Alterations of normal left ventricular performance by general anesthesia

Serial invasive and noninvasive (systolic time interval) measurements of left ventricular performance were obtained in six healthy volunteers during general anesthesia employing the following sequence: thiopental induction, succinylcholine (prior to endotracheal intubation), and halothane--100 per cent oxygen at 1.25 and 1.75 MAC. Heart rate (HR), mean pulmonary arterial "wedge" pressure (PAW) and mean systemic arterial pressure (MAP) were measured continuously; cardiac index and systolic time intervals (STI's) were measured during each intervention. At both levels of halothane, MAP and stroke work index decreased (both P less than 0.02), while HR and systemic vascular resistance did not change. At 1.25 MAC halothane PAW was unchanged, but at 1.75 MAC PAW increased from 8 +/- 4 (SD) to 11 +/- 5 torr (P less than 0.02). Preload was altered at 1.25 MAC by administration of 600-1,000 ml lactated Ringer's solution; PAW increased from 9 +/- 4 to 17 +/- 3 torr (P less than 0.01). At 1.75 MAC halothane, volume expansion increased PAW in a similar manner, but the resultant ventricular function curve was depressed compared with 1.25 MAC halothane. In additon, at each level of halothane anesthesia, the ventricular function curve was depressed compared with results obtained in awake normal subjects. Afterload was altered at 1.25 MAC halothane by infusion of phenylephrine sufficient to raise MAP by 30 per cent. This intervention resulted in a greater depression of cardiac performance than that observed at 1.75 MAC halothane alone. Although alterations in STI's were directionally similar to changes observed in invasive hemodynamic measurements, STI's were sensitive to acute alternations in loading conditions. It is concluded that the levels of halothane commonly employed for general anesthesia significantly depress left ventricular performance in normal subjects, as evidenced by abnormal responses to alterations in preload and afterload, and that STI's should not be employed for routine measurement of left ventricular performance during anesthesia unless both the afterload and the preload on the myocardium are known.     

Pulmonary shunting during anesthesia with deliberate hypotension

Pulmonary shunting (Qs/Qt with FIO2 = 1) was measured in 18 anesthetized patients during deliberate hypotension. Hypotension was induced in 12 patients with sodium nitroprusside and light halothane anesthesia and in six others with deep halothane anesthesia and mechanical hyperventilation. Similar results were observed in the two groups. During the hypotensive period mean arterial pressure (MAP) was reduced to 49 +/- 2 torr, a 37 per cent decrease from the control level after the onset of operation and a 40 per cent decrease compared with the recovery level during closure of the wound. Qs/Qt, however, remained unchanged throughout the study: 5.2 +/- 0.9 per cent initially, 5.4 +/- 0.8 per cent during hypotension, and 4.7 +/- 0.5 per cent during recovery. It is concluded that pulmonary shunting need not develop during deliberate hypotension induced with either technique.     

Cerebral energy levels during trimethaphan-induced hypotension in the rat: effects of light versus deep halothane anesthesia

Hypotension may be expected to produce less perturbation of metabolism in the brain when cerebral metabolic rate is lowered by deep anesthesia. Male Wistar rats having unilateral carotidartery ligation were exposed to mean arterial pressure (MAP) of 40 torr for 22 min by an intravenous infusion of trimethaphan during anesthesia with halothane, 0.6 or 2 per cent, in oxygen. Cortical tissue metabolite levels on the side of the ligated carotid artery were more abnormal in rats receiving halothane, 0.6 per cent, than in those receiving halothane, 2 per cent. Values at halothane, 0.6 per cent, were adenosine triphosphate (ATP), 1.71 +/- 0.05 (+/-SEM) mumol/g, phosphocreatine (PCr) 1.97 +/- 0.07 mumol/g. and lactate 16.5 +/- 5.1 mumol/g; corresponding values at halothane, 2 per cent, were ATP 2.27 +/- 0.02, PCr 4.02 +/- 0.23, and lactate 4.75 +/- 0.9 mumol/g. ATP and PCr values were significiantly lower (P less than 0.05) and the lactate value was significantly higher with halothane, 0.6 per cent, than with halothane 2 per cent. Cerebral oxygen consumption decreased 47 per cent in rats anesthetized with halothane, 2 per cent. Preservation of cortical metabolite levels in deeply anesthetized animals suggests a protective effect of cerebral metabolic depression.     

