF) and cerebral metabolic rate for oxygen (CMRO₂) during cardiac operations. The validity of the CBF method is important because our management of the patient during cardiopulmonary bypass (CPB) is based, in part, on our understanding of the cerebral hemodynamics during CPB. In 20 patients undergoing coronary artery bypass grafting, CBF and CMRO₂ were determined by both methods. Measurements were made before onset of CPB and once during CPB. Ten patients underwent CPB with systemic normothermia (37°C) and 10 with systemic hypothermia (27°C). Anesthesia consisted of fentanyl and midazolam. CPB pump flows were kept at 2.2 to 2.4 L • min^-1 • m^-2 and -stat pH management was used. Xenon-133 clearance significantly underestimated CBF and CMRO₂ relative to the Kety-Schmidt technique before CPB and at both bypass temperatures. Values obtained by ¹³³Xe clearance were approximately 50% of that measured by the Kety-Schmidt method. The modified ¹³³Xe technique as typically used during cardiac operations does not appear to measure CBF accurately; this leads to corresponding errors in CMRO₂ calculations. Determination of CMRO₂ and cerebral autoregulatory function during cardiac operations appears to be more appropriate if based on the more direct Kety-Schmidt technique. Accordingly, our management of CPB with respect to cerebral perfusion as it has been determined by the modified ¹³³Xe clearance method may require reassessment.

	Introduction

Top Footnotes Abstract Introduction Methods Results Comment Acknowledgments References

 
The purpose of this study was to compare two methods for measuring cerebral blood flow (CBF) and cerebral metabolic rate for oxygen (CMRO₂) in patients undergoing cardiac operations. Because our understanding of cerebral hemodynamics forms part of the basis for our management of cardiopulmonary bypass (CPB), it is essential that the methodology used to measure CBF and CMRO₂ is accurate. Virtually all studies in humans during cardiac operations and CPB have used a modification of the intraarterial xenon-133 (¹³³Xe) clearance technique. The original intraarterial ¹³³Xe technique involved injection of a bolus of ¹³³Xe into the internal carotid artery. Gamma emission was determined by one or more extracranial detectors and the rate of ¹³³Xe clearance allowed determination of CBF [1]. The original intraarterial method generated CBF results close to that of the gold standard, the Kety-Schmidt technique [1]. Because the detector is extracranial, it will measure blood flow to both cerebral and noncerebral tissues if ¹³³Xe injection occurs proximal to the internal carotid artery. As blood flow to scalp, bone, and other noncerebral tissue is less than that to brain, the ¹³³Xe technique may systematically underestimate CBF under these conditions.

For editorial comment, see page 558.

The intraarterial ¹³³Xe technique was modified for use during cardiac operations because it is simple and relatively noninvasive. This was in contrast to the Kety-Schmidt technique, which requires access to cerebral venous drainage and the cumbersome analysis of multiple arterial and venous blood samples for determination of saturation curves.

Because of the inaccessibility of the internal carotid artery, investigators using ¹³³Xe clearance during cardiac operations have used common carotid or brachiocephalic artery ¹³³Xe injection or injection into the arterial inflow line of the extracorporeal circuit, or both. This modification of the original technique may lead to erroneous results.

Delivery of ¹³³Xe at sites proximal to the internal carotid artery are likely to exaggerate the underestimation of CBF using the ¹³³Xe technique. Injection of ¹³³Xe proximal to the internal carotid artery results in the delivery of a greater proportion of the ¹³³Xe bolus to lower the flow to extracranial tissues. Furthermore, proximal injection sites may result in a slurred peak of cerebral radioactivity that would cause further underestimation of calculated CBF. The Kety-Schmidt technique is not subject to these errors.

The Kety-Schmidt technique for measuring CBF is an application of the Fick principle, which is subject to minimal artifact [2]. This methodology depends on the direct measurement of arterial and cerebral venous blood concentrations of an inert, freely diffusible indicator. Rate of uptake of the indicator from cerebral tissue into the cerebral venous blood allows calculation of CBF. If venous sampling is from the jugular bulb, contamination from extracerebral tissues is negligible [3]. Therefore, flows determined by the Kety-Schmidt technique represent global brain–blood flow. Because of its solid theoretical foundation, limited assumptions, and the directness of the technique, the Kety-Schmidt method has been the standard to which other methods are compared [4]. However, because of its complexity, it has been uncommonly used since the introduction of ¹³³Xe clearance.

