Response of the heart to acute hypertension during halothane, enflurane, and isoflurane anesthesia

In the open chest dog model, the response of the left ventricle exposed to acute mechanical hypertension was evaluated while the animals were receiving various concentrations of halothane, enflurane, and isoflurane. Myocardial contractility was quantified by the end-systolic pressure-length relation (ESPL). When the mean aortic pressure was increased by 40% above the control value for a given concentration of inhalation agent, the end-diastolic volume increased and thereby maintained stroke work. However, as the end-tidal concentrations of the anesthetics increased, this compensatory mechanism became progressively more ineffective as a result of myocardial depression caused by the anesthetics. No evidence could be found of an improvement in myocardial contractility as the aortic pressure was increased. Mild depression of myocardial contractility could be demonstrated for 1.1 MAC halothane, 0.6 MAC enflurane, and 1.0 MAC isoflurane. Severe depression of contractility occurred at 2.3 MAC halothane, 1.2 MAC enflurane, and 1.5 MAC isoflurane.     

Effects of inhalational anesthetics on verapamil pharmacokinetics in dogs

Six dogs were chronically instrumented in order to collect aortic blood samples and record mean arterial pressure, cardiac output and heart rate. Each animal received verapamil 200 micrograms X kg-1 by 10-min intravenous infusions on four occasions in random sequence: awake, and during halothane 1.2%, enflurane 2.5%, and isoflurane 1.6% anesthesia. Rate of initial distribution of verapamil was reduced during anesthetic exposure. Verapamil intercompartmental clearance from the central compartment to the peripheral compartment was decreased during exposure to halothane and isoflurane, and tended to decrease during enflurane exposure as well. Verapamil terminal volume of distribution at steady-state was reduced by halothane, enflurane, and isoflurane exposure as compared with awake: 65 +/- 10, 80 +/- 9, and 93 +/- 191, respectively, versus 132 +/- 121 (mean +/- SEM; P less than 0.05). Verapamil total clearance was also reduced by halothane, enflurane, and isoflurane as compared with awake: 37 +/- 4, 39 +/- 2 and 41 +/- 31 X h-1, respectively, versus 64 +/- 71 X h-1 (P less than 0.05). Verapamil administered to awake animals resulted in a decrease from baseline in mean arterial pressure; 95 +/- 8 mmHg versus 108 +/- 4 mmHg (P less than 0.05): and an increase in cardiac output; 2.60 +/- 0.33 1 X min-1 versus 1.93 +/- 0.22 1 X min-1 (P less than 0.05). During halothane, enflurane, and isoflurane anesthesia, verapamil administration resulted in a similar decrease in mean arterial pressure; however cardiac output decreased, in contrast to the increase noted in awake animals.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of halothane, enflurane, and isoflurane on coronary blood flow autoregulation and coronary vascular reserve in the canine heart

To investigate the effects of volatile anesthetics on coronary blood flow (CBF) autoregulation and coronary vascular reserve, studies were performed on chronically instrumented dogs, awake and during the administration of 1.0 MAC halothane, enflurane, and isoflurane. Coronary pressure-flow plots were generated by measuring left anterior descending coronary artery blood flow while varying coronary inflow pressure with a hydraulic occluder. Autoregulation was quantitated by two measures: the slope of the horizontal "autoregulated" portion of the pressure-flow relationship and the autoregulation index (ArI) of Norris. Slope values (ml.min-1.mmHg-1 +/- SD) were: awake, 0.243 +/- 0.043; halothane, 0.414 +/- 0.044; enflurane, 0.587 +/- 0.187; and isoflurane, 0.795 +/- 0.246. The increase in slope was statistically significant only for halothane and isoflurane (P less than .05). The ArI approaches 1.0 when autoregulation is perfect, and approaches zero or is a negative number when autoregulation is absent. The authors found ArI values of: awake, 0.55; halothane, -0.08; enflurane, -0.01; isoflurane, -0.02. These values indicate good autoregulation while awake, but impaired autoregulation with all three anesthetics (P less than .05). Coronary vascular reserve was calculated, at a diastolic coronary pressure of 40 mmHg, as the difference between resting flow and flow during maximal coronary vasodilation induced by intracoronary adenosine. Coronary vascular reserve, maximal coronary conductance, and coronary zero-flow pressure were not significantly altered by these anesthetics. The authors conclude that 1.0 MAC enflurane, halothane, and isoflurane mildly disrupt CBF autoregulation, increasing CBF out of proportion to myocardial demands. Under the conditions of this study, these anesthetics do not affect maximal CBF or coronary vascular reserve.     