Evidence for regulation of the NADH peroxidase gene (npr) from Enterococcus faecalis by OxyR

To evaluate residual effects of inhalational anesthetics after reversal of neuromuscular blocking agent, neuromuscular function was monitored after halothane or sevoflurane anesthesia in thirty-seven patients (ASA physical status I or II) for elective surgery after obtaining informed consent. Electromyograph of the adductor pollicis muscle in response to train of four (TOF) stimulation was monitored throughout the study. The first twitch of TOF (T1; % of its control) and the ratio of the fourth twitch to the first twitch of TOF (T4/T1; TR) were recorded at 0, 2, 5, 10, and 15 min after reversal. The patients were divided into five groups; 1) the fentanyl group (n = 7) received fentanyl/N2O; 2) in the halothane stop group (n = 6), halothane was discontinued at least fifteen minutes before neostigmine administration; 3) in the halothane stable group (n = 7), 0.7% halothane was maintained until fifteen minutes after neostigmine; 4) in the sevoflurane stop group (n = 12), sevoflurane was discontinued fifteen minutes before the reversal; 5) in the sevoflurane stable group (n = 5), 3% sevoflurane was maintained until fifteen minutes after the reversal. Anesthesia was induced by thiopental 4 mg.kg-1 and suxamethonium 1 mg.kg-1 and the patients were intubated. After initial dose of vecuronium 0.1 mg.kg-1, the additional dose of 0.02 mg.kg-1 was administered to maintain T1 under 10% of the control value. At the end of the surgery atropine 0.015 mg.kg-1 and neostigmine 0.04 mg.kg-1 were administered to reverse vecuronium when T1 had recovered to 25% of its control. Halothane groups did not differ from fentanyl group. Recovery of T1 at 15 min was suppressed after discontinuation of sevoflurane (86.0 +/- 8.2%) in comparison with fentanyl (97.0 +/- 8.3%). Both T1 (75.4 +/- 12.2%) and TR (68.0 +/- 12.6%) at 15 min after the reversal during 3% sevoflurane inhalation were below those of the stable group. We conclude that the residual sevofulrane after discontinuation of inhalation may impair the neuromuscular transmission after the reversal of neuromuscular blockade. Neuromuscular function should be monitored after the end of anesthesia even though the patient is fully awake.     

Inorganic fluoride nephrotoxicity: prolonged enflurane and halothane anesthesia in volunteers

The effects of prolonged enflurane and halothane administration on urine-concentrating ability were determined in volunteers by examining their responses to vasopressin before anesthesia and on days 1 and 5 after anesthesia. A significant decrease in maximum urinary osmolality of 264 +/- 34 mOsm/kg (26 per cent of the preanesthetic value) was present on day 1 after enflurane anesthesia, whereas subjects anesthetized with halothane had a significant increase in maximum urinary osmolality of 120 +/- 44 mOsm/kg. Serum inorganic fluoride level peaked at 33.6 muM and remained above 20 muM for approximately 18 hours. Thus, the threshold level for inorganic fluoride nephrotoxicity is lower than previously suspected.     

Effect of dietary chloride content on the elimination of bromide by dogs

The effect of dietary chloride content (0.2, 0.4 and 1.3 per cent chloride on a dry matter basis) on the disposition of a single oral dose of bromide (14 mg kg-1) was evaluated in normal beagles. Increasing the dietary chloride content from 0.2 to 1.3 per cent resulted in a significant decrease in the mean apparent elimination half-life from 69 +/- 22 days to 24 +/- 7 days. The mean area under the concentration curve (AUC) for dogs fed 1.3 per cent chloride was significantly smaller than the AUC for dogs fed 0.2 per cent chloride. Dietary chloride had no effect on the maximum serum concentrations (Cmax) or on the time (Tmax) to reach the maximum concentrations. The steady-state serum bromide concentrations predicted from the single dose data for daily doses of 14 mg kg-1 of bromide were significantly lower in dogs fed 1.3 per cent chloride (310 +/- 150 mg litre-1) than in dogs fed 0.2 per cent chloride (1950 +/- 1140 mg litre-1). The predicted mean daily doses of bromide necessary to maintain serum levels within the therapeutic range for dogs fed 1.3 per cent chloride (43 +/- 13 mg kg-1) were almost twice as high as the dose estimated for dogs fed 0.4 per cent chloride (22 +/- 3 mg kg-1) and nearly three times as high as the dose estimated for dogs fed 0.2 per cent chloride (15 +/- 4 mg kg-1). These differences were statistically significant (P = 0.002).     