A comparison of CBF methodologies during cardiac operations recently was called for in an editorial by Prough and Rogers [5]: ``. . . a conclusive validation study must compare the Kety-Schmidt technique to clearance of ¹³³Xe injected into the arterial side of the oxygenator circuit in hypothermic patients undergoing CPB.'' This study compares those methods under prebypass, normothermic (37°C), and hypothermic (27°C) bypass conditions.

	Methods

Top Footnotes Abstract Introduction Methods Results Comment Acknowledgments References

 
After institutional approval (November 18, 1993) and written informed consent, 20 patients undergoing elective first-time cardiac operation for coronary artery bypass grafting were studied. Ten patients were randomized to undergo CPB with systemic hypothermia (27°C) and 10 with systemic normothermia (37°C). Patients with clinical or laboratory evidence of cerebrovascular disease, allergy to radiographic contrast, increased intracranial pressure, or insulin-dependent diabetes mellitus, and those with uncontrolled hypertension were excluded from the study.

Anesthesia consisted of a high-dose fentanyl–midazolam technique (loading doses, fentanyl 30 µg • kg^-1 and midazolam 100 µg • kg^-1, followed by an infusion of 0.3 µg • kg^-1 • min^-1 fentanyl and midazolam 0.4 µg • kg^-1 • min^-1). Inspired oxygen fraction was maintained between 40% and 70%. Arterial, pulmonary artery, and right atrial blood pressures, heart rate, end-tidal carbon dioxide concentrations, and nasopharyngeal temperature were continuously measured. A catheter was placed percutaneously in the right jugular bulb after anesthetic induction to allow sampling of cerebral venous blood. Catheter position was confirmed by fluoroscopy in all patients.

During CPB, a nonpulsatile pump flow of 2.2 to 2.4 L • min^-1 • m^-2 was maintained. The arterial carbon dioxide tension (PaCO₂) was adjusted to normocapnic levels (35 to 40 mm Hg) without temperature correction (-stat regulation). The bypass pump was primed to maintain a hematocrit of 23% or greater during the bypass period. All aortic cannulations occurred at the ascending aortic arch. Sodium nitroprusside or phenylephrine infusions were used during CPB to maintain a mean arterial blood pressure of 50 to 70 mm Hg. Nasopharyngeal temperature was measured continuously as an indirect indicator of brain temperature.

The CBF both by Kety-Schmidt and ¹³³Xe clearance techniques was measured simultaneously during two periods: (1) prebypass before aortic cannulation and (2) during CPB. In patients undergoing hypothermic CPB, CBF measurements were made when the nasopharyngeal temperature was stable at 27°C; in patients undergoing normothermic CPB, measurements were made after 30 minutes on CPB at 37°C. Mean arterial blood pressure, pump flow rate during CPB, and nasopharyngeal temperature were stable before measurements were made.

Global CBF was measured according to the nitrous oxide (N₂O) method of Kety and Schmidt [2]. Prebypass, 10% N₂O was introduced into the inspiratory gas flow of an air–oxygen mixture. During CPB, 10% N₂O was introduced into the pump oxygenator. Ten timed collections of radial arterial and cerebral venous blood were drawn during 15 minutes of N₂O exposure. Each sample of 1.5 mL was drawn over 30 seconds and placed on ice. The N₂O concentration was measured in the blood samples on an infrared N₂O analyzer (trace N₂O monitor, Dynatech Electro-optics, Saline, MI). The CBF was calculated from curves fit to the measured N₂O concentrations and integrated to infinity (see Appendix 1).

The CBF during each period was calculated as follows [2]:

where = the brain–blood solubility coefficient for N₂O; V(t) = the venous N₂O reading at saturation; and (a - v)dt = the area circumscribed by the difference in arterial and venous N₂O concentration curves.