Comparative echocardiographic studies on the negative inotropic effect of halothane, enflurane and isoflurane

Using the afterload-independent end-systolic pressure-dimension-relationship a study was performed in order to investigate whether there are differences in the negative inotropic effects of halothane, enflurane and isoflurane at 1 MAC in 70% N2O. 30 patients of ASA-groups I and II were studied. Using transoesophageal 2d- and m-mode echocardiography the end-systolic-pressure-dimension-relationship was established and the slope (parameter of contractility) determined. The slope decreased significantly (paired Wilcoxon-test 2 alpha less than 0.01) with halothane (68.5/46.5 mmHg/cm), enflurane (56/48 mm Hg/cm) and isoflurane (63/35 mmHg/cm). There is no difference between the three groups (Kruskal-Wallis-test 2 alpha greater than 0.05). The negative inotropic effects of halothane, enflurane and isoflurane at 1 MAC in 70% N2O are the same. The vasodilation caused by isoflurane enables better pump function compared to halothane and enflurane, but may cause severe hypotension. We conclude that for cardiac risk patients isoflurane has no outstanding advantages in comparison to halothane and enflurane.     

Halothane, enflurane and isoflurane anaesthesia for adenoidectomy in children, using two different premedications

In 48 children subjected to adenoidectomy, comparisons of airway problems, heart rates, cardiac arrhythmias, ventilation and stress hormone reactions were studied during halothane, enflurane and isoflurane anaesthesia. Sixteen children were anaesthetized with either of the three agents and eight patients in each group received diazepam 0.25 mg kg-1 and atropine 0.015 mg kg-1 rectally (DA) as premedication and the remainder diazepam 0.5 mg kg-1, morphine 0.15 mg kg-1 and scopolamine 0.01 mg kg-1 (DMS) rectally. All children were intubated and breathing spontaneously. Equianaesthetic inspired concentrations of halothane, enflurane and isoflurane were used. Airway problems were of the same magnitude during halothane and isoflurane anaesthesia but were less frequent with both agents compared with enflurane anaesthesia. DMS reduced the number of airway reactions in all groups. Respiratory rates were uninfluenced by anaesthesia, intubation and surgery during enflurane anaesthesia. Cardiac arrhythmias were less frequent with enflurane and isoflurane than with halothane. Plasma ACTH and cortisol were similar with all three agents. During induction of anaesthesia in the DA-premedicated halothane group, however, plasma catecholamines were higher than in the group which received DMS, in contrast to the findings during enflurane and isoflurane anaesthesia. The DMS premedication decreased the response of plasma ACTH, cortisol and plasma catecholamines to surgery.     

The effect of halothane, enflurane and isoflurane on the circulation

This study, in open-chested dogs, sought to explore the relationship between whole-body oxygen delivery and oxygen consumption during anaesthesia, using increasing concentrations of halothane, enflurane and isoflurane. Results indicate that the cardiac index and oxygen delivery became critical at less than 1 MAC (minimal alveolar concentration of anaesthetic) for the three commonly used vapours. Halothane caused the least depression of contractility, but the stroke volume was reduced by the well-maintained afterload at 1 MAC. Enflurane and isoflurane were associated with more depression of contractility, but the cardiac output was maintained by an increase in heart rate in the case of isoflurane and reduced mean arterial pressure during the use of enflurane.     

