Propofol Linearly Reduces the Vasoconstriction and Shivering Thresholds

Background: Skin temperature is best kept constant when determining response thresholds because both skin and core temperatures contribute to thermoregulatory control. In practice, however, it is difficult to evaluate both warm and cold thresholds while maintaining constant cutaneous temperature. A recent study shows that vasoconstriction and shivering thresholds are a linear function of skin and core temperatures, with skin contributing 20 plus/minus 6% and 19 plus/minus 8%, respectively. (Skin temperature has long been known to contribute [nearly equal] 10% to the control of sweating.) Using these relations, we were able to experimentally manipulate both skin and core temperatures, subsequently compensate for the changes in skin temperature, and finally report the results in terms of calculated core- temperature thresholds at a single designated skin temperature.

Methods: Five volunteers were each studied on 4 days: (1) control; (2) a target blood propofol concentration of 2 micro gram/ml; (3) a target concentration of 4 micro gram/ml; and (4) a target concentration of 8 micro gram/ml. On each day, we increased skin and core temperatures sufficiently to provoke sweating. Skin and core temperatures were subsequently reduced to elicit peripheral vasoconstriction and shivering. We mathematically compensated for changes in skin temperature by using the established linear cutaneous contributions to the control of sweating (10%) and to vasoconstriction and shivering (20%). From these calculated core-temperature thresholds (at a designated skin temperature of 35.7 degrees Celsius), the propofol concentration- response curves for the sweating, vasoconstriction, and shivering thresholds were analyzed using linear regression. We validated this new method by comparing the concentration-dependent effects of propofol with those obtained previously with an established model.

Results: The concentration-response slopes for sweating and vasoconstriction were virtually identical to those reported previously. Propofol significantly decreased the core temperature triggering vasoconstriction (slope = 0.6 plus/minus 0.1 degree Celsius *symbol* micro gram sup -1 *symbol* ml sup -1; r2 = 0.98 plus/minus 0.02) and shivering (slope = 0.7 plus/minus 0.1 degree Celsius *symbol* micro gram sup -1 *symbol* ml sup -1; r2 = 0.95 plus/minus 0.05). In contrast, increasing the blood propofol concentration increased the sweating threshold only slightly (slope = 0.1 plus/minus 0.1 degree Celsius *symbol* micro gram sup -1 *symbol* ml sup -1; r2 = 0.46 plus/minus 0.39).     

Oral Clonidine Premedication Blunts the Heart Rate Response to Intravenous Atropine in Awake Children

Background: Clonidine, which is known to have analgesic and sedative properties, has recently been shown to be an effective preanesthetic medication in children. The drug may cause side effects, including bradycardia and hypotension. This study was conducted to evaluate the ability of intravenous atropine to increase the heart rate (HR) in awake children receiving clonidine preanesthetic medication.

Methods: We studied 96 otherwise healthy children, 8-13 yr old, undergoing minor surgery. They received, at random, oral clonidine 2 or 4 micro gram *symbol* kg sup -1 or placebo 105 min before scheduled induction of anesthesia. Part I (n = 48, 16 per group): When hemodynamic parameters after insertion of a venous catheter had been confirmed to be stable, atropine was administered in incremental doses of 2.5, 2.5, and 5 micro gram *symbol* kg sup -1 every 2 min. The HR and blond pressure were recorded at 1-min intervals. Part II (n = 48, 16 per group): After the recording of baseline hemodynamic values, successive doses of atropine (5 micro gram *symbol* kg sup -1 every 2 min, to 40 micro gram *symbol* kg sup -1), were administered until HR increased by 20 beats *symbol* min sup -1. The HR and blood pressure were recorded at 1-min intervals.

Results: Part I: The increases in HR in response to a cumulative dose of atropine 10 micro gram *symbol* kg sup -1 were 33 plus/minus 3%, 16 plus/minus 3%, and 8 plus/minus 2% (mean plus/minus SEM) in children receiving placebo, clonidine 2 micro gram *symbol* kg sup -1, and clonidine 4 micro gram *symbol* kg sup -1, respectively (P < 0.05). Part II: The HR in the control group increased by more than 20 beats *symbol* min sup -1 in response to atropine 20 micro gram *symbol* kg sup -1 or less. In two patients in the clonidine 4 micro gram *symbol* kg sup -1 group, HR did not increase by 20 beats *symbol* min sup -1 even after 40 micro gram *symbol* kg sup -1 of atropine.     

Consequences of Electroencephalographic-suppressive Doses of Propofol in Conjunction with Deep Hypothermic Circulatory Arrest

Background: Some patients who undergo cerebral aneurysm surgery require cardiopulmonary bypass and deep hypothermic circulatory arrest. During bypass, these patients often are given large doses of a supplemental anesthetic agent in the hope that additional cerebral protection will be provided. Pharmacologic brain protection, however, has been associated with undesirable side effects. These side effects were evaluated in patients who received large doses of propofol.

Methods: Thirteen neurosurgical patients underwent cardiopulmonary bypass and deep hypothermic circulatory arrest to facilitate clip application to a giant or otherwise high-risk cerebral aneurysm. Electroencephalographic burst suppression was established before bypass with an infusion of propofol, and the infusion was continued until the end of surgery. Hemodynamic and echocardiographic measurements were made before and during the prebypass propofol infusion and again after bypass. Emergence time also was determined.