The brain–blood solubility coefficient () for N₂O was corrected for temperature during hypothermic CPB based on N₂O solubility changes in oil and water at 27°C [6]. Regional CBF was determined from clearance curves obtained from the extracranial detection of intraarterially injected ¹³³Xe. The measurement technique has been described in detail previously [7], with the exception that in this study the indicator was injected into either the right common carotid (n = 2) or the brachiocephalic artery (n = 18) before CPB. Prebypass, the injectate contained 2 to 4 mCi of ¹³³Xe diluted to 1.5 to 2.0 mL total volume with physiologic saline. The ¹³³Xe was monitored by a single thallium-activated sodium iodide detector placed adjacent to and at right angles to the right parietal bone (see Appendix 1) [7].

During CPB, 4 to 6 mCi of ¹³³Xe diluted in 3.0 to 4.0 mL of saline was injected into a port on the arterial inflow circuit [8–10]. A minimum of 30 minutes elapsed between the before CPB and CPB measurements in all patients. The partition coefficient for ¹³³Xe was corrected as necessary for both alterations in hematocrit and temperature during CPB [11].

If the PaCO₂ between the two measurement periods differed, the prebypass CBF (by both methods) was corrected by 3% for each mm Hg difference in PaCO₂ [12, 13].

The CMRO₂ was calculated to be the product of the CBF (by either method) and the arteriovenous oxygen content difference. Arterial and venous oxygen content at 27°C were calculated after the oxygen tension was determined at 27°C using the method of Severinghaus [14] (see Appendix 1).

For each measurement technique and each patient group (normothermic, hypothermic), the Wilcoxon signed rank test was used to compare changes in CBF and CMRO₂ from the before CPB to the CPB periods. In addition, for each study condition, the Wilcoxon rank sum test was used to compare the CBF and CMRO₂ determinations made by the two CBF methodologies. When multiple comparisons were made on the same individuals, a p value of less than or equal to 0.01 was considered significant. All data are given as mean ± standard deviation.

	Results

Top Footnotes Abstract Introduction Methods Results Comment Acknowledgments References

 
Physiologic variables in each study period for both groups are summarized in Table 1. Mean arterial blood pressure and hemoglobin differed from the prebypass to the bypass period in both groups. The prebypass PaCO₂ tended to be lower than the bypass PaCO₂ in both groups. During CPB, the normothermic and hypothermic groups differed only with respect to mean temperature. Mean arterial blood pressure, hemoglobin, arterial oxygen tension, and PaCO₂ did not differ between the normothermic and hypothermic groups (Table 1).

View larger version (17K): [in this window] [in a new window]   Fig 1. . Cerebral blood flow (CBF) during the three study conditions by the two measurement techniques. In the prebypass period n = 20; n = 10 in the two cardiopulmonary bypass (CPB) periods. (#Between-groups differences by Wilcoxon rank sum test (p 0.01); *change from before CPB within groups (p 0.01) by Wilcoxon signed rank test.)

During normothermic CPB (n = 10), mean CBF_K-S was 51 ± 10 mL • 100 g^-1 • min^-1, whereas CBF_xe was 29 ± 8 mL • 100 g^-1 • min^-1 (n = 10); the ¹³³Xe technique underestimated CBF_K-S by 43%. During normothermic CPB, CBF_K-S increased significantly as compared with the prebypass value (51 versus 36 mL • 100 g^-1 • min^-1). Similar increases in CBF during normothermic CPB were demonstrated by the ¹³³Xe technique (29 versus 18 mL • 100 g^-1 • min^-1). This increase in CBF was highly significant by both techniques (p < 0.01 Wilcoxon signed rank test) (Fig 1). The CBF_K-S and CBF_xe differed at the level p < 0.01 during all three study conditions (Wilcoxon rank sum test).

The prebypass CMRO₂ as determined by the Kety-Schmidt technique was 2.55 ± 1.22 mL • 100 g^-1 • min^-1 and by CBF_xe was 1.23 ± 0.51 mL • 100 g^-1 • min^-1 (n = 20) (Fig 2).

View larger version (18K): [in this window] [in a new window]   Fig 2. . Cerebral metabolic rate (CMRO2) during the three study conditions by the two measurement techniques. In the prebypass period n = 20; n = 10 in the two cardiopulmonary bypass (CPB) periods. (#Between-groups differences by Wilcoxon rank sum test (p 0.01); * change from before CPB within groups (p 0.01) by Wilcoxon signed rank test.)