Comparison of the systemic and coronary hemodynamic actions of desflurane, isoflurane, halothane, and enflurane in the chronically instrumented dog

The systemic and coronary hemodynamic effects of desflurane were compared to those of isoflurane, halothane, and enflurane in chronically instrumented dogs. Since autonomic nervous system function may significantly influence the hemodynamic actions of anesthetics in vivo, a series of experiments also was performed in the presence of pharmacologic blockade of the autonomic nervous system. Eight groups comprising a total of 80 experiments were performed on 10 dogs instrumented for measurement of aortic and left ventricular pressure, the peak rate of increase of left ventricular pressure (dP/dt), subendocardial segment length, coronary blood flow velocity, and cardiac output. Systemic and coronary hemodynamics were recorded in the conscious state and after 30 min equilibration at 1.25 and 1.75 MAC desflurane, isoflurane, halothane, and enflurane. Desflurane (+79 +/- 12% change from control) produced greater increases in heart rate than did halothane (+44 +/- 12% change from control) or enflurane (+44 +/- 9% change from control) at 1.75 MAC. Desflurane preserved mean arterial pressure to a greater degree than did equianesthetic concentrations of isoflurane. This result was attributed to a smaller effect on peripheral vascular resistance as compared to isoflurane and greater preservation of myocardial contractility as evaluated by peak positive left ventricular dP/dt and the rate of increase of ventricular pressure at 50 mmHg (dP/dt50) compared to other volatile anesthetics. Increases in diastolic coronary blood flow velocity (+19 +/- 6 and +35 +/- 12% change from control at 1.75 MAC, respectively) and concomitant decreases in diastolic coronary vascular resistance (-41 +/- 12 and -58 +/- 6% change from control at 1.75 MAC, respectively) were produced by desflurane and isoflurane. In the presence of autonomic nervous system blockade, the actions of desflurane and isoflurane were nearly identical with the exception of coronary vasodilation. After autonomic nervous system blockade, isoflurane increased coronary blood flow velocity, but desflurane did not. Furthermore, both desflurane and isoflurane continued to produce less depression of myocardial contractility than did halothane and enflurane. In summary, at equianesthetic concentrations, desflurane and isoflurane produced similar hemodynamic effects; however, in the absence of drugs that inhibit autonomic reflexes, desflurane had less negative inotropic activity and produced less decrease in arterial pressure. The coronary vasodilator actions of desflurane and isoflurane within the limitations of this model were not similar. When the increase in heart rate and rate-pressure product produced by desflurane were prevented in dogs with autonomic nervous system blockade, desflurane produced no change in coronary blood flow velocity.     

The divergent actions of volatile anaesthetics on background neuronal activity and reactive capability in the central nervous system in cats

The effects of halothane, isoflurane, and enflurane on background neuronal activity and reactive capability in the central nervous system were studied in cats. The background neuronal activity was assessed by midbrain reticular cell firing, which was measured by the method of multi-unit activity, and the EEG in the cortex, amygdala, and hippocampus. The reactive capability was assessed by evoked responses in the visual neuronal pathway. All anaesthetics studied suppressed reticular cell firing in a dose-dependent manner, and the suppression by halothane (43.8 +/- 10.3% of control, mean +/- SD) was less than isoflurane (66.5 +/- 5.8%, P < 0.01) and enflurane (73.1 +/- 8.8%, P < 0.05) at 1 MAC. Spontaneous EEG spikes developed at 4.8% isoflurane and 3.6% enflurane anaesthesia. Phasic activation of reticular cell firing was associated with EEG spikes during isoflurane and enflurane anaesthesia, and the activation during enflurane anaesthesia was greater than during isoflurane anaesthesia (P < 0.01). Photic stimulation provoked EEG spikes and repetitive stimulation induced seizure activity only at 3.6% enflurane anaesthesia. Halothane and isoflurane suppressed stimulation induced responses in the visual neuronal pathway. The amplitudes of N1 in visual cortical evoked responses induced by photic stimulation were suppressed to 70.1 +/- 24.5% of control at 2.4% halothane and 39.3 +/- 27.3% at 4.8% isoflurane. Enflurane, at 3.6%, augmented the evoked response induced by photic stimulation (398.4 +/- 83.0% of control in the amplitude of N1). These results indicate that all the agents studied had suppressive actions on background neuronal activity in the order halothane < isoflurane = enflurane. The effects on reactive capability were divergent among agents, e.g., enflurane enhanced, halothane suppressed, and the actions of isoflurane were intermediate. We conclude that the anaesthetic effects on background activity and on reactive capability are divergent and that suppression of reactive capability is a factor in determining the ease of clinical application of the anaesthetics.     