Results: Prebypass propofol at 243 plus/minus 57 micro gram *symbol* kg sup -1 *symbol* min sup -1 decreased vascular resistance from 34 plus/minus 8 to 27 plus/minus 8 units without changing heart rate, arterial or filling pressures, cardiac index, stroke volume, or ejection fraction. Propofol blood concentration was 8 plus/minus 2 micro gram/ml. Myocardial wall motion appeared hyperdynamic at the end of cardiopulmonary bypass, and all patients were weaned therefrom without inotropic support. After bypass, vascular resistance decreased further, and cardiovascular performance was improved compared to baseline values. Nine of the 13 patients emerged from anesthesia and were able to follow commands at 3.1 plus/minus 1.4 h. Three others had strokes and a fourth had cerebral swelling.     

Effect of Vasoconstrictive Agents Added to Lidocaine on Intravenous Lidocaine-induced Convulsions in Rats

Background: Epinephrine is reported to decrease the threshold of intravenous lidocaine-induced convulsions. However, the mechanism underlying this effect is not clear. Therefore, we carried out a study to examine the role of vasopressor-induced hypertension.

Methods: Fifty-six awake Wistar rats were assigned to seven groups of eight. All groups received a continuous intravenous infusion of lidocaine at a rate of 4 mg *symbol* kg sup -1 *symbol* min sup -1 until generalized convulsions occurred. The control group (group C) received plain lidocaine. The acute hypertensive groups received lidocaine with epinephrine (group E), norepinephrine (group N), or phenylephrine (group P) to increase mean arterial blood pressure (MAP) to 150 plus/minus 5 mm Hg. Sodium nitroprusside (SNP) was added to prevent an increase in mean arterial pressure in the remaining three groups (vasopressor-SNP groups).

Results: The acute hypertensive groups required significantly smaller cumulative doses of lidocaine to produce convulsions compared with control (C - 41.5 plus/minus 2.9 > E - 24.1 plus/minus 2.7, N = 27.1 plus/minus 2.8, P = 26.7 plus/minus 2.5 mg *symbol* kg sup -1; values are mean plus/minus SD, P < 0.01) In addition, plasma lidocaine concentrations (C = 11.0 plus/minus 0.7 > E = 7.4 plus/minus 0.5, N = 7.9 plus/minus 0.6, P = 8.1 plus/minus 0.8 micro gram *symbol* ml sup -1, P < 0.01) and brain lidocaine concentrations (C = 50.9 plus/minus 4.5 > E = 32.6 plus/minus 4.2, N - 34.5 plus/minus 4.8, P - 37.1 plus/minus 4.5 micro gram *symbol* g sup -1, P < 0.01) were less in the acute hypertensive groups at the onset of convulsions. In the vasopressor-SNP groups, the plasma and brain lidocaine concentrations at the onset of convulsions returned to the control values, although epinephrine and norepinephrine, but not phenylephrine, still decreased cumulative convulsant doses of lidocaine significantly (P < 0.01) compared with control (E + SNP = 30.8 plus/minus 2.9 < N + SNP = 34.8 plus/minus 2.8, P < 0.01) < P + SNP = 40.2 plus/minus 3.0 mg *symbol* kg sup -1, P < 0.01). The brain/plasma concentration ratios were similar for the seven groups.     

Pharmacokinetics of Propofol after a Single Dose in Children Aged 1-3 Years with Minor Burns: Comparison of Three Data Analysis Approaches

Background: No complete pharmacokinetic profile of propofol is yet available in children younger than 3 yr, whereas clinical studies have demonstrated that both induction and maintenance doses of propofol are increased with respect to body weight in this age group compared to older children and adults. This study was therefore undertaken to determine the pharmacokinetics of propofol after administration of a single dose in aged children 1-3 yr requiring anesthesia for dressing change.

Methods: This study was performed in 12 children admitted to the burn unit and in whom burn surface area was less than or equal to 12% of total body surface area. Exclusion criteria were: unstable hemodynamic condition, inappropriate fluid loading, associated pulmonary injury, or burn injury older than 2 days. Propofol (4 mg *symbol* kg sup -1) plus fentanyl (2.5 micro gram *symbol* kg sup -1) was administered while the children were bathed and the burn area cleaned during which the children breathed spontaneously a mixture of oxygen and nitrous oxide (50:50). Venous blood samples of 300 micro liter were obtained at 5, 15, 30, 60, 90, and 120 min, and 3, 4, 8, and 12 h after injection; an earlier sample was obtained from 8 of 12 children. The blood concentration curves obtained for individual children were analyzed by three different methods: noncompartmental analysis, mixed-effects population model, and standard two-stage analysis.