During normothermic CPB at 37°C, CMRO₂ was 2.35 ± 0.33 and 1.32 ± 0.30 mL • 100 g^-1 • min^-1 by the Kety-Schmidt and xenon techniques, respectively. The CMRO₂ did not differ from the prebypass value as measured by either method (Fig 2).

The metabolic rates determined by the Kety-Schmidt and xenon techniques during each study condition differed at the level of p 0.01 by Wilcoxon rank sum test (Fig 2).

	Comment

Top Footnotes Abstract Introduction Methods Results Comment Acknowledgments References

 
The ¹³³Xe clearance technique as modified to measure CBF during cardiac operations systematically underestimates CBF during both bypass and nonbypass conditions as compared with the standard Kety-Schmidt method. Cerebral metabolic values as derived from CBF measurements are similarly underestimated. This is of importance because our management of patients during CPB with respect to cerebral perfusion is based largely on reports of CBF and CMRO₂ measurements using the modified ¹³³Xe technique.

The method of regional CBF_xe determination used was the initial slope calculation, an analysis technique that emphasizes the cortical, fast flow component of CBF [1]. Conversely, the N₂O saturation curves for the Kety-Schmidt technique were integrated to infinity, an analysis technique that will minimize the global flows calculable by the Kety-Schmidt method [4]. In spite of this, the CBF measurements obtained by the two techniques were very different (Fig 3) and opposite to what might have been predicted from the above considerations (ie, the CBF_xe would be greater than the CBF_K-S).

View larger version (21K): [in this window] [in a new window]   Fig 3. . Cerebral blood flow (CBF) measured by the Kety-Schmidt technique (CBFK-S) plotted against cerebral blood flow measured by the xenon-133 technique (CBFxe) during each of the three study periods in mL • 100 g-1 • min-1. Before cardiopulmonary bypass (CPB), 20 patients; CPB 27°C, 10 patients; CPB 37°C, 10 patients.

Accurate measurement of CBF and CMRO₂ using the ¹³³Xe technique is predicated on minimizing artifact attributable to contamination of radioactivity in extracerebral tissues and near instantaneous arrival of the bolus into the counting field [18]. If this is not achieved, CBF is underestimated. In our experience, injection of ¹³³Xe proximal to the internal carotid leads to lower peak counts than is achieved by an internal carotid injection, the rate of rise is slower and the peak somewhat slurred. This, together with distribution of large amounts of ¹³³Xe to the extracerebral tissues, may explain the low CBF values obtained with ¹³³Xe during cardiac operations. Direct injection of ¹³³Xe into the internal carotid artery or common carotid artery injection with external carotid clamping, as during carotid operations, minimizes these problems. However, these techniques are not feasible during cardiac operations as they require either carotid dissection or arteriography.

The Kety-Schmidt technique, on the other hand, is subject to minimal extracerebral contamination [3], therefore, flow determinations closely approximate actual global CBF. Our results and those of Stephan and colleagues [19], who used similar methodology, are in agreement and are significantly greater than those reported with ¹³³Xe. In addition, the Kety-Schmidt values we report closely approach the predicted theoretical [5] and measured values in humans under fentanyl–midazolam anesthesia [19] and those measured by more direct techniques in animals [16, 17].

The Kety-Schmidt technique with shorter N₂O uptake periods has the potential to overestimate CBF [20], particularly at low CBFs. However, according to Lassen and Klee [21], this potential error ``. . . may be counteracted by prolonging the saturation period to 15 or 20 minutes and by extrapolation of the curves to infinity.'' Both of these steps were undertaken in our study design and data analysis, therefore, risk for overestimation of CBF by incomplete equilibration of tissue and venous N₂O is minimal.

Both the Kety-Schmidt technique and the ¹³³Xe clearance technique appear to measure the relative change in CBF and CMRO₂ that occurs with decreasing temperature, but the absolute values determined by the ¹³³Xe technique in our study and in previous reports of CBF and CMRO₂ during cardiac operations may be incorrect [8–10, 15]. These values are not consistent with previously measured values in awake or anesthetized humans by either the Kety-Schmidt [2, 4] or internal carotid ¹³³Xe techniques [4, 22].