Cerebrovascular responses to carbon dioxide in children anaesthetized with halothane and isoflurane

To determine the effects of isoflurane and halothane on cerebrovascular reactivity to CO2, 30 children aged one to six years were anaesthetized with isoflurane or halothane in an air and oxygen mixture with an FIO2 of 0.3. The end-tidal concentrations (0.5 minimum alveolar concentration (MAC) or 1.0 MAC) of isoflurane or halothane were age-adjusted. After achieving a steady-state at both 0.5 MAC and 1.0 MAC isoflurane and halothane, the end-tidal carbon dioxide tension (PETCO2) was randomly adjusted to 20, 40, or 60 mmHg. Cerebral blood flow velocity (CBFV) and the cerebrovascular resistance index (RI+) in the middle cerebral artery (MCA) were measured by a transcranial Doppler monitor. Three measurements of CBFV and RI+ were obtained at each PETCO2 and isoflurane or halothane concentration. Any rise in the PETCO2 caused an increase in CBFV during both 0.5 MAC (r2 = 0.99 and 0.99) and 1.0 MAC (r2 = 0.96 and 0.95) isoflurane and halothane anaesthesia, respectively (P less than 0.05). The CBFV for isoflurane increased as PETCO2 increased from 20 to 60 mmHg for both 0.5 MAC and 1.0 MAC (P less than 0.05). The CBFV for halothane increased as PETCO2 increased from 20 to 40 mmHg for both 0.5 MAC and 1.0 MAC halothane (P less than 0.05), but did not change as PETCO2 increased from 40 to 60 mmHg for both 0.5 MAC and 1.0 MAC halothane. The RI+ showed an inverse relationship with CBFV at each PETCO2 for 0.5 MAC (r2 = 0.98 and 0.99) and 1.0 MAC (r2 = 0.76 and 0.53) isoflurane and halothane, respectively (P less than 0.05). The CBFV did not differ significantly between 0.5 and 1.0 MAC isoflurane and halothane at corresponding PETCO2 values. The cerebrovascular response to CO2 at 20 mmHg between 0.5 MAC and 1.0 MAC halothane was not significantly different. These data strongly suggest that isoflurane and halothane in doses up to 1.0 MAC do not affect the cerebrovascular reactivity of the MCA to CO2 in anaesthetized, healthy children.     

Comparison of metaproterenol, isoetharine and salbutamol in the relief of methacholine-induced bronchospasm in dogs

We evaluated cardiovascular effects and effectiveness of isoetharine, metaproterenol and salbutamol, when administered intratracheally to relieve methacholine-induced bronchospasm in dogs anaesthetized with 50 per cent nitrous oxide, oxygen, halothane and mechanically ventilated. Methacholine 2 micrograms X kg-1 X hour-1 was administrated first followed by halothane (1 MAC) for 30 minutes (control), then metaproterenol, isoetharine or salbutamol. Metaproterenol (15 mg) significantly decreased transpulmonary pressure to 20.1 +/- 0.5 (SE) from 22.5 +/- 1.15 cmH2O (p less than 0.025) after three min and to 15 +/- 0.5 cmH2O (p less than 0.005) after 90 min. Isoetharine (2.5 mg) decreased transpulmonary pressure after five min to 22.1 +/- 1 from 24.5 +/- 1.5 cmH2O (p less than 0.05), and to 21.75 +/- 0.55 mmH2O after 90 min. Salbutamol 25 micrograms X kg-1 decreased transpulmonary pressure to 20.7 +/- 0.75 from 24.25 +/- 1.28 after three min and to 16 +/- .5 after 90 min. The peak effects on airway pressure occurred at 15 min for metaproterenol, 25 min for salbutamol and 20 min for isoetharine. Pulmonary vascular resistance was not significantly changed during halothane anaesthesia alone but decreased significantly after metaproterenol and isoetharine infusion. Heart rate increased ten per cent after metaproterenol, three per cent after isoetharine, and five per cent after salbutamol. No arrhythmias occurred in any group. Cardiac output increased significantly to 3.25 +/- 0.2 from 1.5 +/- 0.17 L X min-1 (p less than 0.025) after metaproterenol to 3.2 +/- .025 from 1.45 +/- .009 after salbutamol and was unchanged after isoetharine. Metaproterenol and salbutamol in the presence of 1 MAC halothane anaesthesia relieved methacholine-induced bronchospasm more rapidly than did isoetharine. The onset of effect was 3 +/- 0.05 min for metaproterenol and salbutamol and 5 +/- 0.01 min for isoetharine. The effect lasted 210 +/- 10.5 min for metaproterenol, 170 +/- 12.5 min for salbutamol and 90 +/- 4.75 min for isoetharine.     