Results: Using noncompartmental analysis, total clearance of propofol (+/-SD) was 0.053+/-0.013 l *symbol* kg sup -1 *symbol* min sup -1, volume of distribution at steady state 9.5+/-3.7 l *symbol* kg sup -1, and mean residence time 188+/-85 min. Propofol pharmacokinetics were best described by a weight-proportional three-compartmental model in both population and two-stage analysis. Estimated and derived pharmacokinetic parameters were similar using these two pharmacokinetic approaches. Results of population versus two-stage analysis are as follow: systemic clearance 0.049 versus 0.048 l *symbol* kg sup -1 *symbol* min sup -1, volume of central compartment 1.03 versus 0.95 l *symbol* kg sup -1, volume of distribution at steady state 8.09 versus 8.17 l *symbol* kg sup -1.     

Negative and Selective Effects of Propofol on Isolated Swine Myocyte Contractile Function in Pacing-induced Congestive Heart Failure

Background: Although propofol (2-6 di-isopropylphenol) is commonly used to induce and maintain anesthesia and sedation for surgery, systematic hypotension and reduced cardiac output can occur in patients with or without intrinsic cardiac disease. The effect of propofol on myocyte contractility after the development of congestive heart failure (CHF) remains unknown. This study tested the hypothesis that propofol would have direct effects on myocyte contractile function in both healthy and CHF cardiac myocyte preparations.

Methods: Isolated left ventricular (LV) myocyte contractile function (shortening velocity, micro meter/s) was examined in myocytes from five control pigs and in five pigs with pacing-induced CHF (240 beats/min, for 3 weeks) in the presence of propofol concentrations ranging from 1-6 micro gram/ml. In addition, myocyte contractility in response to beta-adrenergic receptor stimulation (isoproterenol, 10-50 nM) in the presence of propofol (3 micro gram/ml) was examined.

Results: Three weeks of pacing caused LV dysfunction consistent with CHF as evidenced by increased LV end-diastolic diameter (control 3.3 +/- 0.1 cm vs. CHF 5.6 +/- 0.2 cm; P < 0.05) and reduced LV fractional shortening (control 34 +/- 3% vs. CHF 12 +/- 2%, P < 0.05). Propofol (6 micro gram/ml) caused a concentration-dependent negative effect on velocity of shortening from baseline in both control (67 +/- 2 micro meter/s vs. 27 +/- 3 micro meter/s; P < 0.05) and CHF myocytes (29 +/- 1 micro meter/s vs. 15 +/- 1 micro meter/s; P < 0.05). Importantly, CHF myocytes were more sensitive than control myocytes to the negative effects of propofol on velocity of shortening at the lower concentration (1 micro gram/ml). beta-adrenergic responsiveness was reduced by propofol (3 micro gram/ml) in control myocytes only.     

Propofol Has No Direct Effect on Sinoatrial Node Function or on Normal Atrioventricular and Accessory Pathway Conduction in Wolff-Parkinson-White Syndrome during Alfentanil/Midazolam Anesthesia

Background: Propofol has been implicated as causing intraoperative bradyarrhythmlas. Furthermore, the effects of propofol on the electrophysiologic properties of the sinoatrial (SA) node and on normal atrioventricular (AV) and accessory pathways in patients with Wolff-Parkinson-White syndrome are unknown. Therefore, this study examined the effects of propofol on the cardiac electrophysiologic properties in humans to determine whether propofol promotes bradyarrhythmias and its suitability as an anesthetic agent in patients undergoing ablative procedures.

Methods: Twelve patients with Wolff-Parkinson-White syndrome undergoing radiofrequency catheter ablation were studied. Anesthesia was induced with alfentanil (50 micro gram/kg), midazolam (0.15 mg/kg), and vecuronium (20 mg) and maintained with alfentanil (2 micro gram *symbol* kg sup -1 *symbol* min sup -1) and midazolam (12 mg, every 15 min, as needed). A electrophysiologic study was performed consisting of measurement of the effective refractory period of the right atrium, AV node, and accessory pathway and the shortest cycle length of the AV node and accessory pathway during antegrade stimulation plus the effective refractory period of the right ventricle and accessory pathway and the shortest cycle length of the accessory pathway during retrograde stimulation. Determinants of SA node function including sinus node recovery time, corrected sinus node recovery time, and SA conduction time; intraatrial conduction time and atrial-His interval also were measured. Reciprocating tachycardia was induced by rapid right atrial or ventricular pacing, and the cycle length and atrial-His, His-ventricular, and ventriculoatrial intervals were measured. Alfentanil/midazolam was then discontinued. Propofol was administered (bolus 2 mg/kg + 120 micro gram *symbol* kg sup -1 *symbol* min sup -1), and the electrophysiologic measurements were repeated.

Results: Propofol caused a statistically significant but clinically unimportant prolongation of the right atrial refractory period. The effective refractory periods of the AV node, right ventricle, and accessory pathway, as well as the shortest cycle length, were not affected. Parameters of SA node function and intraatrial conduction also were not affected. Sustained reciprocating tachycardia was inducible in 8 of 12 patients, and propofol had no effect on its electrophysiologic properties. All accessory pathways were successfully identified and ablated.     