On the basis of previous hypothermia studies in animals and humans [17, 23], we expected a significant decrease in CBF with cooling but this was not seen. The hemodilution that occurs with initiation of CPB (Table 1) results in a decrease in blood viscosity. This decrease in viscosity probably preserves CBF during decreasing oxygen demand. Decreased CPB hematocrit would also explain the increase in CBF we documented during normothermic bypass where CMRO₂ is unchanged. In the absence of this hemodilution, we estimate that CBF at 27°C would have decreased by an additional 43%.

Because the N₂O blood–brain partition coefficient has not been reported at 27°C, we estimated this coefficient change. Although this might be criticized, the maximum predicted change in over the 10°C temperature change in our study was 11% [6]. This estimation is consistent with the chemical properties of a gas with a low solubility such as N₂O [24] whose partition coefficient is close to unity at 37°C [25]. This solubility change minimally affects our CBF_K-S results and does not impact on the qualitative relationship between CBF_K-S and CBF_xe that we report.

Our use of a single gamma detector for ¹³³Xe measurements might also be criticized. However, single detectors provide reliable values under nonbypass conditions [4], and it appears that our regional measurements are representative of hemispheric flows. The CBF values that we report here using a single probe are not different from investigations that used multiple detectors under similar conditions [8–10, 15].

Lassen [4] proposed that CBF measurements deviating significantly from established values are ``. . . clear indications of gross systematical errors....'' The same is true of CMRO₂ measurements. Although the circulatory conditions of CPB are abnormal, reported CBF values of 10 to 20 mL • 100 g^-1 • min^-1 and CMRO₂ values of 0.3 to 0.6 mL • 100 g^-1 • min^-1 [8, 9, 15] make little physiologic sense even at 27°C. The values we report using the Kety-Schmidt methodology under nonbypass, normothermic, and hypothermic bypass conditions are reasonable and consistent with theoretical predictions in humans and reported values in humans and animals.

The commonly used modification of the ¹³³Xe clearance method for CBF measurements during cardiac operations and CPB appears to be unacceptable. As characteristically used CBF and CMRO₂ are systemically underestimated. This has the potential to lead to misunderstandings of cerebral hemodynamics during cardiac operations and accordingly a reevaluation of our management of CPB with regard to the cerebral circulation may be required.

	Appendix

 
Cerebral Blood Flow Methodologies
Kety-Schmidt
Before bypass 10% N₂O was introduced into the inspiratory gas flow with an air–oxygen mixture. End-tidal PaCO₂ and hemodynamics were stable before measurement was initiated. A time zero sample of 1.5 mL of arterial blood was drawn as a baseline for N₂O content and then CBF measurements were made over a 15-minute N₂O uptake period. Ten paired radial arterial and jugular bulb venous samples were drawn on the following schedule: (arterial) 0, 0.25, 1.25, 2.25, 3.25, 4.25, 6.25, 8.25, 10.25, 12.25, and 14.25 minutes of N₂O exposure; (venous) 0.5, 1.5, 2.5, 3.5, 4.5, 6.5, 8.5, 10.5, 12.5, and 14.5 minutes of N₂O exposure. Each sample of 1.5 mL was drawn anaerobically over 30 seconds in heparinized syringes. The dead space volume of catheter and lines as well as volume and rate of dead space drawn between measured samples was determined so the exact time that arterial and venous samples were drawn from the circulation was known. Samples were placed immediately on ice and the N₂O concentration (ppm) in each sample was determined with an infrared N₂O analyzer (trace N₂O monitor; Dynatech Electro-optics, Saline, MI) (resolution 1 ppm, calibrated with 87 ppm span gas). The CBF was then calculated from arterial and venous uptake curves fit to the measured N₂O concentrations and integrated to infinity (Fig 4).

View larger version (20K): [in this window] [in a new window]   Fig 4. . Representative arterial and venous nitrous oxide (N20) uptake curves from a patient during cardiopulmonary bypass at 27°C.(CBF = cerebral blood flow.)

where = the brain–blood solubility coefficient for N₂O; V(t) = the venous N₂O reading at saturation; and (a - v)dt = the area circumscribed by the difference in the arterial and venous N₂O concentration curves.

