The inhibition of calcium efflux from rat liver mitochondria by halogenated anesthetics

The halogenated anesthetics halothane, enflurane and isoflurane inhibit the calcium efflux induced by Ruthenium Red in isolated rat liver mitochondria. The extent of the inhibition is higher for enflurane (approximately 50%) than for either isoflurane (approximately 35%) or halothane (approximately 15%), and does not increase significantly between 0.1 and 0.6-1.0 mM anesthetic. Both the mitochondrial respiratory rate and transmembrane electrical potential are unaffected by the halogenated anesthetics concentrations capable to inhibit the efflux of calcium.     

Effect of volatile anaesthetics on the electrical activity and the coupling coefficient of weakly electrically coupled neurones

1. The application of the volatile anaesthetics, halothane and isoflurane (1% v/v and 2% v/v), to the CNS of Lymnaea reduced the firing frequency of the small weakly coupled pedal A cluster (PeA) neurones, which eventually become quiescent. There was no change in their resting membrane potential. 2. Met-enkephalin significantly increased the coupling coefficient between PeA neurones. 3. The volatile anaesthetics decreased the coupling coefficient even in the presence of met-enkephalin. 4. These effects were dose dependent and the effects of halothane were more rapid than those of isoflurane, reflecting their different anaesthetic potencies.     

Estimation of minimum alveolar concentration (MAC) for halothane, enflurane and isoflurane in spontaneously breathing guinea pigs

MAC for halothane, enflurane and isoflurane was determined in guinea pigs (Cavia porcellus) exposed to constant anesthetic concentrations (2.5 hours each) in a flow-through glass chamber. The following values were obtained (N = 8 for each anesthetic): 1.01 +/- 0.03 vol% for halothane, 2.17 +/- 0.04 vol% for enflurane, and 1.15 +/- 0.05 vol% for isoflurane. In guinea pigs, MAC for halothane and enflurane are similar to those reported for other rodents, while MAC for isoflurane is lower. The data indicate that guinea pigs possibly are more susceptible to isoflurane's anesthetic actions than other rodents.     

Volatile anesthetics selectively alter [3H]ryanodine binding to skeletal and cardiac ryanodine receptors.

The effect of clinical concentrations of volatile anesthetics on ryanodine receptors of cardiac and skeletal muscle sarcoplasmic reticulum was evaluated using [3H]ryanodine binding. At 2 volume percent, halothane and enflurane stimulated binding to cardiac SR by 238% and 204%, respectively, while isoflurane had no effect. In contrast, halothane and enflurane had no effect on [3H]ryanodine binding to skeletal ryanodine receptors, while isoflurane produced a significant stimulation. These results suggest that volatile anesthetics interact in a site-specific manner with ryanodine receptors of cardiac or skeletal muscle to effect Ca2+ release-channel gating.     

Interaction of GABA and volatile anesthetics in the nematode Caenorhabditis elegans

The authors tested whether mutant strains of Caenorhabditis elegans with altered sensitivity to volatile anesthetics have altered responses to GABA or GABA-agonists. They determined the ED50s of the wild-type strain N2 and two mutant strains of C. elegans to a GABA-mimetic ivermectin (IVM) and to GABA. unc-79, a strain with increased sensitivity to halothane, was more sensitive than N2 to IVM and GABA. unc-9, a strain that suppresses the increased sensitivity of unc-79 to halothane, was less sensitive than N2 to IVM and GABA. The authors also tested whether doses of GABA or IVM and volatile anesthetics were additive in their effects on C. elegans. Halothane (2.1%) did not shift the ED50 of IVM, but was antagonistic to GABA. Enflurane (4%) was antagonistic to both IVM and GABA. However, ED50s of halothane and enflurane were unchanged in the presence of IVM (35 nM) or GABA (150 mM). The authors conclude that GABA by itself does not appear to mediate halothane or enflurane sensitivity in C. elegans.     

Elevated ornithine decarboxylase activity in the rat liver following exposure to halothane,enflurane and isoflurane

Exposure of rats to the volatile anesthetics, halothane, enflurane and isoflurane and low FIO₂ (0.8%) for two hours results in a transient induction of ODC appearing maximally four hours after exposure. Without the low oxygen accompanying the anesthetic or the low oxygen alone, no significant induction of ODC occurred. The concentration of anesthetic used to produce the ODC induction were 0.5% halothane, 1.5% enflurane and 1.4% isoflurane. Except for halothane, reducing the anesthetic concentration only slightly reduced the effect on ODC levels to control values. Reduction of halothane concentrations to 0.1% was required to reduce the values to control levels. Pretreatment of the animals with either cycloheximide or actinomycin D delayed the onset of ODC induction. The data support the fact that liver damage can occur in the absence of metabolism of the drug.     

Pituitary-adrenocortical axis, serum serotonin and biochemical response after halothane or isoflurane anaesthesia in rabbits

