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Prediction of volatile anaesthetic solubility in blood and priming fluids for extracorporeal circulation

2001; Elsevier BV; Volume: 86; Issue: 3 Linguagem: Inglês

10.1093/bja/86.3.338

1471-6771

Rebecca Yu, Zhou Jian-xin, Jin Liu,

Intensive Care Unit Cognitive Disorders

Volatile anaesthetics are often used during cardiopulmonary bypass (CPB). To understand the kinetics of inhaled anaesthetics during CPB, anaesthetists should understand changes in blood solubility caused by fluid use. We set out to predict the solubility of three volatile anaesthetics, desflurane, isoflurane and halothane, during CPB by determining: (i) their solubility in fresh whole blood and eight CPB priming fluids at 37°C; (ii) the effect of temperature on the solubility of these anaesthetics in lactated Ringer's, gelofusin, banked blood and plasma; (iii) their solubility in different mixtures of these four priming fluids at different temperatures; and (iv) their estimated and actual solubility in blood during hypothermic CPB. We calculated solubility using a concept of volume fraction partition coefficient and compared estimated and measured solubilities. For the three anaesthetics tested, solubilities are in the order: fresh whole blood ≈ plasma > banked blood > normal saline ≈ lactated Ringer's ≈ gelofusin ≈ Haemaccel ≈ hydroxyethyl starch > mannitol. The solubilities of the anaesthetics in all priming fluids increased logarithmically at lower temperatures (P banked blood > normal saline ≈ lactated Ringer's ≈ gelofusin ≈ Haemaccel ≈ hydroxyethyl starch > mannitol. The solubilities of the anaesthetics in all priming fluids increased logarithmically at lower temperatures (P<0.05). The volume-fraction estimates of the partition coefficients were within approximately ±20% of the measured values for all values of solubility. The corresponding estimates of solubility for CPB blood samples were between –36% and +24% of the measured values. During normothermic CPB, blood solubility of volatile anaesthetics would be unchanged when using plasma, slightly reduced when using banked blood and markedly reduced when using crystalloids and colloids. During cardiopulmonary bypass (CPB), volatile anaesthetics can be added to the oxygenator to provide anaesthesia,1Woodcock TE Murkin JM Farrar JK Tweed A Guiraudon GM McKenzie FN Pharmacologic EEG suppression during cardiopulmonary bypass: cerebral haemodynamic and metabolic effects of thiopental or isoflurane during hypothermia and normothermia.Anesthesiology. 1987; 67: 218-224Crossref PubMed Scopus (69) Google Scholar 2Loomis CW Brunet D Milne B Cervenko FW Johnson GD Arterial isoflurane concentration and EEG burst suppression during cardiopulmonary bypass.Clin Pharmacol Ther. 1986; 40: 304-313Crossref PubMed Scopus (20) Google Scholar regulate systemic vascular resistance3Norden I The influence of anaesthetics on systemic vascular resistance during cardiopulmonary bypass.Scand J Thorac Cardiovasc Surg. 1974; 8: 81-87Crossref PubMed Scopus (16) Google Scholar 4Hess W Arnold B Schulte-Sasse U et al.Comparison of isoflurane and halothane when used to control intraoperative hypertension in patients undergoing coronary artery bypass surgery.Anesth Analg. 1983; 62: 15-20Crossref PubMed Scopus (33) Google Scholar and reduce hormonal responses to CPB.5Balasaraswathi K Glisson SN El-Etr AA et al.Haemodynamic and catecholamine response to isoflurane anaesthesia in patients undergoing coronary artery surgery.Can Anaesth Soc J. 1982; 29: 533-538Crossref PubMed Scopus (12) Google Scholar 6Flezzani P Croughwell ND Mclntyre RW Reves JG Isoflurane decreases the cortisol response to cardiopulmonary bypass.Anesth Analg. 1986; 65: 1117-1122Crossref PubMed Scopus (22) Google Scholar The rate of wash-in and wash-out of volatile anaesthetics via oxygenators depends on their solubility in blood.7Nussmeier NA Moskowitz GJ Weiskopf RB Cohen NH Fisher DM Eger II, EI In vitro anesthetic washin and washout via bubble oxygenators: Influence of anesthetic solubility and rates of carrier gas inflow and pump blood flow.Anesth Analg. 