Myocardial effects of eltanolone in hamsters with hypertrophic cardiomyopathy

Eltanolone is a new short-acting i.v. induction agent that induces less cardiovascular depression than propofol or thiopentone and has no significant effect on intrinsic contractility in normal myocardium. However, its effects on diseased myocardium are unknown. We have studied in vitro the effects of eltanolone 0.1, 1, and 10 micrograms ml- 1 on the intrinsic contractility of left ventricular papillary muscles from normal hamsters and those with hypertrophic cardiomyopathy (strain BIO 14.6, 6-month-old) (Krebs-Henseleit solution, 29 degrees C, pH 7.40, Ca2+ 2.5 mmol litre-1, stimulation frequency 3 min-1). Cardiac hypertrophy (mean 134 (SD 9)%, P < 0.001) was observed in cardiomyopathic hamsters. Contractility of papillary muscles from hamsters with cardiomyopathy was less than that of controls, as shown by the lower active isometric force (8 (3) vs 35 (14) mN mm-2, P < 0.001). Eltanolone did not induce any significant inotropic or lusitropic effects in normal hamsters, and the effects of eltanolone were not significantly different between normal hamsters and those with cardiomyopathy.      

Propofol Fails to Attenuate the Cardiovascular Response to Rapid Increases in Desflurane Concentration

Background: A rapid increase in desflurane concentration to greater than 1 MAC transiently increases heart rate, arterial blood pressure, and circulating catecholamine concentration. Because propofol decreases sympathetic outflow, it was hypothesized that propofol would blunt these responses.

Methods: To test this hypothesis, five healthy male volunteers were studied three times. After induction of anesthesia with 2 mg *symbol* kg sup -1 propofol, anesthesia was maintained with 4% end-tidal desflurane in oxygen (0.55 MAC) via an endotracheal tube for 32 min. On separate occasions, in random order, either no propofol or 2 mg *symbol* kg sup -1 propofol was administered either 2 or 5 min before increasing end-tidal desflurane concentration from 4% to 8%.

Results: Without propofol pretreatment, the increase to 8% desflurane transiently increased heart rate (from 63+/-3 beats/min to 108 +/-5 beats/min, mean+/-SEM; P < 0.01), mean arterial pressure (from 73+/-1 mmHg to 118+/-6 mmHg; P < 0.01), and epinephrine concentration (from 14+/-1 pg *symbol* ml sup -1 to 279+/-51 pg *symbol* ml sup -1; P < 0.05). There was no significant change in norepinephrine concentration (from 198+/-37 pg *symbol* ml sup -1 to 277+/-46 pg *symbol* ml sup -1). The peak plasma epinephrine concentration was attenuated by each propofol pretreatment (158+/-35 pg *symbol* ml sup -1, propofol given 2 min before, and 146 + 41 pg *symbol* ml sup -1, propofol given 5 min before; P < 0.05), but neither propofol pretreatment modified the cardiovascular or norepinephrine responses.     

Prediction of Movement during Propofol/Nitrous Oxide Anesthesia: Performance of Concentration, Electroencephalographic, Pupillary, and Hemodynamic Indicators

Background: Movement in response to painful stimulation is the end point classically used to assess the potency of anesthetic agents. In this study, the ability of modeled propofol effect-site concentration to predict movement in volunteers during propofol/nitrous oxide anesthesia was tested, then it was compared with the predictive abilities of the Bispectral Index and 95% spectral edge frequency of the electroencephalogram, pupillary reflex amplitude, and systolic arterial blood pressure. In addition, the relationships between simple end points of loss and recovery of consciousness, and pupillary, hemodynamic, and propofol concentration indicators were studied.

Methods: Ten healthy volunteers were anesthetized with an infusion of propofol, which was increased in three equal steps to 21 mg *symbol* kg lean body mass sup -1 *symbol* h sup -1. After loss of the ability to hold a syringe and of the eyelash reflex, 60% nitrous oxide was introduced and the trachea was intubated without the use of muscle relaxants. The propofol infusion rate then was decreased to 15.4 mg *symbol* kg lean body mass sup -1 *symbol* h sup -1. Ten minutes later, tetanic electrical stimulation was administered to the thigh via needle electrodes: if movement was observed within 1 min, the propofol infusion rate was increased by 1.75 mg *symbol* kg lean body mass sup -1 *symbol* h sup -1 5 min after the stimulus; if not, it was similarly decreased. This 15-min sequence was repeated until volunteers "crossed over" from movement to no movement (or vice versa) four times. The propofol infusion rate then was increased to 21 mg *symbol* kg lean body mass sup -1 *symbol* h sup -1, nitrous oxide was discontinued, the trachea was extubated, and the infusion rate was decreased in five equal steps over 50 min. The times at which the eyelash reflex returned and the birth date was recalled were recorded. The electroencephalogram was monitored continuously (FP1, FP2, ref: nasion, ground: mastoid). Measurements of the pupillary response, arterial blood pressure, and heart rate were recorded during induction and awakening, just before and for 5 min after each stimulation. Arterial blood samples were obtained for propofol assay, and propofol effect-site concentrations were calculated at each time. The predictive value of indicators was compared using a new statistic, the prediction probability (PK).