Hepatic clearance of lidocaine during N2O anesthesia in dogs

Lidocaine catabolism under N2O anesthesia was evaluated in 5 dogs given a lidocaine infusion of 2 mg/kg/min for 20 minutes. Comparison of results with those of a prior similar study with halothane to be significantly faster in the animals given N2O. The extraction ratio for lidocaine, which did not vary with its arterial concentration, was significantly lower with halothane than with N2O. Decreased hepatic catabolism of drugs such as lidocaine should be anticipated in patients anesthetized with potent inhalation agents such as halothane.     

Preservation of the ration of cerebral blood flow/metabolic rate for oxygen during prolonged anesthesia with isoflurane, sevoflurane, and halothane in humans

BACKGROUND: In several animal studies, an increase in cerebral blood flow (CBF) produced by volatile anesthetics has been reported to resolve over time during prolonged anesthesia. It is important to investigate whether this time-dependent change of CBF takes place in humans, especially in clinical situations where surgery is ongoing under anesthesia. In this study, to evaluate the effect of prolonged exposure to volatile anesthetics (isoflurane, sevoflurane, and halothane), the CBF equivalent (CBF divided by cerebral metabolic rate for oxygen (CMRO2) was determined every 20 min during anesthesia lasting more than 4h in patients. METHODS: Twenty-four surgical patients were assigned to three groups at random to receive isoflurane, sevoflurane, or halothane (8 patients each). End-tidal concentration of the selected volatile anesthetic was maintained at 0.5 and 1.0 MAC before surgery and then 1.5 MAC for the 3 h of surgical procedure. Normothermia and normocapnia were maintained. Mean arterial blood pressure was kept above 60 mmHg, using phenylephrine infusion, if necessary. CBF equivalent was calculated every 20 min as the reciprocal of arterial-jugular venous oxygen content difference. RESULTS: CBF equivalent at 0.5 MAC of isoflurane, halothane, and sevoflurane was 21 +/- 4, 20 +/- 3, and 21 +/- 5 ml blood/ml oxygen, respectively. All three examined volatile anesthetics significantly (P<0.01) increased CBF equivalent in a dose-dependent manner (0.5, 1.0, 1.5 MAC). AT 1.5 MAC, the increase of CBF equivalent with all anesthetics was maintained increased with minimal fluctuation for 3 h. The mean value of CBF equivalent at 1.5 MAC in the isoflurane group (45 +/- 8) was significantly (P<0.01) greater than those in the halothane (32 +/- 8) and sevoflurane (31 +/- 8) groups. Electroencephalogram was found to be relatively unchanged during observation periods at 1.5 MAC. CONCLUSIONS: These results demonstrate that CBF/CMRO2 ratio is markedly increased above normal and maintained during prolonged inhalation of volatile anesthetics in humans. It is impossible to determine whether these data indicate a stable CBF or whether CBF and CMRO2 are changing in parallel during the observation period. The unchanging electroencephalographic pattern suggests that the former possibility is more likely and that the increase of CBF produced by volatile anesthetics is maintained over time without decay, which has been reported in several animal studies. It also is suggested that isoflurane possesses greater capability to maintain global CBF relative to CMRO(2) than does halothane or sevoflurane. time.)     