1988; 67: 982-987Crossref PubMed Google Scholar Two important factors affect the solubility of volatile anaesthetics: hypothermia increases solubility,7Nussmeier NA Moskowitz GJ Weiskopf RB Cohen NH Fisher DM Eger II, EI In vitro anesthetic washin and washout via bubble oxygenators: Influence of anesthetic solubility and rates of carrier gas inflow and pump blood flow.Anesth Analg. 1988; 67: 982-987Crossref PubMed Google Scholar, 8Eger RR Eger II, EI Effect of temperature and age on the solubility of enflurane, halothane, isoflurane, and methoxyflurane in human blood.Anesth Analg. 1985; 64: 640-642Crossref PubMed Scopus (46) Google Scholar, 9Lockwood GG Sapsed-Byrne SM Smith MA Effect of temperature on the solubility of desflurane, sevoflurane, enflurane and halothane in blood.Br J Anaesth. 1997; 79: 517-520Crossref PubMed Scopus (39) Google Scholar, 10Ikeda S Determination of the solubility of halothane in canine blood and cerebral tissue at hypothermia, using a tonometer for constant-gas-flow equilibration.Anesthesiology. 1972; 37: 87-91Crossref PubMed Scopus (5) Google Scholar, 11Laasberg LH Hedley-Whyte J Halothane solubility in blood and solutions of plasma proteins: effects of temperature, protein composition and hemoglobin concentration.Anesthesiology. 1970; 32: 351-356Crossref PubMed Scopus (33) Google Scholar, 12Han YH Helrich M Effect of temperature on solubility of halothane in human blood and brain tissue homogenate.Anesth Analg. 1966; 45: 775-780Crossref PubMed Scopus (8) Google Scholar but crystalloid haemodilution decreases it.11Laasberg LH Hedley-Whyte J Halothane solubility in blood and solutions of plasma proteins: effects of temperature, protein composition and hemoglobin concentration.Anesthesiology. 1970; 32: 351-356Crossref PubMed Scopus (33) Google Scholar 12Han YH Helrich M Effect of temperature on solubility of halothane in human blood and brain tissue homogenate.Anesth Analg. 1966; 45: 775-780Crossref PubMed Scopus (8) Google Scholar Although the effect of hypothermia on solubilities in saline and plasma has been studied,12Han YH Helrich M Effect of temperature on solubility of halothane in human blood and brain tissue homogenate.Anesth Analg. 1966; 45: 775-780Crossref PubMed Scopus (8) Google Scholar and although the effects of hypothermia and crystalloid haemodilution on blood solubility of halothane, enflurane and isoflurane have been observed in CPB,13Nussmeier NA Lambert ML Moskowitz BA et al.Washin and washout of isoflurane administered via bubble oxygenators during hypothermia cardiopulmonary bypass.Anesthesiology. 1989; 71: 519-525Crossref PubMed Scopus (49) Google Scholar, 14Sada T Maguire HT Aldrete JA Halothane solubility in blood during cardiopulmonary bypass: the effect of haemodilution and hypothermia.Can J Anaesth. 1979; 26: 164-167Crossref Scopus (9) Google Scholar, 15Feingold A Crystalloid hemodilution, hypothermia, and halothane blood solubility during cardiopulmonary bypass.Anesth Analg. 1977; 56: 622-626Crossref PubMed Scopus (13) Google Scholar, 16Tarr TJ Snowdon SL Blood/gas solubility coefficient and blood concentration of enflurane during normothermia and hypothermic cardiopulmonary bypass.J Cardiothorac Vasc Anesth. 1991; 5: 111-115Abstract Full Text PDF PubMed Scopus (14) Google Scholar the solubility of volatile anaesthetics in colloid and other priming fluids has not been investigated. Data for the recently introduced agent, desflurane, are limited. To provide such information for predicting blood/gas partition coefficients (λB/G) during CPB, we studied the following: (i) solubility of desflurane, isoflurane and halothane in eight CPB priming fluids; (ii) effect of temperature on the solubility of these anaesthetics in four CPB priming fluids; (iii) estimated and measured solubilities of the three anaesthetics in different combinations of the four priming fluids at different temperatures; and (iv) predicted and