The reported value of 1.06 for was used when body temperature was 37°C [25]. When the patient was hypothermic (27°C), was estimated based on the changing solubility of N₂O in oil and water at 27°C [6]. A of 0.94 was used for CBF determinations done at 27°C.

During CPB, 10% N₂O was introduced into the fresh gas flow. Paired arterial and jugular bulb venous measurements were taken on the schedule as described. During CPB, arterial blood was drawn from a shunt line taken off the arterial inflow line of the CPB machine rather than the radial artery.

If PaCO₂, mean arterial blood pressure, or pump flow rate varied by more than 15% during a study period, the study period was aborted and was resumed a minimum of 15 minutes later to insure residual N₂O had been cleared from the circulation. A repeat time zero baseline N₂O was then drawn.

Xenon-133 Clearance
Regional CBF was determined from clearance curves obtained from the extracranial detection of intraarterially injected ¹³³Xe. The ¹³³Xe was monitored by a single thallium-activated sodium iodide detector. The crystal, 1.25-inch in diameter by 0.25-inch thick, was recessed 1 inch behind a tapered lead collimator with an opening widening from 0.875 to 1.125 inches at the surface of the crystal. The detector was placed adjacent to and at right angles to the skull over the parietal boss [7].

Prebypass, ¹³³Xe dissolved in saline was injected into the exposed right brachiocephalic artery (18 patients) or the right common carotid artery (2 patients). In the prebypass period, the injectate contained 2 to 4 mCi of ¹³³Xe diluted in 1.5 to 2.0 mL total volume with saline. This measurement was done simultaneously with the Kety-Schmidt method.

An initial slope method was used to determine regional CBF by ¹³³Xe. After injection of ¹³³Xe, a pulse was initiated by the operator to start the timing circuit. The sampling of the logarithmic peak count rate was delayed by 10 seconds to compensate for the lag time of the clearance curve. This peak count was then held for 1 minute by a sample/hold circuit while a differential amplifier subtracted the count rate of the logarithmic curve at the end of 1 minute. This value was then multiplied by a noninverting amplifier, by 20.01 to give the product of the partition coefficient for ¹³³Xe, and the factor 2.3 for converting common to natural logarithms, and to increase the gain 10-fold to drive the digital panel meter [7]. The complete clearance curve for each CBF_xe was generated, although the ISI technique used samples of gamma counts at two discrete points.

Regional blood flow computed by this automated analyzer has shown excellent correlation with the manual method of computation. The coefficient of correlation (r) comparing manual computation and this automated method was 0.95 with p < 0.001 based on 181 previous measurements [7].

For the ¹³³Xe measurement during bypass, 4 to 6 mCi of ¹³³Xe diluted in 3.0 to 4.0 mL of saline was injected into a port on the arterial inflow circuit distal to the membrane oxygenator. Detection was as described above. A minimum of 30 minutes elapsed between the before CPB and CPB measurements in all patients. The bypass CBF_xe measurement was done simultaneously with the Kety-Schmidt determination. The partition coefficient () for ¹³³Xe was corrected as necessary for both alterations in hematocrit and temperature during CPB according to the method of, and results obtained by Chen and colleagues [11] for brain and blood at 27°C and 37°C:

where _tb = tissue–blood partition coefficient for ¹³³Xe; _tp = tissue–plasma partition coefficient for ¹³³Xe; _cp = red cell–plasma partition coefficient for ¹³³Xe; and H = hematocrit.

The PaCO₂ tended to be different in the prebypass and bypass measurement periods. To allow for CBF comparisons at equivalent PaCO₂, the prebypass CBF (by both methods) was corrected by 3% for each mm Hg difference in PaCO₂ when the prebypass PaCO₂ differed from that during CPB [12, 13].

Cerebral Metabolism Measurement
The CMRO₂ was determined from the product of the arteriovenous oxygen content difference and the CBF (by both methods). Arterial and jugular bulb blood gas tensions and saturations were determined (IL-BGE Analyzer, IL 4-286 Co-Oximeter; Instrumentation Laboratories, Inc, Boston, MA) during both CBF measurement periods. Blood gas tensions were measured at 37°C and the arterial and venous oxygen tensions were subsequently back-corrected to a blood temperature of 27°C when the patient was hypothermic. The formula of Severinghaus [14] was used:

The arterial and venous oxygen content, AVDO₂, and CMRO₂ at 27°C were calculated based on this temperature correction.