Retrospective evaluation of cardiopulmonary and acid-base variables during long-term balanced anesthesia for experimental surgery in dogs

Cardiopulmonary and acid-base variables recorded during long-term balanced anesthesia lasting between 12.5 and 16.9 h were evaluated retrospectively in 15 healthy foxhounds that underwent experimental bulla osteotomy with implantation of hearing aids. After premedication with propionylpromazine (0.11 +/- 0.02 mg/kg of body weight) and L-methadone (0.71 +/- 0.06 mg/kg) intravenously (i.v.) and induction with pentobarbital sodium (6.02 +/- 0.83 mg/kg i.v.), anesthesia was maintained with halothane (end-tidal concentration; ETHAL: 0.4 to 1.5%) in nitrous oxide (2 L/min) and oxygen (1 L/min). Because of positional changes from sternal to right lateral recumbency after presurgical brain stem electric response audiometry and differences in duration of surgery, data obtained between 4 (baseline) and 14 h after induction of anesthesia were analyzed. Arterial (PaO2) and alveolar (PAO2) O2 tensions, arterial-to-alveolar O2 tension ratio (PaO2/PAO2), and arterial O2 content (CaO2) remained relatively stable throughout anesthesia. Arterial carbon dioxide tension (PaCO2) was significantly increased above baseline (39, 33 to 46 mm Hg [median, range]) between 7 (39.8, 36.5 to 48.9 mm Hg) and 9 (42, 37.5 to 49.5 mm Hg) h after induction. Because changes in PaCO2 were accompanied by significant increases in body temperature from baseline (36.3, 34.6 to 37.4 degrees C) between 8 (37.1, 35 to 38 degrees C) and 11 (37.6, 35.3 to 38.1 degrees C) h after anesthesia induction as well as by slight increases in arterial blood pressure, the PaCO2 increase may have been caused by increase in metabolic CO2 production and enhanced drainage of CO2 from the tissues into systemic circulation. Furthermore, mild metabolic acidosis (pHa: 7.31, 7.26 to 7.38; HCO3-: 18.9, 16.7 to 21.8 mEq/L; base deficit [BD]: -6.3, -8.5 to -3.4 mEq/L) already existed at 4 h after induction and was related in part to tissue hypoperfusion. Small increases in pHa during the course of anesthesia were accompanied by significant increases in HCO3- concentration and significant decreases in BD between 5 and 10 h after induction. Minor circumscribed swelling of the dependent triceps or masseter muscle was noticed on the first postoperative day in two dogs, and marked tissue swelling with hematoma formation at the medial side of one hind limb was noticed in a third dog. All dogs recovered completely and were submitted to follow-up studies. The anesthetic protocol and extent of monitoring used were adequate to provide safe long-term anesthesia for an experimental surgical procedure with a 100% survival rate and uneventful recovery in most of the dogs.     

Differential response of arteries and vein grafts to blood flow reduction

BACKGROUND: Because the relative efficacy of antiarrhythmic agents on halothane-epinephrine arrhythmias has not been well characterized, this study was undertaken to comparatively evaluate the antiarrhythmic action of Na(+)-, K(+)- and Ca(2+)-channel blockers on epinephrine-induced ventricular arrhythmias during halothane anesthesia in rats. METHODS: Rats were anesthetized at random with either halothane (1.5%), isoflurane (2.0%), or pentobarbital (50 mg/kg intraperitoneally), and the lungs were mechanically ventilated with oxygen. The rats were studied in three consecutive protocols. Protocol I determined the arrhythmogenic thresholds of epinephrine during the three types of anesthesia in 33 rats. Protocol II determined the arrhythmogenic thresholds of epinephrine during halothane anesthesia in 64 rats receiving saline (control) or one of five antiarrhythmic agents. Protocol III measured the duration of epinephrine-induced arrhythmias during halothane anesthesia in 42 rats receiving saline (control) or one of five antiarrhythmic agents. RESULTS: In protocol I, the arrhythmogenic doses of epinephrine during halothane, isoflurane, or pentobarbital anesthesia were 1.7 +/- 3.2, 11.1 +/- 0.6, and 39.0 +/- 3.9 micrograms/kg, respectively, and the corresponding plasma concentrations were 4.3 +/- 0.8, 103.7 +/- 9.2, and 246.7 +/- 28.9 ng/ml, respectively. In protocol II, the arrhythmogenic doses were similar in rats receiving saline and in those receiving lidocaine. The arrhythmogenic doses in rats receiving verapamil, flecainide (Na(+)- and K(+)-channel blocker), E-4031 (K(+)-channel blocker), or amiodarone(K(+)-channel blocker with Na(+)-, Ca(2+)-, and beta-blocking activity) increased significantly, i.e., 4.2, 4.2, 5.5, and 31.7 times control (P < 0.01). In protocol III, lidocaine had no effect on the duration of arrhythmias. Flecainide, E-4031, and verapamil markedly reduced the duration of arrhythmias induced by epinephrine, 8 micrograms/kg intravenously (P < 0.01), whereas only amiodarone markedly reduced the duration of arrhythmias induced by epinephrine, 16 micrograms/kg intravenously (P < 0.01). CONCLUSIONS: It was concluded that agents with K(+)-channel blocking properties were the most effective in preventing halothane-epinephrine arrhythmias in rats.     