measured λB/G of the three agents during hypothermic CPB. Liquid/gas partition coefficients (λ) were measured using a two-stage headspace equilibration method (see below) for fresh whole blood, plasma, banked blood, CPB priming fluids, mixtures of different primes, and diluted blood in CPB. Coefficients were obtained for desflurane, isoflurane and halothane simultaneously by using a mixture of the three anaesthetic vapours in air. The solubilities of desflurane, isoflurane and halothane in banked blood (Blood Bank, Beijing, China), plasma (Blood Bank, Beijing), normal saline (China Dazhong, Tianjing, China), lactated Ringer's solution (China Dazhong, Tianjing, China), gelofusin (Braun, Switzerland), Haemaccel (Behring, Germany), hydroxyethyl starch (Changshu Pharmaceutical, Jiangshu, China) and mannitol (ZhenDa TianQing, Jiangshu, China) were measured by gas chromatography (see below). We used 10 samples of each solution at 37°C. To compare fresh whole blood with banked blood, the solubility in fresh whole blood (Fuwai Hospital, Beijing, China) and ACD solution (Fuwai Hospital) was measured. Collection of fresh whole blood was approved by the Committee of Scientific Research in Fuwai Hospital and informed consent was obtained from each of the 10 male healthy volunteers aged 23 (22–25) yr (mean (range)). The solubility of desflurane, isoflurane and halothane in lactated Ringer's solution (a crystalloid solution), gelofusin (a colloid solution), plasma and banked blood was measured at 37, 33, 29, 25, 21 and 17°C. We used six samples of each fluid at each temperature. Lactated Ringer's solution, gelofusin, plasma and banked blood were mixed in different proportions, as determined by a computer, to give 494 mixtures, each with a volume of approximately 270 ml. We randomly chose 10 of these mixtures which had different proportions of the four constituents (Table 1). The solubilities of desflurane, isoflurane and halothane in these 10 mixtures were measured at 37, 33, 29, 25, 21 and 17°C, using six samples from each mixture at each temperature. Estimated λ of the mixtures was calculated from the equation: estimated λ=Σ(λx×Fx) where λx is the solubility of the agent in each constituent x and Fx is the fractional concentration of each constituent in the total mixture. We called this the volume fraction partition coefficient.Table 1Composition of mixtures of priming fluidsAmount (ml) in mixtureMixtureLactated Ringer'sGelofusinPlasmaBanked blood154108010825454108543102686834468343413652160054639193390745459090845135900919307701039154770 Open table in a new tab After approval from the Committee of Scientific Research in Fuwai Hospital, we obtained informed consent from 20 adult patients undergoing valve replacement surgery requiring CPB. Patients were anaesthetized using total intravenous anaesthesia. Lactated Ringer's solution or gelofusin was administered before CPB. The CPB circuit were primed with lactated Ringer's solution and gelofusin. Blood samples were taken 15 min after the beginning of CPB to allow a steady state to be reached after haemodilution by priming fluid. Urine output, type and volume of infused fluids, and CPB priming fluid were noted. Blood loss was estimated before the blood sample was collected. The solubility of desflurane, isoflurane and halothane in each blood sample (measured λB/G of diluted blood in CPB) were measured at 37, 33, 29, 25, 21 and 17°C. The solubilities of the three anaesthetics in each blood sample were estimated using the concept of volume fraction partition coefficient. The method is given in the Appendix. Anaesthetic concentration was measured with a GOW-MAC 580 gas chromatograph equipped with a 6 m stainless steel column (0.32 cm internal diameter) packed with Chromosorb-P60/80 mesh maintained at 75°C. We used a 10 ml min−1 nitrogen carrier flow, and a flame ionization detector supplied with hydrogen at 35 ml min−1 and air at 300 ml min−1. The output was passed to a TAI-SSC922 integrator and peak areas were calculated. Under these