Results: Loss and return of the eyelash reflex occurred at greater propofol effect-site concentrations than either dropping the syringe or recall of the birthday. The propofol effect-site concentration (in the presence of 60% nitrous oxide) predicted to prevent movement after a supramaximal stimulus in 50% of volunteers was 1.80 micro gram/ml (95% confidence limits: 1.40-2.34 micro gram/ml). The Bispectral Index (PK = 0.86), 95% spectral edge frequency (PK = 0.81), pupillary reflex amplitude (PK = 0.74), and systolic arterial blood pressure (PK = 0.78) did not differ significantly from modeled propofol effect-site concentration (PK = 0.76) in their ability to predict movement.     

Effects of Fentanyl on Sympathetic Activation Associated with the Administration of Desflurane

Background: Activation of the sympathetic nervous system occurs when desflurane is inspired shortly after anesthetic induction and when the inspired concentration of desflurane is rapidly increased during steady-state periods of anesthesia. The purpose of this study was to determine the effectiveness and dose response of fentanyl pretreatment in attenuating the neurocirculatory responses to desflurane in healthy human volunteers.

Methods: After Institutional Research Review Board approval, three study groups were selected and, in random order, received either placebo (n = 10), a 2.5-micro gram *symbol* kg sup -1 intravenous bolus of fentanyl citrate followed by a continuous infusion of 1 micro gram *symbol* kg sup -1 *symbol* h sup -1 (n = 9), or a 5.0-micro gram *symbol* kg sup -1 intravenous bolus followed by an infusion of 2 micro gram *symbol* kg sup -1 *symbol* h sup -1 (n = 11) before the administration of desflurane. Arterial (MAP) and central venous (CVP) pressures were measured directly, and heart rate (HR) was determined indirectly. Efferent muscle sympathetic nerve activity (SNA) was recorded from the peroneal nerve by microneurography. After neurocirculatory recordings at conscious unmedicated baseline and 12 min after fentanyl administration, anesthetic induction was carried out with 2.0 mg *symbol* kg sup -1 propofol and 0.2 mg *symbol* kg sup -1 vecuronium. Neurocirculatory measurements were repeated beginning 2 min after induction when desflurane was given via mask (semiclosed circle system, 6 l/min fresh gas flow, 100% Oxygen2) in three incremental 1-min steps (3.6%, 7.2% and 11%). Intubation occurred 10 min after propofol administration. Twenty minutes after intubation, recordings were obtained during two steady-state periods during which end-tidal concentrations had achieved 5.4% (0.75 MAC) and 11% (1.5 MAC) desflurane for at least 10 min. Data also were obtained during the rapid increase in the inspired gas concentration from 5.4% to 11% ("transition").

Results: Neurocirculatory variables did not differ between the three groups at conscious baseline, after fentanyl, and during steady-state periods of anesthesia. Propofol administration significantly reduced SNA and MAP. The MAP reduction was enhanced in the fentanyl-treated groups. After induction, the increases in SNA and MAP associated with the administration of desflurane by mask were not significantly reduced by fentanyl. The transition from 5.4% to 11% desflurane resulted in increases in SNA, HR, MAP, and fentanyl administration significantly attenuated the HR and MAP components. At the 11% steady-state measurement period, CVP was increased and MAP was decreased from conscious baseline, and these changes were not modified by fentanyl.     

pH-Stat Management Reduces the Cerebral Metabolic Rate for Oxygen during Profound Hypothermia (17 degrees Celsius): A Study during Cardiopulmonary Bypass in Rabbits

Background: Greater cerebral metabolic suppression may increase the brain's tolerance to ischemia. Previous studies examining the magnitude of metabolic suppression afforded by profound hypothermia suggest that the greater arterial carbon dioxide tension of pH-stat management may increase metabolic suppression when compared with alpha-stat management.

Methods: New Zealand White rabbits, anesthetized with fentanyl and diazepam, were maintained during cardiopulmonary bypass (CPB) at a brain temperature of 17 degrees Celsius with alpha-stat (group A, n = 9) or pH-stat (group B, n = 9) management. Measurements of brain temperature, systemic hemodynamics, arterial and cerebral venous blood gases and oxygen content, cerebral blood flow (CBF) (radiolabeled microspheres), and cerebral metabolic rate for oxygen (CMRO2) (Fick) were made in each animal at 65 and 95 min of CPB. To control for arterial pressure and CBF differences between techniques, additional rabbits underwent CPB at 17 degrees Celsius. In group C (alpha-stat, n = 8), arterial pressure was decreased with nitroglycerin to values observed with pH-stat management. In group D (pH-stat, n = 8), arterial pressure was increased with angiotensin II to values observed with alpha-stat management. In groups C and D, CBF and CMRO2 were determined before (65 min of CPB) and after (95 min of CPB) arterial pressure manipulation.