Comparison of the effects of volatile anesthetics on brain glucose metabolism in rats

The objective of this investigation was to compare the effects of the commonly used volatile anesthetics on concentrations of plasma and cerebral glucose and cerebral intermediary metabolites. Fasted male Long-Evans rats were anesthetized with a volatile anesthetic and, after tracheostomy and paralysis, were mechanically ventilated. Each of three groups received one MAC concentration of anesthesia with halothane, enflurane, or isoflurane. At the end of 60-75 min of anesthesia, blood was sampled for arterial blood gas and plasma glucose analysis, and the brain was rapidly sampled and frozen for analysis of energy metabolites. Physiologic variables were maintained as follows: PaCO2 30-40 mmHg, pHa 7.20-7.40, PaO2 greater than 60 mmHg, MAP greater than 60 mmHg, and rectal temperature 37.5-38.5 degrees C. Mean plasma glucose concentrations in the three groups were as follows (muMol/ml +/- SEM): halothane, 7.45 /- .62; enflurane, 6.95 +/- .22; isoflurane, 10.11 +/- 1.00. Mean brain glucose concentrations in the three groups were (muMol/gm wet weight): halothane, 2.04 +/- .20; enflurane, 2.07 +/- .26; isoflurane, 3.04 +/- .31. Plasma and brain glucose levels were significantly increased in the isoflurane group compared to the other two groups (P less than .05) with no differences occurring in the brain/plasma glucose ratio among the three groups. No differences were present between groups in brain lactate, pyruvate, fructose diphosphate, malate, alpha-ketoglutarate, phosphocreatine, or adenine nucleotides. Thus, at one MAC concentration, major differences between volatile anesthetics on brain energy availability are not present, although isoflurane raised cerebral glucose levels.     

Comparative effects of halothane, enflurane, and isoflurane at equipotent anesthetic concentrations on isolated ventricular myocardium of the ferret. I. Contractility

The effects of halothane, enflurane, and isoflurane on myocardial contractility were compared in papillary muscles of the right ventricle of adult male ferrets at 30 degrees C. Isotonic and isometric variables of contractility were measured before, during, and after exposure to incremental concentrations of halothane (n = 9 muscles), enflurane (n = 9 muscles), and isoflurane (n = 9 muscles), in steps of 0.25 MAC up to 1.5 MAC of halothane and of enflurane, and up to 2.0 MAC of isoflurane. Each of the three anesthetics caused a dose-dependent reversible decrease in contractility. The onset of maximal myofibrillar activation was delayed in a dose-dependent manner, and time to peak shortening of the isotonic preloaded twitch was unchanged, except for a slight decrease at greater than 1 MAC of enflurane. Isoflurane's negative inotropic effects were clearly less than those of either halothane or enflurane. Comparison of the time course of contraction and relaxation in both isometric and isotonic twitches suggests that, in addition to effects on intracellular calcium availability, these anesthetics decrease the myofibrillar responsiveness to calcium and/or the calcium sensitivity of the contractile proteins.     