conditions, the peaks of desflurane, isoflurane and halothane were completely separated. Primary and secondary (compressed gas tank) standards were used for calibration. Primary standards were made by injecting an aliquot of each anaesthetic into a glass flask of known volume with a syringe. Because of the high saturated vapour pressure of desflurane, we took steps to ensure that no desflurane was lost. Liquid desflurane and the syringe were kept at 4°C in a refrigerator. Liquid desflurane was drawn into the cool syringe at 4°C in the refrigerator and was injected into the flask or tank immediately. The primary standards (glass flask) were used to calibrate the secondary standards; the secondary standards (tank) were injected at intervals to calibrate the gas chromatograph during each study. All R2 of the linear regression between concentration of anaesthetics and peak area of gas chromatography output were higher than 0.9995 throughout the study. The regression equation was used to convert peak area to agent concentration. Peak areas were proportional to concentrations over the entire range of the concentrations tested. A gas mixture of desflurane, isoflurane and halothane for equilibration in solubility determination was prepared as follows. A stainless steel cylinder (8.1 litres) was evacuated to a pressure of about 0.5 atm less than ambient. Liquid desflurane, isoflurane and halothane were aspirated into the cylinder and the cylinder was filled with compressed air. We calculated the volume of the three liquid anaesthetics transferred into the cylinder and the compressed air pressure required in the cylinder to ensure that the total pressure of each anaesthetic in the cylinder was <90% of its saturated vapour pressure. The cylinder was rolled for 30 min to mix the contents in the cylinder thoroughly. The anaesthetic concentrations in the cylinder were then calibrated using the primary standard; it contained 1.65% desflurane, 1.78% isoflurane and 1.85% halothane. A 20 ml gas-tight glass syringe, calibrated precisely and capped with a three-way stopcock, was sealed by coating the plunger with a thin layer of silicone grease. The gas-tightness of these grease-sealed syringes was tested before the study: the concentrations of anaesthetic vapours in the syringes decreased by no more than 2% over 8 h. This also showed that the grease did not absorb anaesthetic. Approximately 7 ml of liquid sample was drawn into a syringe and the above-mentioned anaesthetic gas mixture was added to give 18 ml; the three-way stopcock was then closed. The syringe was shaken vigorously and immersed in a waterbath at the chosen test temperature. Every 15 min for 2 h, the syringe was shaken vigorously for 5–10 s. After the third shaking, the plunger of the syringe was withdrawn to the 20 ml position with the stopcock closed, causing a small negative pressure in the syringe. The stopcock was then opened briefly to allow air into the syringe and to restore ambient pressure in the syringe. After this 2 h period (the first equilibration period), the concentration of anaesthetic (C1) in the gas phase of the syringe was analysed by gas chromatography. All the gas and some of the liquid in the syringe were expelled and exactly 4 ml of liquid sample (VL) was retained in the syringe for the second equilibration. Vapour-free air was drawn in to move the plunger to the 18 ml position. The syringe was shaken vigorously and immersed in the waterbath with the same temperature as in the first equilibration period. The second equilibration had the same sequence of shaking, volume adjustment and timing as in the first equilibration. At the end of the second equilibration period, the concentrations of anaesthetics in gas phase (C2) were analysed by gas chromatography. The total amount of anaesthetic (ml, in liquid plus gas phase) after the second equilibration is equal to that in the liquid phase which was retained in syringe after the first equilibration. This relationship can be expressed as: C2×VG+CL2×VL=CL1×VL(1) where