Results: In groups A (alpha-stat) and B (pH-stat), arterial pressure; hemispheric CBF (44 plus/minus 17 vs. 21 plus/minus 4 ml *symbol* 100 g sup -1 *symbol* min sup -1 [median plus/minus quartile deviation]; P = 0.017); and CMRO2 (0.54 plus/minus 0.13 vs. 0.32 plus/minus 0.10 ml Oxygen2 *symbol* 100 g sup -1 *symbol* min sup -1; P = 0.0015) were greater in alpha-stat than in pH-stat animals, respectively. As a result of arterial pressure manipulation, in groups C (alpha-stat) and D (pH-stat) neither arterial pressure (75 plus/minus 2 vs. 78 plus/minus 2 mm Hg) nor hemispheric CBF (40 plus/minus 10 vs. 48 plus/minus 6 ml *symbol* 100 g sup -1 *symbol* min sup -1; P = 0.21) differed between alpha-stat and pH-stat management, respectively. Nevertheless, CMRO2 was greater in alpha-stat than in pH-stat animals (0.71 plus/minus 0.10 vs. 0.45 plus/minus 0.10 ml Oxygen2 *symbol* 100 g sup -1 *symbol* min sup -1, respectively; P = 0.002).     

Anesthetic Potency of Remifentanil in Dogs

Background: Remifentanil is an opioid that is rapidly inactivated by esterases in blood and tissues. This study examined the anesthetic potency and efficacy of remifentanil in terms of its reduction of enflurane minimum alveolar concentration (MAC) in dogs.

Methods: Twenty-five dogs were anesthetized with enflurane. One group received incremental infusion rates of remifentanil from 0.055 to 5.5 micro gram *symbol* kg sup -1 *symbol* min sup -1. A second group received constant rate infusions of remifentanil of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 for 6-8 h. Enflurane MAC was measured before, hourly during remifentanil infusion, and at the end of the experiment after naloxone administration. A third group received alternating infusions of 0.5 and 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 with MAC determinations made 30 min after each change in the infusion rate. Heart rate, mean arterial pressure, and remifentanil blood concentrations were measured during MAC determinations.

Results: Enflurane MAC was reduced up to a maximum of 63.0+/- 10.4% (mean+/-SD) in a dose-dependent manner by remifentanil infusion. The dose producing a 50% reduction in the enflurane MAC was calculated as 0.72 micro gram *symbol* kg sup -1 *symbol* min sup -1 and the corresponding blood concentration was calculated as 9.2 ng/ml. Enflurane MAC reduction remained stable during continuous, constant rate infusions for periods of 6-8 h without any signs of tolerance. Recovery of enflurane MAC to baseline occurred in 30 min (earliest measurement) after stopping the remifentanil infusion.     

Repeated Doses of Rocuronium Bromide Administered to Cirrhotic and Control Patients Receiving Isoflurane: A Clinical and Pharmacokinetic Study

Background: Steroid muscle relaxants often display pharmacodynamic changes in patients with cirrhosis because of alterations in elimination processes. Rocuronium is a new steroid muscle relaxant possibly eliminated through the liver. This study was designed to compare rocuronium pharmacodynamics and pharmacokinetics in cirrhotic and healthy patients.

Methods: Rocuronium was administered to 26 cirrhotic patients and 24 control subjects anesthetized with isoflurane for an elective procedure. Patients were randomly allocated to receive an initial dose of rocuronium: 120, 180, 250, or 300 micro gram *symbol* kg sup -1. Dose-response curves were established, and ED50 was calculated. Preselected maintenance doses (75, 150, or 225 micro gram *symbol* kg sup -1) were administered at 25% recovery of twitch height to compare clinical duration of action. At the end of the procedure, relaxation was reversed in half of the patients, and the time course of recovery was compared in the two groups. Blood samples drawn during the procedure and after the last maintenance dose allowed pharmacokinetic analysis in six cirrhotic patients and six control subjects.

Results: ED50 of the initial dose was 144 micro gram *symbol* kg sup -1 in cirrhotic patients and 60 micro gram *symbol* kg sup -1 in control subjects, related to a higher initial volume of distribution (cirrhotic 78.5+/-31.7 ml *symbol* kg sup -1, control 29.8 +/-17.3 ml *symbol* kg sup -1). Time from complementary dose to 25% recovery was longer in cirrhotic patients (41.0+/-20.7 min vs. 30.2+/-9.7 min), but time course of action during maintenance was not statistically different in the two groups. In cirrhotic patients receiving five maintenance doses or more, prolongation of the duration of action with successive maintenance doses could be statistically demonstrated. Spontaneous recovery was delayed in cirrhotic patients, because of impaired elimination processes: greater volume of distribution at steady-state (264+/-92 vs. 151+/-59 ml *symbol* kg sup -1); trend toward a lower clearance (189+/-60 vs. 296 +/-169 ml *symbol* min sup -1).     

The Relation between Cerebral Metabolic Rate and Ischemic Depolarization: A Comparison of the Effects of Hypothermia, Pentobarbital, and Isoflurane

Background: Reductions in cerebral metabolic rate may increase the brain's tolerance of ischemia. However, outcome studies suggest that reductions in cerebral metabolic rate produced by anesthetics and by hypothermia may not be equally efficacious. To examine this question, we measured the effects of hypothermia, pentobarbital, and isoflurane on the cerebral metabolic rate for glucose (CMRG) and on the time to the loss of normal membrane ion gradients (terminal ischemic depolarization) of the cortex during complete global ischemia.