The microbicidal effect of aldehydes and aldehyde combinations

The effects of enflurane anesthesia on adrenal medullary catecholamine secretion and on the pressor effect of splanchnic-nerve stimulation were studied in cats given pentobarbital for basal anesthesia. Inhalation of enflurane, 1.2 and 2.2 per cent, caused dose-related inhibition of both spontaneous catecholamine release and secretion evoked by splanchnic-nerve stimulation. During inhalation of 2.2 per cent enflurane spontaneous release of epinephrine was decreased to 19 and 25 per cent, respectively, of the initial values, and the stimulated release was decreased to 30 and 15 per cent, respectively. Enflurane also inhibited the pressor effect of splanchnic-nerve stimulation, whereas that of norepinephrine was not changed significantly. These results are similar to those previously obtained with halothane and methoxyflurane. It is concluded that the decrease in catecholamine secretion caused by enflurane is in part due to a direct effect on the chromaffin cell, namely to an inhibition of the secretion-stimulating effect of acetylcholine released from splanchnic nerves.     

Selective anesthetic inhibition of brain nitric oxide synthase

BACKGROUND: It has been postulated that nitric oxide (NO) is a neurotransmitter involved in consciousness, analgesia, and anesthesia. Halothane has been shown to attenuate NO-mediated cyclic guanosine monophosphate accumulation in neurons, and a variety of anesthetic agents attenuate endothelium-mediated vasodilation, suggesting an interaction of anesthetic agents and the NO-cyclic guanosine monophosphate pathway. However, the exact site of anesthetic inhibitory action in this multistep pathway is unclear. The current study examines effects of volatile and intravenous anesthetic agents on the enzyme nitric oxide synthase (NOS) in brain. METHODS: NOS activity was determined by in vitro conversion of [14C]arginine to [14C]citrulline. Wistar rats were decapitated and cerebellum quickly harvested and homogenized. Brain extracts were then examined for NOS activity in the absence and presence of the volatile anesthetics halothane and isoflurane, and the intravenous agents fentanyl, midazolam, ketamine, and pentobarbital. Dose-response curves of NOS activity versus anesthetic concentration were constructed. Effects of anesthetics on NOS activity were evaluated by analysis of variance. RESULTS: Control activities were 57.5 +/- 4.5 pmol.mg protein-1.min-1 in the volatile anesthetic experiments and 51.5 +/- 6.5 pmol.mg protein-1.min-1 in the intravenous anesthetic experiments. NOS activity was not affected by ketamine (< or = 1 x 10(-4) M), pentobarbital (< or = 5 x 10(-5) M), fentanyl (< or = 1 x 10(-5) M), and midazolam (< or = 1 x 10(-5) M). Halothane decreased NOS activity to 36.7 +/- 2.5 (64% of control, P < 0.01 from control), 23.8 +/- 4.3 (41%, P < 0.01 from control and < 0.05 from 0.5% halothane), 25.2 +/- 3.8 (44%, P < 0.01 from control and < 0.05 from 0.5% halothane), and 19.7 +/- 2.8 (34%, P < 0.01 from control and < 0.05 from 0.5% halothane) pmol.mg protein-1.min-1 at 0.5, 1.0, 2.0, and 3.0% vapor. Isoflurane decreased NOS activity to 48.9 +/- 6.1 (85% of control), 46.0 +/- 3.2 (80%, P < 0.05 from control), 40.3 +/- 5.1 (70%, P < 0.05 from control), and 34.2 +/- 4.0 (60%, P < 0.05 from control and 0.5% and 1.0% isoflurane) pmol.mg protein-1.min-1 at 0.5, 1.0, 1.5, 2.0% vapor, respectively. CONCLUSIONS: Volatile anesthetics inhibit brain NOS activity in an in vitro system, but the intravenous agents examined have no effect at clinically relevant concentrations. This inhibition suggests a protein-anesthetic interaction between halothane, isoflurane, and NOS. In contrast, intravenous agents appear to have no direct effect on NOS activity. Whether intravenous agents alter signal transduction or regulatory pathways that activate NOS is unknown.     