Comparison of the effects of succinylcholine and atracurium on intracranial pressure in monkeys with intracranial hypertension

The effects of succinylcholine (1.5 mg X kg-1 IV) administered five minutes after a defasciculating dose of curare (0.05 mg X kg-1 IV), were compared with the effects of atracurium (0.5 mg X kg-1 IV) on intracranial pressure (ICP) in 13 cynomolgus monkeys with intracranial hypertension (ICP approximately 25 mmHg). Neither succinylcholine nor atracurium increased ICP during general anaesthesia with 60 per cent N2O/O2, 0.5-1 per cent halothane. During a rapid sequence induction and intubation with thiopentone 5 mg X kg-1 IV, ICP increased equally with intubation following both atracurium (25 +/- 1 to 32 +/- 2 mmHg) and succinylcholine (25 +/- 1 to 31 +/- 2 mmHg) (p less than 0.05). Intubation was also associated with significant increases in PaCO2, CVP and MAP. We conclude that in this primate model of intracranial hypertension, neither atracurium nor succinylcholine (when given following a defasciculating dose of curare) elevates ICP. In terms of the elevation of ICP associated with intubation, atracurium was found to offer no advantage over succinylcholine.     

MAC-AWAKE OF ISOFLURANE, ENFLURANE AND HALOTHANE EVALUATED BY SLOW AND FAST ALVEOLAR WASHOUT

End-tidal anaesthetic concentrations at first eye opening inresponse to a verbal command during recovery from anaesthesia(MAC-awake), were measured for isoflurane (n = 16), enflurane(n = 16) and halothane (n = 14). MAC-awake was measured duringeither slow or fast alveolar washout. Slow washout was obtainedby decreasing anaesthetic concentrations in predetermined stepsof 15min, assuming equilibration between brain and alveolarpartial pressures. Fast alveolar washout was obtained by discontinuationof the inhalation anaesthetic, which had been maintained at1 MAC for at least 15 min. Mean MAC-awake obtained with slowalveolar washout was similar for isoflurane (0.25 (SD 0.03)MAC), and enflurane (0.27 (0.04) MAC) and significantly greaterthan values obtained by fast alveolar washout (isoflurane: 0.19(0.03) MAC; enflurane: 0.20 (0.03) MAC). The MAC-awake of isofluraneand enflurane was significantly less than that of halothane,which was 0.59 (0.10) MAC as evaluated by the slow and 0.50(0.05) MAC as evaluated by the fast alveolar washout method.Recovery time from anaesthesia with fast alveolar washout was8.8 (4.0) min for halothane, which was not different from isoflurane(15 (2.5) min), but significantly shorter than for enflurane(22 (10) min), reflecting differences in the anaesthetic concentrationgradient between MAC and MAC-awake values. These data do notsupport the hypothesis of a uniform ratio between MAC and MAC-awakevalues.     

Thiopental and epinephrine-induced dysrhythmias in dogs anesthetized with enflurane or isoflurane

Epinephrine-induced dysrhythmias were studied in 19 dogs anesthetized with 1.25 MAC enflurane or isoflurane, or the same preceded by thiopental (20 mg/kg). In 11 (group 1) dogs, thiopental reduced the dose of epinephrine required for production of ventricular ectopy, bigeminy and tachycardia with enflurane, and only ventricular tachycardia with isoflurane (P less than 0.05). Thiopental potentiation of epinephrine-induced dysrhythmias with enflurane lasted 4 hr after induction. In eight (group 2) dogs, the arrhythmic dose (ADE in microgram/ml) and plasma level of epinephrine (PLE in ng/ml) for four or more ventricular extrasystoles in 15 sec were determined in the same animal under each of the four test conditions. ADE and PLE values (X +/- SEM) were, respectively, enflurane, 9.1 +/- 1.0 and 141 +/- 24 (8/8 dogs); enflurane-thiopental, 5.0 +/- 0.6 and 63 +/- 16 (8/8 dogs); isoflurane, 28.3 and 330 (1/7 dogs); and isoflurane-thiopental, 15.2 +/- 2.8 and 265 +/- 59 (5/7 dogs). In addition, thiopental had no effect on plasma epinephrine levels reached during epinephrine infusions with 1.0 (enflurane only), 2.0 (enflurane, isoflurane) and 4.0 micrograms X kg-1 X min-1 (isoflurane only). Nor were epinephrine levels reached during enflurane or enflurane-thiopental different from those reached during isoflurane or isoflurane-thiopental. It is concluded that thiopental potentiates several types of epinephrine-induced ventricular dysrhythmias with enflurane, but only ventricular tachycardia with isoflurane. Furthermore, isoflurane or isoflurane-thiopental were less sensitizing than enflurane or enflurane-thiopental. Finally, neither thiopental nor the anesthetic agents affected plasma epinephrine levels reached during epinephrine infusions lasting 3 min.     