Methods: As pericranial temperature was varied between 39 and 25 degrees Celsius in normocapnic halothane-anesthetized rats, CMRG (using14 Carbon-deoxyglucose) or the time to depolarization (using a glass microelectrode in the cortex) after a Potassium sup + -induced cardiac arrest was measured. In other studies, CMRG and depolarization times were measured in normothermic animals (37.7 plus/minus 0.2 degree Celsius) anesthetized with high-dose pentobarbital or isoflurane (both producing burst suppression on the electroencephalogram) or in halothane-anesthetized animals whose temperatures were reduced to 27.4 plus/minus 0.3 degree Celsius. These three states were designed to produce equivalent CMRG values.

Results: As temperature was reduced from 39 to 25 degrees Celsius, CMRG decreased from 66 to 21 micro Meter *symbol* 100 g sup -1 *symbol* min1 (Q10 = 2.30), and depolarization times increased from 76 to 326 s. In similarly anesthetized animals at approximately 27 degrees Celsius, CMRG was 32 plus/minus 4 micro Meter *symbol* 100 g sup -1 *symbol* min sup -1 (mean plus/minus SD), whereas in normothermic pentobarbital- and isoflurane-anesthetized rats, CMRG values were 33 plus/minus 3 and 37 plus/minus 4 micro Meter *symbol* 100 g1 *symbol* min sup -1, respectively (P = 0.072 by one-way analysis of variance). Despite these similar metabolic rates, the times to depolarization were markedly different: for hypothermia it was 253 plus/minus 29 s, for pentobarbital 109 plus/minus 24 s, and for isoflurane 130 plus/minus 28 s (P < 0.0001).     

Effect of 7.2% Hypertonic Saline/6% Hetastarch on Left Ventricular Contractility in Anesthetized Humans

Background: Although a positive inotropic effect of hypertonic saline has been demonstrated in isolated cardiac tissue as well as in animal preparations, no information exists about a possible positive inotropic action of hypertonic saline in humans. The aim of this investigation was to determine whether a clinically relevant positive inotropic effect can be demonstrated in humans.

Methods: Twenty-six patients without cardiovascular disease were randomized to receive 4 ml/kg of either 7.2% hypertonic saline/6% hetastarch or 6% hetastarch (control) at a rate of 1 ml *symbol* kg sup -1 *symbol* min sup -1 while under general endotracheal anesthesia. Transesophageal echocardiography was used to evaluate left ventricular function. Arterial pressure, heart rate, and left ventricular end-systolic and end-diastolic diameter, area, and wall thickness were measured immediately before and after administration of either solution. Fractional area change, end-systolic wall stress, and the area under the end-systolic pressure-length relationship curve (ESPLRarea) were calculated. ESPLRarea was used to assess left ventricular contractility.

Results: Administration of hypertonic saline/hetastarch resulted in a significant decrease of mean arterial pressure and end-systolic wall stress from 77 plus/minus 14 (mean plus/minus SD) to 64 plus/minus 17 mmHg (P < 0.01) and from 52 plus/minus 14 to 32 plus/minus 11 103 dyne/cm2 (P > 0.01), respectively. End-diastolic area and fractional area change increased from 16.5 plus/minus 2.9 to 21.7 plus/minus 3.3 cm2 (P < 0.01) and from 0.53 plus/minus 0.07 to 0.70 plus/minus 0.06 (P < 0.01), respectively, whereas there was only a minor change of ESPLRarea from 38 plus/minus 13 to 44 plus/minus 13 mmHg.cm (P < 0.05).     

Pharmacokinetics of Rocuronium in Children Aged 4-11 Years

Background: Rocuronium is a new nondepolarizing muscle relaxant with a rapid onset and intermediate duration of action. Although the pharmacokinetics of rocuronium have been determined in adults and the elderly, similar data are lacking in children. Accordingly, rocuronium's pharmacokinetics were determined in children aged 4-11 yr.

Methods: Rocuronium (600 micro gram/kg) was administered to 20 children aged 4-11 yr anesthetized with nitrous oxide and less or equal to 1% halothane, and four plasma samples were obtained over 4 h to determine rocuronium concentrations. The pharmacokinetics of rocuronium were determined using two sparse-sampling population approaches, mixed- effects modeling, and naive pooled data analysis.

Results: With mixed-effects modeling, weight-normalized plasma clearance varied with weight (P < 0.01), being 79.4 ml *symbol* min sup -1 + 3.13 ml *symbol* kg sup -1 *symbol* min sup -1. Neither weight- normalized distributional clearance (2.67 ml *symbol* kg sup -1 *symbol* min sup -1), weight-normalized central compartment volume (106 ml/kg), nor weight-normalized volume of distribution at steady-state (224 ml/kg) varied with weight, height, or age. Similar results were obtained with the naive pooled data approach.     