CMRO₂ for oxygen:

Arteriovenous oxygen content difference (determined at 37°C):

where Hb = hemoglobin concentration; SxO₂ = oxygen saturation; and PxO₂ = partial pressure of oxygen₂, CvO₂, and CxO₂.

	Acknowledgments

Top Footnotes Abstract Introduction Methods Results Comment Acknowledgments References

 
This study was supported by the American Heart Association, Minnesota Affiliate, and Mayo Foundation.

	Footnotes

Top Footnotes Abstract Introduction Methods Results Comment Acknowledgments References

 
Address reprint requests to Dr Cook, Department of Anesthesiology, Mayo Clinic, 200 First St SW, Rochester, MN 55905.

	References

Top Footnotes Abstract Introduction Methods Results Comment Acknowledgments References

 

1. Olesen J, Paulson OB, Lassen NA. Regional cerebral blood flow in man determined by the initial slope of the clearance of intra-arterially injected ¹³³Xe. Stroke 1971;2:519–40.[Abstract/Free Full Text]
2. Kety SS, Schmidt CF. The determination of cerebral blood flow in man by the use of nitrous oxide in low concentrations. Am J Physiol 1945;143:53–66.[Free Full Text]
3. Shenkin HA, Harmel MH, Kety SS. Dynamic anatomy of the cerebral circulation. Arch Neurol Psychiat 1948;60:240–52.
4. Lassen NA. Normal average value of cerebral blood flow in younger adults is 50 ml/100 g/min. J Cereb Blood Flow Metab 1985;5:347–9.[Medline]
5. Prough DS, Rogers AT. What are the normal levels of cerebral blood flow and cerebral oxygen consumption during cardiopulmonary bypass in humans? Anesth Analg 1993;76:690–3.[Free Full Text]
6. Allott PR, Steward A, Flook V, Mapleson WW. Variation with temperature of the solubilities of inhaled anaesthetics in water, oil and biological media. Br J Anaesth 1973;45:294–300.[Free Full Text]
7. Anderson RE, Sundt TM Jr. An automated cerebral blood flow analyzer: concise communication. J Nucl Med 1977;18:728–31.[Abstract/Free Full Text]
8. Croughwell N, Smith LR, Quill T, et al. The effect of temperature on cerebral metabolism and blood flow in adults during cardiopulmonary bypass. J Thorac Cardiovasc Surg 1992;103:549–54.[Abstract]
9. Murkin JM, Farrar JK, Tweed WA, McKenzie FN, Guiraudon G. Cerebral autoregulation and flow/metabolism coupling during cardiopulmonary bypass: the influence of PaCO₂. Anesth Analg 1987;66:825–32.[Abstract/Free Full Text]
10. Rogers AT, Prough DS, Gravlee GP, et al. Sodium nitroprusside infusion does not dilate cerebral resistance vessels during hypothermic cardiopulmonary bypass. Anesthesiology 1991;74:820–6.[Medline]
11. Chen RY, Fan FC, Kim S, Jan KM, Usami S, Chien S. Tissue-blood partition coefficient for xenon: temperature and hematocrit dependence. J Appl Physiol 1980;49:178–83.[Free Full Text]
12. Forster A, Juge O, Morel D. Effects of midazolam on cerebral hemodynamics and cerebral vasomotor responsiveness to carbon dioxide. J Cereb Blood Flow Metab 1983;3:246–9.[Medline]
13. Kety SS, Schmidt CF. The effects of altered arterial tensions of carbon dioxide and oxygen on cerebral blood flow and cerebral oxygen consumption of normal young men. J Clin Invest 1948;27:484–92.
14. Severinghaus JW. Simple, accurate equations for human blood O₂ dissociation computations. J Appl Physiol 1979;46:599–602.[Abstract/Free Full Text]
15. Prough DS, Rogers AT, Stump DA, Mills SA, Gravlee GP, Taylor C. Hypercarbia depresses cerebral oxygen consumption during cardiopulmonary bypass. Stroke 1990;21:1162–6.[Abstract/Free Full Text]
16. Michenfelder JD, Milde JH. The relationship among canine brain temperature, metabolism, and function during hypothermia. Anesthesiology 1991;75:130–6.[Medline]
17. Busija DW, Leffler CW. Hypothermia reduces cerebral metabolic rate and cerebral blood flow in newborn pigs. Am J Physiol 1987;253:H869–73.[Abstract/Free Full Text]
18. Betz E. Cerebral blood flow: its measurement and regulation. Physiol Rev 1972;52:595–630.[Free Full Text]
19. Stephan H, Weyland A, Kazmaier S, Henze T, Menck S, Sonntag H. Acid-base management during hypothermic cardiopulmonary bypass does not affect cerebral metabolism but does affect blood flow and neurological outcome. Br J Anaesth 1992;69:51–7.[Abstract/Free Full Text]
20. Madsen PL, Holm S, Herning M, Lassen NA. Average blood flow and oxygen uptake in the human brain during resting wakefulness: a critical appraisal of the Kety-Schmidt technique. J Cereb Blood Flow Metab 1993;13:646–55.[Medline]
21. Lassen NA, Klee A: Cerebral blood flow determined by saturation and desaturation with krypton₈₅: an evaluation of the validity of the inert gas method of Kety and Schmidt. Circ Res 1965;XVI:26–32.
22. Ingvar DH, Cronqvist S, Ekberg R, Risberg J, Hoedt-Rasmussen K. Normal values of regional cerebral blood flow in man, including flow and weight estimates of gray and white matter. Acta Neurol Scand 1965;41:72–8.
23. Ehrmantraut WR, Ticktin HE, Fazekas JF. Cerebral hemodynamics and metabolism in accidental hypothermia. Arch Intern Med 1957;99:57–9.[Abstract/Free Full Text]
24. White DC, Halsey MJ. Effects of changes in temperature and pressure during experimental anaesthesia. Br J Anaesth 1974;46:196–201.[Free Full Text]
25. Kety SS, Harmel MH, Broomell HT, Rhode CB. The solubility of nitrous oxide in blood and brain. J Biol Chem 1948;173:487–96.[Free Full Text]