VG and VL are the gas volume and sample volume retained in the syringe for the second equilibration, respectively; CL1 and CL2 are the anaesthetic concentrations in liquid samples at the end of the first and second equilibration, respectively. λ is defined as the ratio of anaesthetic concentration (vol%) in liquid phase to that in gas phase (vol%), e.g. CL1=λ×C1 and CL2=λ×C2. Substituting these into equation (1) yields: C2×VG+λ×C2×VL=λ×C1×VL This equation can be rearranged to give: λ=(VG/VL)×(C2/(C1-C2)) Equation (3) was used to calculate λ. Means and standard deviations were obtained for λ in priming fluids and blood. Solubilities in each priming fluid at 37°C for each anaesthetic were compared with those in fresh whole blood using Student's t-test. The ratio of mean solubility in each priming fluid and mean solubility in fresh whole blood (RP/B) was calculated. Repeated-measures analysis of variance was used to determine the difference among the three anaesthetics for each priming fluid. We related logeλ in each fluid to temperature, and calculated residual standard deviation (RSD) and 95% confidence limits (CL) of the slope and intercept of the regression lines. To assess the concept of volume fraction partition coefficient and the methods of predicting solubility given in the Appendix, regression and Bland and Altman's 'limits of agreement' analysis17Bland JM Altman DG Statistical methods for assessing agreement between two methods of clinical measurement.Lancet. 1986; i: 307-310Abstract Scopus (39371) Google Scholar were performed between estimated λ in mixtures of priming fluids and in CPB blood and the corresponding measured λ. P 0.05), but were significantly greater than those in the other priming fluids and in ACD solution (P<0.05).Table 2Solubility of desflurane, isoflurane and halothane in eight priming fluids, fresh whole blood and ACD solution at 37°C (n=10). Data are shown as mean (sd) [95% CL]. RP/B is the ratio of mean solubility in each priming fluid to mean solubility in fresh whole blood for a given anaestheticPriming fluidDesfluraneIsofluraneHalothaneλRP/BλRP/BλRP/BFresh whole blood0.522 (0.056) [0.482–0.562]1.343 (0.117) [1.259–1.427]2.435 (0.245) [2.260–2.610]Plasma0.525 (0.043) [0.494–0.555]1.0061.350 (0.121) [1.264–1.436]1.0052.215 (0.208) [2.066–2.363]0.910Banked blood0.454 (0.028) [0.434–0.475]0.8701.169 (0.101) [1.097–1.241]0.8702.141 (0.151) [2.033–2.249]0.879Normal saline0.282 (0.011) [0.274–2.290]0.5400.529 (0.019) [0.515–0.542]0.3940.755 (0.027) [0.736–0.775]0.301Lactated Ringer's0.279 (0.008) [0.273–0.284]0.5340.532 (0.015) [0.521–0.543]0.3960.757 (0.025) [0.739–0.774]0.311Gelofusine0.280 (0.011) [0.272–0.288]0.5360.564 (0.023) [0.547–0.580]0.4200.776 (0.022) [0.760–0.792]0.319Haemaccel0.284 (0.010) [0.277–0.292]0.5440.562 (0.016) [0.550–0.573]0.4180.783 (0.021) [0.768–0.798]0.322Hydroxyethyl starch0.279 (0.011) [0.271–0.286]0.5340.545 (0.020) [0.531–0.560]0.4060.769 (0.027) [0.750–0.788]0.316Mannitol0.218 (0.009) [0.212–0.225]0.4180.442 (0.017) [0.429–0.454]0.3290.654 (0.024) [0.637–0.671]0.269ACD solution0.293 (0.004) [0.289–0.296]0.5610.557 (0.010) [0.550–0.563]0.4150.779 (0.023) [0.753–0.785]0.320 Open table in a new tab For all three anaesthetics, the liquid/gas partition coefficients increased as temperature decreased (Table 3; four CPB priming fluids in step (ii), diluted blood during CPB in step (iv)). To estimate λ in CPB blood in step (iv), we used λ values from our previous study.18Zhou JX Liu YQ Liu J The combined effect of hypothermia and crystalloid hemodilution on the blood solubility of volatile anesthetics.Anesthesiology. 1998; 89: A504Crossref Google Scholar The solubilities were in the order: desflurane < isoflurane < halothane in all conditions. As temperature decreased, logeλ increased linearly (P<0.05). The temperature coefficient of λ (percentage change in λ per degree centigrade) was calculated.19Allott PR Steward A Flook V et al.Variation with temperature of the solubilities of inhaled anaesthetics in water, oil and biological media.Br J Anaesth. 