The paradoxical positive inotropic effect of sevoflurane in healthy and cardiomyopathic hamsters

We investigated the effects of sevoflurane (0.7 to 3.6 vol%) on inotropy and lusitropy in left ventricular papillary muscles of healthy hamsters and genetically induced cardiomyopathic (strain BIO 14.6) hamsters in vitro (29 degrees C, pH 7.40, Ca(2+) 2.5 mM, stimulation frequency three per minute) under low (isotony) and high (isometry) loads. Sevoflurane induced a moderate positive inotropic effect in healthy hamsters (maximum unloaded shortening velocity and isometric active force at 3.6 vol%: 115% +/- 12% and 128% +/- 21% of baseline values, respectively; P < 0.01) and in cardiomyopathic hamsters (maximum unloaded shortening velocity and isometric active force at 3.6 vol%: 115% +/- 20% and 124% +/- 31% of baseline values, respectively; P < 0.05). This positive inotropic effect did not differ between healthy and cardiomyopathic hamsters, even when sevoflurane concentrations were corrected for minimum alveolar anesthetic concentration values in each strain, and was unchanged after alpha- and beta-adrenoceptor blockade. After calcium-channel blockade, this positive inotropic effect was abolished in healthy hamsters but enhanced in cardiomyopathic hamsters. In both strains, sevoflurane induced a moderate negative lusitropic effect under low and high loads. IMPLICATIONS: A paradoxical moderate positive inotropic effect of sevoflurane was observed in hamster ventricular muscle. This effect was likely related to calcium channel interaction, because after calcium-channel blockade, it was abolished in healthy hamsters and enhanced in cardiomyopathic hamsters.     

Effects of Propofol or Isoflurane Anesthesia on Cardiac Conduction in Children Undergoing Radiofrequency Catheter Ablation for Tachydysrhythmias

Background: To determine suitability for ablation procedures in children, two commonly used anesthetic agents were studied: propofol and isoflurane.

Methods: Twenty patients presenting for a radiofrequency catheter ablation procedure were included and randomly assigned to two groups. A baseline electrophysiology study was performed during anesthesia with thiopental, alfentanil, nitrous oxide, and pancuronium in all patients. At the completion of the baseline electrophysiology study (EPS), 0.8-1.2% isoflurane was administered to patients in group 1 and 2 mg/kg propofol bolus plus an infusion of 150 micro gram *symbol* kg sup -1 *symbol* min sup -1 was administered to patients in group 2. Nitrous oxide and pancuronium were used throughout the procedure. After 30 min of equilibration, both groups underwent a repeat EPS. The following parameters were measured during the EPS: cycle length, atrial-His interval, His-ventricle interval, corrected sinus node recovery time, AV node effective refractory period, and atrial effective refractory period. Using paired t tests, the electrophysiologic parameters described above measured during propofol or isoflurane anesthesia were compared to those measured during baseline anesthesia. Statistical significance was accepted as P < 0.05.

Results: There was no statistically significant difference in the results obtained during baseline anesthesia when compared with those measured during propofol or isoflurane anesthesia.     

Anesthetics Affect the Uptake but Not the Depolarization-evoked Release of GABA in Rat Striatal Synaptosomes

Background: Numerous classes of anesthetic agents have been shown to enhance the effects mediated by the postsynaptic gamma-aminobutyric acid A (GABAA) receptor-coupled chloride channel in the mammalian central nervous system. However, presynaptic actions of anesthetics potentially relevant to clinical anesthesia remain to be clarified. Therefore, in this study, the effects of intravenous and volatile anesthetics on both the uptake and the depolarization-evoked release of GABA in the rat stratum were investigated.

Methods: Assay for specific GABA uptake was performed by measuring the radioactivity incorporated in purified striatal synaptosomes incubated with3 H-GABA (20 nM, 5 min, 37 degrees Celsius) and increasing concentrations of anesthetics in either the presence or the absence of nipecotic acid (1 mM, a specific GABA uptake inhibitor). Assay for GABA release consisted of superfusing3 H-GABA preloaded synaptosomes with artificial cerebrospinal fluid (0.5 ml *symbol* min sup 1, 37 degrees Celsius) and measuring the radioactivity obtained from 0.5 ml fractions over 18 min, first in the absence of any treatment (spontaneous release, 8 min), then in the presence of either KCl alone (9 mM, 15 mM) or with various concentrations of anesthetics (5 min), and finally, with no pharmacologic stimulation (5 min). The following anesthetic agents were tested: propofol, etomidate, thiopental, ketamine, halothane, enflurane, isoflurane, and clonidine.

Results: More than 95% of3 H-GABA uptake was blocked by a 10 sup 3 -M concentration of nipecotic acid. Propofol, etomidate, thiopental, and ketamine induced a dose-related, reversible, noncompetitive, inhibition of3 H-GABA uptake: IC50 = 4.6 plus/minus 0.3 x 105 M, 5.8 plus/minus 0.3 x 10 sup -5 M, 2.1 plus/minus 0.4 x 10 sup -3 M, and 4.9 plus/minus 0.5 x 10 sup -4 M for propofol, etomidate, thiopental, and ketamine, respectively. Volatile agents and clonidine had no significant effect, even when used at concentrations greater than those used clinically. KCl application induced a significant, calcium-dependent, concentration-related, increase from basal3 H-GABA release, +34 + 10% (P < 0.01) and +61 plus/minus 13% (P < 0.001), respectively, for 9 mM and 15 mM KCl. The release of3 H-GABA elicited by KCl was not affected by any of the anesthetic agents tested.