This article has been cited by other articles:

				I. MacVeigh, D. J. Cook, T. A. Orszulak, R. C. Daly, and D. E. Munnikhuysen Nitrous Oxide Method of Measuring Cerebral Blood Flow During Hypothermic Cardiopulmonary Bypass Ann. Thorac. Surg., March 1, 1997; 63(3): 736 - 740. [Abstract] [Full Text]

				U. H. Trivedi, R. L. Patel, M. R. J. Turtle, G. E. Venn, and D. J. Chambers Relative Changes in Cerebral Blood Flow During Cardiac Operations Using Xenon-133 Clearance Versus Transcranial Doppler Sonography Ann. Thorac. Surg., January 1, 1997; 63(1): 167 - 174. [Abstract] [Full Text]

				D. J. Cook, W. C. Oliver Jr, T. A. Orszulak, R. C. Daly, and R. D. Bryce Cardiopulmonary Bypass Temperature, Hematocrit, and Cerebral Oxygen Delivery in Humans Ann. Thorac. Surg., December 1, 1995; 60(6): 1671 - 1677. [Abstract] [Full Text]

				D. J. Cook, R. E. Anderson, J. D. Michenfelder, W. C. Oliver Jr, T. A. Orszulak, R. C. Daly, and R. D. Bryce Who's Afraid of Kety-Schmidt? Ann. Thorac. Surg., October 1, 1995; 60 (4): 1156 - 1157. [Full Text]

				W. L. Young, M. F. Newman, D. Amory, and J. G. Reves Cerebral Blood Flow Values During Cardiopulmonary Bypass: Relatively Absolute or Absolutely Relative? Ann. Thorac. Surg., March 1, 1995; 59(3): 558 - 561. [Full Text]

This Article Abstract Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Author home page(s): Robert E. Anderson Thomas A. Orszulak Richard C. Daly Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Cook, D. J. Articles by Bryce, R. D. Search for Related Content PubMed PubMed Citation Articles by Cook, D. J. Articles by Bryce, R. D. Related Collections Related Article