1973; 45: 294-300Crossref PubMed Scopus (59) Google ScholarTable 3Solubility of anaesthetics in four fluids, fresh whole blood (from previous study18) and CPB blood at different temperatures. Data are shown as mean (sd). Temp. coef.=temperature coefficient (%/°C), i.e. the slope of regression line of logeλ on temperature in °C19SolutionsNumber of samplesTemp. coef.(%/°C)Temperature (°C)373329252117DesfluraneLactated Ringer's6–4.160.283 (0.005)0.314 (0.003)0.343 (0.005)0.438 (0.024)0.532 (0.035)0.629 (0.064)Gelofusin6–3.090.303 (0.005)0.346 (0.013)0.393 (0.007)0.463 (0.005)0.522 (0.011)0.545 (0.033)Banked blood6–2.780.459 (0.036)0.529 (0.055)0.581 (0.015)0.646 (0.038)0.754 (0.026)0.792 (0.035)Plasma6–2.750.484 (0.007)0.547 (0.014)0.602 (0.011)0.744 (0.019)0.780 (0.015)0.809 (0.015)Fresh whole blood6–2.830.550 (0.019)0.626 (0.021)0.684 (0.038)0.724 (0.030)0.800 (0.044)1.036 (0.092)Diluted blood in CPB20–4.200.379 (0.045)0.413 (0.040)0.499 (0.047)0.587 (0.042)0.697 (0.077)0.867 (0.102)IsofluraneLactated Ringer's6–4.810.541 (0.015)0.599 (0.012)0.696 (0.033)0.888 (0.066)1.142 (0.112)1.345 (0.121)Gelofusin6–3.940.550 (0.027)0.676 (0.030)0.762 (0.009)0.926 (0.015)1.080 (0.033)1.203 (0.078)Banked blood6–3.751.118 (0.105)1.334 (0.206)1.539 (0.070)1.811 (0.119)2.120 (0.135)2.347 (0.149)Plasma6–3.961.166 (0.034)1.369 (0.026)1.412 (0.041)1.943 (0.067)2.324 (0.089)2.416 (0.113)Fresh whole blood6–3.741.377 (0.050)1.610 (0.164)1.832 (0.135)2.088 (0.208)2.568 (0.282)2.888 (0.231)Diluted blood in CPB20–4.660.967 (0.137)1.071 (0.140)1.306 (0.111)1.548 (0.206)1.875 (0.327)2.461 (0.324)HalothaneLactated Ringer's6–4.730.742 (0.026)0.845 (0.027)0.993 (0.048)1.283 (0.106)1.545 (0.088)1.843 (0.143)Gelofusin6–3.970.792 (0.033)0.945 (0.051)1.051 (0.058)1.302 (0.026)1.540 (0.046)1.719 (0.117)Banked blood6–4.251.812 (0.221)1.981 (0.323)2.342 (0.177)3.050 (0.136)3.598 (0.335)3.954 (0.385)Plasma6–4.491.900 (0.056)2.204 (0.061)2.311 (0.063)3.084 (0.116)3.914 (0.126)4.461 (0.246)Fresh whole blood6–4.332.588 (0.119)3.115 (0.370)3.593 (0.315)4.175 (0.436)5.238 (0.421)6.175 (0.490)Diluted blood in CPB20–4.921.730 (0.265)1.850 (0.268)2.399 (0.388)2.800 (0.534)3.365 (0.738)4.641 (0.796) Open table in a new tab Details of the fitted linear equations for the dependence of logeλ on temperature are given in Table 4. The RSDs are in terms of logeλ and lie between 0.021 and 0.075 for different media at different temperatures; these correspond to RSDs of between 2.1% and 7.5% of the arithmetic values of λ.Table 4Regression equations for predicting solubility from temperature (°C) for four priming fluids, fresh whole blood (from previous study18) and CPB blood. Logeλ=slope×T(°C)+intercept. RSD=residual standard deviation; R2=coefficient of determination for regression line; CL=confidence limitSlope (95% CL)Intercept (95% CL)RSDR2DesfluraneLactated Ringer's–0.042 (–0.050, –0.033)–0.221 (–0.026, 0.467)0.05320.976Gelofusin–0.031 (–0.037, –0.025)–0.034 (–0.198, 0.130)0.03540.982Banked blood–0.028 (–0.032, –0.024)0.266 (0.151, 0.382)0.02500.988Plasma–0.027 (–0.036, –0.019)0.309 (0.070, 0.549)0.05190.951Fresh whole blood–0.028 (–0.038, –0.018)0.437 (0.160, 0.714)0.06000.940Diluted blood in CPB–0.042 (–0.048, –0.036)0.536 (0.366, 0.706)0.03680.990IsofluraneLactated Ringer's–0.048 (–0.057, –0.039)1.102 (0.853, 1.352)0.05400.982Gelofusin–0.039 (–0.044, –0.035)0.883 (0.753, 1.013)0.02820.992Banked blood–0.038 (–0.041, –0.034)1.518 (1.419, 1.618)0.02150.996Plasma–0.040 (–0.052, –0.027)1.604 (1.257, 1.951)0.07520.951Fresh whole blood–0.037 (–0.041, –0.034)1.700 (1.600, 1.800)0.02170.996Diluted blood in CPB–0.047 (–0.055, –0.039)1.636 (1.412, 1.859)0.04840.984HalothaneLactated Ringer's–0.047 (–0.053, –0.041)1.413 (1.252, 1.574)0.03480.992Gelofusin–0.040 (–0.044, –0.035)1.237 (1.109, 1.366)0.02780.994Banked blood–0.043 (–0.051, –0.034)2.132 (1.894, 2.370)0.05160.980Plasma–0.045 (–0.056, –0.034)2.254 (1.938, 2.569)0.06840.968Fresh whole blood–0.043 (–0.047, –0.039)2.547 (2.439, 