Comparative effects of propofol, pentobarbital, and isoflurane on cerebral blood flow and blood volume

While intravenous and volatile anesthetics have widely differing effects on cerebral blood flow (CBF), clinical studies suggest that the relative differences in their effects on intracranial pressure (ICP) may be smaller. Because acute changes in ICP are determined primarily by changes in cerebral blood volume (CBV), we compared the impact of propofol, pentobarbital, and isoflurane on CBF and CBV in rats. Equipotent doses of the three agents were determined by tail-clamp studies. Animals were then anesthetized with propofol (20 mg/kg load, 38 mg.kg-1.h-1 infusion), pentobarbital (30 mg/kg load, 20 mg.kg-1.h-1 infusion), or isoflurane 1.6-1.8%. Two hours later, CBF and CBV were measured using 3H-nicotine as a CBF tracer, and 14C-dextran and 99mTc-labeled red cells as markers for cerebral plasma and red blood cell volumes (CPV and CRBCV), respectively. Total CBV was the sum of CPV and CRBCV. CBF was 2.0-2.6 times greater with isoflurane than with propofol or pentobarbital (137 vs. 67 and 52 ml.100 g-1.min-1, respectively). By contrast, while CBV was greater in the isoflurane group than in either the propofol or pentobarbital groups, the magnitude of the intergroup differences were much smaller (propofol = 2.49 +/- 0.28 ml/100 g; pentobarbital = 2.27 +/- 0.15 ml/100 g; isoflurane = 2.77 +/- 0.24 ml/100 g, mean +/- SD). These results suggest that the simple measurement of CBF may not adequately describe the cerebrovascular effects of an anesthetic, at least with respect to predicting the magnitude of the agents likely effects on ICP.     

Quantitative autoradiography of halothane binding in rat brain

14C-halothane direct photoaffinity labeling was used to characterize the distribution of halothane binding in rat brain to test the hypothesis that anesthetics bind preferentially to a specific, heterogeneously distributed, receptor or channel. Slide-mounted sagittal rat brain sections were placed in gas-tight quartz cuvettes with 100 microM 14C-halothane in phosphate buffered saline with 0 to 7.5 mM unlabeled halothane, or unlabeled chloroform and isoflurane at 10 times the clinical EC50, and then exposed to UV light for 60 to 100 sec. Autoradiograms of nine brain regions (cortex, corpus callosum, hippocampal molecular and pyramidal layers, dentate molecular and granule cell layers, and cerebellar molecular, granular and white matter layers) were prepared and quantitated using Image 1.44. Total label incorporation was widespread, but exhibited subtle heterogeneity. There was significantly more total labeling in regions of high synaptic density than in regions containing primarily cell bodies or white matter. Most labeling (approximately 80%) was displaced by unlabeled halothane and can therefore be considered specific. Significantly more specific labeling was found in regions of high synaptic density. Isoflurane did not inhibit halothane photolabeling significantly, but chloroform inhibited it by approximately 50%. In conclusion, halothane photolabeling distribution in the mammalian brain is widespread, saturable and selective, but does not mimic the distribution of any individual receptor or channel. Brain regions with high synaptic density displayed the greatest degree of specific binding, consistent with transmission being an important functional target of volatile anesthetics. These results suggest a remarkably widespread individual target, or more likely, similar binding sites in multiple targets, and are consistent with the notion that anesthesia is the result of action at multiple sites.     

Pentobarbital anesthesia: lack of effect on venous prostaglandins in dogs

Venous prostaglandins A, E, and F were determined by radioimmunoassay in 10 dogs before and one hour after administration of sodium pentobarbital (35 mg/Kg, iv). In the conscious state, PGA was 0.34 + 0.04 ng/ml (mean +/- SE), PGE 0.20 + 0.01 ng/ml, and PGF 0.25 + 0.03 ng/ml. During pentobarbital anesthesia, these levels were unchanged (p greater than 0.05). Thus, pentobarbital anesthesia had no effect on peripheral venous prostaglandin levels.     