Attenuation of contraction of isolated canine coronary arteries by enflurane and halothane

Contraction of vascular smooth muscle such as that existing in coronary arteries is regulated in part by Ca++ entry into cells via Ca++ channels. Volatile anaesthetics are known to attenuate agonist-induced coronary artery constriction. The purpose of this experiment was to determine if 1.5 MAC concentrations of halothane or enflurane attenuated contractions evoked by activation of one type of Ca++ channel--the potential operator channel. In the current experiment, potential operator channels were activated by depolarizing isolated canine coronary artery rings with high concentration of K+, causing Ca++ entry and vessel contraction. Rings without endothelium were suspended for isometric force measurement in organ chambers containing aerated Krebs-Ringer solution. Maximum response to Ca++ in rings depolarized with K+ was 120 +/- 5 per cent in untreated versus 101 +/- 3 per cent in rings treated with enflurane (P less than 0.01). The maximum response was 123 +/- 6 per cent in untreated versus 111 +/- 5 per cent during halothane administration (P less than 0.05). In contrast, nifedipine 10(-9) M depressed maximum contractions from 114 +/- 5 per cent to 37 +/- 4 per cent (P less than 0.01) and nifedipine 10(-8) M depressed contractions to 30 +/- 4 per cent (P less than 0.01). In a further series of experiments, sustained contractions were depressed by continued administration of the anaesthetics, indicating no loss of anaesthetic effect with time. The results indicate that 1.5 MAC halothane and enflurane attenuate contractions of canine coronary arteries evoked by depolarization and Ca++ entry through potential operated channels. However, neither halothane nor enflurane exhibited the marked depressant effect exerted by nifedipine.     

The effect of halothane, isoflurane, or sufentanil on the hypertensive response to cerebellar retraction during posterior fossa surgery

The blood pressure (BP) response to cerebellar retraction during microvascular decompression of the fifth cranial nerve was investigated in 26 ASA physical status 2 or 3 patients with trigeminal neuralgia. One surgeon performed all operations. To determine the effect of three anesthetic techniques on the BP response, patients were randomly assigned to receive halothane, isoflurane, or sufentanil in sufficient doses with 60% nitrous oxide to achieve a precerebellar retraction systolic BP that was 10-20% below the average ward systolic BP (as per standard clinical practice). The resultant doses were halothane 1.65 +/- 0.27 (mean +/- SD) MAC, isoflurane 1.56 +/- 0.17 MAC (P greater than 0.05), and sufentanil 2.7 micrograms/kg (MAC values include 0.6 MAC contribution from 60% nitrous oxide). In all patients BP increased during the cerebellar retractor placement period compared with the preretractor placement period (P less than 0.05). The peak increase in systolic BP in response to cerebellar retraction was 17 +/- 6 mmHg for halothane, 38 +/- 20 mmHg for isoflurane, and 26 +/- 19 mmHg for sufentanil. The difference between halothane and isoflurane was significant (P less than 0.05). Mean and diastolic BP showed similar significant differences. The authors conclude that halothane attenuates the hypertensive response to cerebellar retraction more than isoflurane when administered in approximately 1.6 MAC concentrations (MAC value includes contribution from nitrous oxide).     