2.655)0.02340.996Diluted blood in CPB–0.049 (–0.060, –0.038)2.297 (1.987, 2.607)0.06710.974 Open table in a new tab As anticipated, logeλ of desflurane, isoflurane and halothane in the prime mixtures increased linearly as temperature decreased. We found a direct linear relationship between logarithm of estimated λ (logeλe) and measured λ (logeλm) in mixed primes for desflurane, isoflurane and halothane (P<0.05, Figure 1a). Figure 1b shows the 'limits of agreement' analysis between estimated and measured logeλ. The mean difference between estimated and measured logeλ was –0.010 and the sd was 0.105, which indicated that the estimated λ in the mixtures of primes were within +22% and –20% of the measured values of λ. A direct linear relationship was found between the logarithm of estimated λ (logeλe, calculated according to Appendix) and measured λ (logeλm) in CPB blood (P banked blood > normal saline ≈ lactated Ringer's solution ≈ gelofusine ≈ Haemaccel ≈ hydroxyethyl starch ≈ ACD solution > mannitol (Table 2). This order implies that, during normothermic infusion and normothermic CPB, λ in diluted blood would be unchanged by using plasma, slightly decreased by using banked blood and greatly decreased by using crystalloid and colloid solutions. As anticipated, reduction in temperature caused an increase in solubility of the anaesthetics in all priming fluids, mixtures and CPB blood. This is consistent with the change for fresh whole blood.7Nussmeier NA Moskowitz GJ Weiskopf RB Cohen NH Fisher DM Eger II, EI In vitro anesthetic washin and washout via bubble oxygenators: Influence of anesthetic solubility and rates of carrier gas inflow and pump blood flow.Anesth Analg. 1988; 67: 982-987Crossref PubMed Google Scholar, 8Eger RR Eger II, EI Effect of temperature and age on the solubility of enflurane, halothane, isoflurane, and methoxyflurane in human blood.Anesth Analg. 1985; 64: 640-642Crossref PubMed Scopus (46) Google Scholar, 9Lockwood GG Sapsed-Byrne SM Smith MA Effect of temperature on the solubility of desflurane, sevoflurane, enflurane and halothane in blood.Br J Anaesth. 1997; 79: 517-520Crossref PubMed Scopus (39) Google Scholar, 10Ikeda S Determination of the solubility of halothane in canine blood and cerebral tissue at hypothermia, using a tonometer for constant-gas-flow equilibration.Anesthesiology. 1972; 37: 87-91Crossref PubMed Scopus (5) Google Scholar, 11Laasberg LH Hedley-Whyte J Halothane solubility in blood and solutions of plasma proteins: effects of temperature, protein composition and hemoglobin concentration.Anesthesiology. 1970; 32: 351-356Crossref PubMed Scopus (33) Google Scholar, 12Han YH Helrich M Effect of temperature on solubility of halothane in human blood and brain tissue homogenate.Anesth Analg. 1966; 45: 775-780Crossref PubMed Scopus (8) Google Scholar 18Zhou JX Liu YQ Liu J The combined effect of hypothermia and crystalloid hemodilution on the blood solubility of volatile anesthetics.Anesthesiology. 1998; 89: A504Crossref Google Scholar Table 3 gives the temperature coefficients of λ. Taking all agents and all solutions tested in this study into account, no correlation was found between temperature coefficient and its λ at 37°C. However, for a given solution (with a minor exception for lactated Ringer's), the magnitudes of the temperature coefficients were in the same order as the partition coefficients at 37°C: desflurane < isoflurane < halothane. We assumed that the solubility of an anaesthetic in a mixture of different solutions is equal to the sum of the solubility in each component multiplied by its volume fraction, a concept we call 'volume fraction partition coefficient'. This concept was substantiated in this study. For example, 1 unit of banked blood (250 ml in volume) used in this study consists of 200 ml (80% in volume fraction) whole blood and 50 ml (20% in volume fraction) ACD solution, and solubility of desflurane in banked blood at 37°C would be (0.52×80%)+(0.29×20%). The estimated solubilities of desflurane, isoflurane