Delayed onset of malignant hyperthermia induced by isoflurane and desflurane compared with halothane in susceptible swine

BACKGROUND: Desflurane (difluoromethyl 1-fluoro 2,2,2-trifluoroethyl ether) is a new inhalational anesthetic currently under investigation for use in humans. Recently, the authors showed that desflurane is a trigger of malignant hyperthermia (MH) in susceptible swine. To date, there has been no in vivo comparison of the relative ability of inhalational anesthetics to trigger MH. The effects of desflurane, isoflurane, and halothane on six MH-susceptible purebred and six MH-susceptible mixed-bred Pietrain swine were examined. METHODS: The animals were exposed to 1 MAC and 2 MAC (if MH was not triggered after 1 MAC hour) doses of each of the three volatile anesthetics in random sequence at 7-10-day intervals and changes in end-tidal CO2, arterial blood gases, serum lactate, core and muscle temperature, blood pressure, and heart rate were measured. RESULTS: There was a statistical difference between anesthetics in the time required to trigger MH; halothane exposure resulted in the fastest onset of an MH episode (20 +/- 5 min), compared with isoflurane (48 +/- 24 min) and desflurane (65 +/- 28 min), both of which required significantly longer exposures. There was no statistical difference between the MH purebred and mixed-bred swine in the time required to trigger MH (defined as a PaCO2 of 70 mmHg) with a given agent, and time to triggering was also independent of the order of exposure to the three anesthetics. Malignant hyperthermia susceptibility was confirmed in ten surviving animals, by both in vivo succinylcholine challenge and in vitro contracture testing. CONCLUSIONS: Although all three volatile anesthetics triggered MH, exposure to halothane resulted in significantly shorter times to MH triggering when compared with desflurane and isoflurane.     

Respiratory effects of desflurane anesthesia on spontaneous ventilation in infants and children

Volatile anesthetics depress spontaneous ventilation in a dose-dependent manner with variations in effects among different drugs. The goal of this prospective study was to assess respiratory changes during spontaneous ventilation using desflurane/O2/N2O anesthesia in two groups of children. Both groups were undergoing minor surgery and consisted of children < 2 yr old (Group I) and children > 2 yr old (Group II). They were examined at 0.5, 1, and 1.5 minimum alveolar anesthetic concentration desflurane anesthesia. Induction of anesthesia was performed via a face mask and a mixture of O2/N2O (40:60) with halothane. At lease 20 min after stopping halothane, the respiratory variables were recorded on desflurane anesthesia. Tidal volume and minute ventilation decreased significantly (P <0.05) as desflurane increased from 0.5 to 1.5 MAC in both groups. At 1.5 MAC, the respiratory rate was greater in Group II than in Group I (P <0.05). In both groups, the increase in end-tidal CO2 was significant at 1.5 MAC versus 1 and 0.5 MAC (P <0.05). Apnea, i.e., no respiratory movement for 20 s, occurred at 1.5 MAC in one patient in each group. The respiratory duty cycle did not change in any of the groups. Both indices of paradoxical respiration--amplitude index and delay index--did not change. IMPLICATIONS: Desflurane induces respiratory depression at concentrations higher than 1 minimum alveolar anesthetic concentration mainly due to a decrease in tidal volume. Therefore, desflurane at high concentrations should be used cautiously in infants and children with spontaneous ventilation.     

Brain alpha 2-adrenergic receptor binding during incomplete cerebral ischemia in the rat

alpha 2-Adrenergic agonists decrease sympathetic activity and improve outcome from brain ischemia. We evaluated whether changes in alpha 2-adrenergic receptor binding activity may be important in the sympathetic depressant and cerebral protective effects of halothane (1.1% inspired) or isoflurane (1.4% inspired) compared to fentanyl/nitrous oxide (N2O) anesthesia. Brain alpha 2-adrenergic receptor binding was measured using [3H]-clonidine in each of four treatment conditions: 1, unanesthetized; 2, anesthetized (fentanyl/N2O, halothane, or isoflurane): 3, anesthetized with ischemia; 4, after 4 h recovery from ischemia. Ischemia was produced by right carotid artery ligation combined with hemorrhagic hypotension to 30 mm Hg for 30 min. Both halothane and isoflurane decreased alpha 2-adrenergic receptor density 20% compared to unanesthetized values (P < 0.01). This decrease was attenuated in ischemic tissue. There were no consistent changes in receptor affinity. These results suggest that inhaled anesthetics decrease the number of alpha 2-adrenergic receptors. This decrease appears to be unrelated to plasma catecholamine concentrations but may be influenced by the degree of ischemia.     