Intrabiliary pressure changes produced by inhalational anesthetics in dogs]

The common bile duct pressure was studied in dogs under inhalation of 1.0 MAC and 2.0 MAC of halothane, enflurane, isoflurane or sevoflurane. A double lumen catheter was inserted into the common bile duct through the cholecystic duct for the measurement of intraductal pressure in the choledochoduodenal junction. The intra-bile-ductal pressure (IBP) was measured with constant rate infusion methods every 10 minutes for one hour. After obtaining control IBP measurements, 44 dogs received randomly either 1.0 MAC (n = 6 in each group) or 2.0 MAC (n = 5 in each group) of each four inhalational anesthetics, through a non-rebreathing system. The decreases in IBP produced by 1.0 MAC concentrations of four inhalation anesthetics were not statistically significant although there was a decline from control measurements obtained for each group. The elevations of IBP following 2.0 MAC halothane, isoflurane or sevoflurane were significantly depressed and were 38.3 +/- 21.2, 67.5 +/- 23.8, 63.7 +/- 23.7 (%, mean +/- SD) of the control levels, respectively. However, 2.0 MAC enflurane produced no significant decrease in IBP.     

Absence of agonistic or antagonistic effect of flumazenil (Ro 15-1788) in dogs anesthetized with enflurane, isoflurane, or fentanyl-enflurane

This study determined the effects of flumazenil on the anesthetic requirements (MAC) of the dog for isoflurane (group 1; n = 6), enflurane (group 2; n = 7), and a combination of fentanyl-enflurane (group 3; n = 6). Control MAC in each group was determined by the tail-clamp method. Each animal in groups 1 and 2 received four iv incremental doses of flumazenil: 0.5, 1.0, 1.5, and 4.5 mg/kg, and isoflurane MAC or enflurane MAC was determined after each dose. The animals in group 3 received a loading dose and a continuous infusion of fentanyl 0.8 micrograms.kg-1.min-1 over 8 h, and enflurane MAC was determined four times during this experimental period. After the fourth enflurane MAC determination in each animal of group 3, a single iv dose of flumazenil 1.5 mg/kg was injected and enflurane MAC was then determined for the last time. In the incremental doses administered, flumazenil did not demonstrate any agonistic or antagonistic interaction with isoflurane, enflurane, or the fentanyl-enflurane combination. In group 3, plasma fentanyl concentrations remained stable at 12.5 +/- 3.0 ng/ml (mean +/- SD) throughout the experiment and reduced enflurane MAC by 60 +/- 8%. The addition of flumazenil changed neither the fentanyl concentration in plasma (12.2 +/- 3.8 ng/ml) nor its reduction of enflurane MAC (61 +/- 7%). In conclusion, the absence of effect of flumazenil on the MAC of enflurane, isoflurane, or a fentanyl-enflurane combination suggests that they do not interact with the benzodiazepine receptor.     

Additive effects of dihydralazine during enflurane or isoflurane hypotensive anaesthesia for spinal fusion

Sixteen patients (13–38 yr) undergoing spinal fusion for scoliosis under controlled hypotension were studied to determine the haemodynamic and neuroendocrine responses to TV dihydralazine (1.0 mg · kg^-1) followed by 0.5 and 1 MAC of enflurane or isoflurane. Twenty minutes after dihydralazine administration mean arterial pressure (-20 per cent) and systemic vascular resistance (-50 per cent) decreased, and cardiac index (+57 per cent), heart rate (+37 per cent) and intrapulmonary shunt increased. Plasma renin activity and aldosterone and norepinephrine levels increased. Further decreases in mean arterial pressure and in systemic vascular resistance were observed when 0 .5 MAC enflurane or isoflurane were added. With 1 MAC anaesthetic levels a further decrease in mean arterial pressure was observed in both goups, but pressure fell to a lower level with isoflurane than with enflurane (p < 0.01). The reduction of arterial blood pressure to a level of 50–60 mmHg for three to four hours was easy to control and was free of complications. The preliminary PV administration of dihydralazine allowed a reduced volatile agent concentration which attenuated undesirable haemodynamic effects, in spite of renin and norepinephrine release, and permitted a rapid intraoperative awakening.