and halothane in banked blood were 0.47, 1.18 and 2.10, respectively, almost identical to the measured solubilities of banked blood (0.45, 1.17 and 2.14, respectively; Table 2). We also estimated solubility in 10 mixtures containing different proportions of priming fluids and found a close relationship between measured and estimated solubility (Figure 1a). The limits of agreement (equal to mean±2 sd of the differences, which will include about 95% of the data points) are 0.201 and –0.221 (Figure 1b). We have shown that the solubility of volatile anaesthetics in CPB primes can be predicted and that the concept of volume fraction partition coefficient is useful for the prediction. For the agents studied, wash-in and wash-out will be quickest for desflurane and slowest for halothane at any given temperature, and slower at low temperature for all agents (Table 3), but quicker on dilution of blood with priming fluids (other than plasma) (Table 2). During CPB, hypothermia will increase anaesthetic blood solubility and haemodilution will reduce it. The effects of these two factors on blood solubility of halothane, enflurane and isoflurane have been observed in CPB.13Nussmeier NA Lambert ML Moskowitz BA et al.Washin and washout of isoflurane administered via bubble oxygenators during hypothermia cardiopulmonary bypass.Anesthesiology. 1989; 71: 519-525Crossref PubMed Scopus (49) Google Scholar, 14Sada T Maguire HT Aldrete JA Halothane solubility in blood during cardiopulmonary bypass: the effect of haemodilution and hypothermia.Can J Anaesth. 1979; 26: 164-167Crossref Scopus (9) Google Scholar, 15Feingold A Crystalloid hemodilution, hypothermia, and halothane blood solubility during cardiopulmonary bypass.Anesth Analg. 1977; 56: 622-626Crossref PubMed Scopus (13) Google Scholar, 16Tarr TJ Snowdon SL Blood/gas solubility coefficient and blood concentration of enflurane during normothermia and hypothermic cardiopulmonary bypass.J Cardiothorac Vasc Anesth. 1991; 5: 111-115Abstract Full Text PDF PubMed Scopus (14) Google Scholar It is not practical to monitor the solubility of the anaesthetics during CPB. If body temperature and the nature and degree of haemodilution by priming fluid are monitored, solubility can be estimated to within about –36% to 24% of the measured value (Figure 2). Therefore, changes in the rates of wash-in and wash-out of the anaesthetics are likely. Our methods have some limitations. We cannot accurately estimate blood loss and circulating blood volume and did not take metabolism of colloid into account. This may have caused the systematically greater value of limits of agreement in predicting λ in CPB blood than that in prime mixtures (–36% to +24% in CPB blood compared with about ±20% in prime mixtures). However, our method will help anaesthetists judge changes in blood solubility of volatile anaesthetics during CPB, and the effect of this change on their pharmacokinetics. This work was supported by a grant from the National Research Foundation of Natural Sciences, Beijing, People's Republic of China and a grant from the Research Foundation of National Education, Beijing, People's Republic of China. (1)Estimate following circulating volumes (ml): (i) fresh whole blood volume (Vfwb), i.e. patient's body weight (kg) multiplied by 70 (ml kg−1); (ii) net added crystalloid volume (Vcry), i.e. (infused crystalloid plus primed crystalloid minus urine output)/3; (iii) added colloid volume (Vcol), i.e. infused colloid plus primed colloid; (iv) added banked blood volume (Vbb), i.e. infused banked blood plus primed banked blood; (v) added plasma volume (Vp), i.e. infused plasma plus primed plasma; and (vi) total circulating blood volume (Vtotal) = Vfwb+Vcry+Vcol+Vbb+Vp. (2) Calculate solubilities for fresh whole blood (λfwb), crystalloid (λcry), colloid (λcol), banked blood (λbb) and plasma (λp) at the temperature at which λ is estimated by using the equations in Table 4. (3) Estimated λ of CPB blood=((Vfwb×λwb)+(Vcry× λcry)+(Vcol×λcol)+(Vbb×λbb)+(Vp×λp))/Vtotal