Oral clonidine premedication reduces minimum alveolar concentration of sevoflurane for tracheal intubation in children

BACKGROUND: Sevoflurane is a useful anesthetic for inhalational induction in children because of its low solubility in blood and relatively nonpungent odor. Clonidine has sedative and anxiolytic properties and reduces the requirement for inhalation agents. Nitrous oxide (N2O) also decreases the requirement of inhaled anesthetics, but the effect is variable. The minimum alveolar concentration for tracheal intubation (MAC(TI)) of sevoflurane was assessed with and without N2O and clonidine premedication. METHODS: Seventy-two patients, aged 3-11 yr, were assigned to one of six groups (n = 12 each). They received one of three preanesthetic medications (two groups for each premedication): placebo (control), 2 microg/kg oral clonidine or 4 microg/kg oral clonidine. In one group of each premedication, anesthesia was induced with sevoflurane in oxygen; in the other group, anesthesia was induced with sevoflurane in the presence of 60% N2O. Each concentration of sevoflurane at which tracheal intubation was attempted was predetermined according to Dixon's up-and-down method and held constant for at least 20 min before the trial RESULTS: The MAC(TI) of sevoflurane in the absence of N2O (mean +/- SEM) was 3.2 +/- 0.2%, 2.5 +/- 0.1%, and 1.9 +/- 0.2% in the control, 2-microg/kg clonidine, and 4-microg/kg clonidine groups, respectively. Nitrous oxide (60%) decreased the MAC(TI) of sevoflurane by 26%, 24%, and 27% in the control, 2-microg/kg clonidine, and 4-microg/kg clonidine groups. CONCLUSIONS: Oral clonidine premedication decreased the MAC(TI) of sevoflurane. Nitrous oxide also decreased the MAC(TI). The combination of clonidine and N2O lessened the MAC(TI) of sevoflurane more than did either drug alone.     

Isoflurane and halothane do not alter the enhanced afterload sensitivity of left ventricular relaxation in dogs with pacing-induced cardiomyopathy

BACKGROUND: The afterload dependence of left ventricular (LV) relaxation is accentuated in the failing heart. The authors tested the hypothesis that isoflurane and halothane alter the afterload sensitivity of LV relaxation in dogs with pacing-induced cardiomyopathy. METHODS: Dogs (n = 6) were chronically instrumented for measurement of LV and aortic pressures and subendocardial segment length. Hemodynamics were recorded, and LV relaxation was evaluated with a time constant of isovolumic relaxation (tau) under control conditions and during decreases and increases in LV load produced by abrupt inferior vena caval (IVC) occlusion and phenylephrine (intravenous infusion), respectively, in the conscious state and during isoflurane and halothane anesthesia (1.5 MAC) on separate days before and after the development of pacing-induced cardiomyopathy. The slope (R) of the tau versus LV end-systolic pressure (P[es]) relation was also used to determine the afterload sensitivity of LV relaxation. RESULTS: IVC occlusion and phenylephrine produced similar or less profound changes in P(es), regional end-systolic force (an index of LV afterload), and end-systolic segment length in cardiomyopathic compared with healthy dogs. However, IVC occlusion and phenylephrine caused more pronounced alterations in tau in conscious and isoflurane- and halothane-anesthetized dogs after the development of cardiomyopathy. R was also greater in cardiomyopathic compared with healthy dogs (e.g., 0.32 +/- 0.03 before pacing to 1.00 +/- 0.13 ms/mmHg in conscious dogs). No differences in the load dependence of LV relaxation were observed between the conscious and anesthetized states before and after production of LV dysfunction. CONCLUSIONS: The results indicate that isoflurane and halothane do not alter the afterload dependence of LV relaxation in the normal and cardiomyopathic heart. The lack of effect of the volatile anesthetics is probably related to anesthetic-induced reductions in the resistance to LV ejection concomitant with simultaneous negative inotropic effects.