To document the changes in serum serotonin, adrenocorticotrophic hormone (ACTH), corticosterone levels and select biochemical parameters in response to inhalant anaesthesia, 20 New Zealand White (NZW) rabbits were assigned to two treatment groups: halothane and isoflurane. Induction of anaesthesia was achieved using a face mask (3.5% halothane and 4.5% isoflurane in oxygen) followed by endotracheal intubation and maintenance of anaesthesia for 30 min (1.5% halothane and 2.5% isoflurane in oxygen). Blood samples were obtained before anaesthetic induction, and at 1, 10, 30, 60, 120 min and 24, 48 and 72 h after endotracheal intubation. Serum serotonin and corticosterone levels were measured by competitive enzyme immunoassay, ACTH by radioimmunoassay. Serum glucose, alanine aminotransferase (ALT), aspartate aminotransferase (AST), alkaline phosphatase (ALP), blood urea nitrogen (BUN) and creatinine levels were measured using an automated analyser. Significant increases in serum ACTH and corticosterone levels occurred after halothane administration while serum serotonin levels did not change. An increase in serum corticosterone and serotonin levels occurred in the isoflurane group but no changes in ACTH concentrations were detected. Administration of halothane significantly increased serum glucose, ALT, AST, BUN and creatinine levels. After isoflurane administration, there was a significant increase in serum glucose, AST, BUN and creatinine levels. Based on these results, halothane stimulates the hypothalamic-pituitary-adrenal axis to a greater extent than isoflurane, but isoflurane increases serum serotonin levels. Both anaesthetic agents alter select biochemical parameters. These results should be taken into account when blood samples are evaluated in treated isoflurane or halothane anaesthetized rabbits.     

Effects of halothane, enflurane, and isoflurane on measurements of Ca(2+) by calcium electrode and aequorin luminescence

We assessed the possible effects of the volatile halogenated anesthetics halothane, enflurane, and isoflurane on Ca(2+) electrode measurements and on the Ca(2+) sensitivity of the bioluminescent protein aequorin. In Ca(2+)-EGTA buffers of different pCa values (7. 870, 6.726, 6.033, 4.974, 4.038, and 2.995) and in serial Ca(2+) dilutions (10(-4), 10(-3), and 10(-2) M), halothane, enflurane, and isoflurane each caused a concentration-dependent and reversible increase in the absolute value of the negative electrode potential. Isoflurane and enflurane had larger effects than halothane. Neither of these anesthetics changed aequorin luminescence at any pCa tested in the range 2-8. There was no potentiation or inactivation of aequorin luminescence over a period of up to 2 h. These results suggest that (1) halothane, enflurane, and isoflurane interfere with Ca(2+) electrode measurements, most likely by changing the physicochemical properties of the membrane; (2) these anesthetics do not inactivate or otherwise modify the characteristics of the reaction of Ca(2+) with aequorin; and (3) these anesthetics do not change the apparent affinity of EGTA for Ca(2+).     

Carbon monoxide production from five volatile anesthetics in dry sodalime in a patient model: halothane and sevoflurane do produce carbon monoxide; temperature is a poor predictor of carbon monoxide production

BACKGROUND: Desflurane and enflurane have been reported to produce substantial amounts of carbon monoxide (CO) in desiccated sodalime. Isoflurane is said to produce less CO and sevoflurane and halothane should produce no CO at all.The purpose of this study is to measure the maximum amounts of CO production for all modern volatile anesthetics, with completely dry sodalime. We also tried to establish a relationship between CO production and temperature increase inside the sodalime. METHODS: A patient model was simulated using a circle anesthesia system connected to an artificial lung. Completely desiccated sodalime (950 grams) was used in this system. A low flow anesthesia (500 ml/min) was maintained using nitrous oxide with desflurane, enflurane, isoflurane, halothane or sevoflurane. For immediate quantification of CO production a portable gas chromatograph was used. Temperature was measured within the sodalime container. RESULTS: Peak concentrations of CO were very high with desflurane and enflurane (14262 and 10654 ppm respectively). It was lower with isoflurane (2512 ppm). We also measured small concentrations of CO for sevoflurane and halothane. No significant temperature increases were detected with high CO productions. CONCLUSION: All modern volatile anesthetics produce CO in desiccated sodalime. Sodalime temperature increase is a poor predictor of CO production.     

Binding of volatile anesthetics to serum albumin: measurements of enthalpy and solvent contributions

This study directly examines the enthalpic contributions to binding in aqueous solution of closely related anesthetic haloethers (desflurane, isoflurane, enflurane, and sevoflurane), a haloalkane (halothane), and an intravenous anesthetic (propofol) to bovine and human serum albumin (BSA and HSA) using isothermal titration calorimetry. Binding to serum albumin is exothermic, yielding enthalpies (DeltaH(obs)) of -3 to -6 kcal/mol for BSA with a rank order of apparent equilibrium association constants (K(a) values): desflurane > isoflurane approximately enflurane > halothane >or= sevoflurane, with the differences being largely ascribed to entropic contributions. Competition experiments indicate that volatile anesthetics, at low concentrations, share the same sites in albumin previously identified in crystallographic and photo-cross-linking studies. The magnitude of the observed DeltaH increased linearly with increased reaction temperature, reflecting negative changes in heat capacities (DeltaC(p)). These -DeltaC(p) values significantly exceed those calculated for burial of each anesthetic in a hydrophobic pocket. The enhanced stabilities of the albumin/anesthetic complexes and -DeltaC(p) are consistent with favorable solvent rearrangements that promote binding. This idea is supported by substitution of D(2)O for H(2)O that significantly reduces the favorable binding enthalpy observed for desflurane and isoflurane, with an opposing increase of DeltaS(obs). From these results, we infer that solvent restructuring, resulting from release of water weakly bound to anesthetic and anesthetic-binding sites, is a dominant and favorable contributor to the enthalpy and entropy of binding to proteins.     

Gas chromatography in anaesthesia: I. A brief review of analytical methods and gas chromatographic detector and column systems

Practical applications and relevant studies involving the anaesthetic gases, have been extensively described in the literature. Many eminent analytical methods have already been developed for medical practice where routine analysis of anaesthetics is frequently needed, particularly during anaesthesia, and in related and respiratory research programmes. The determination of halothane, isoflurane, enflurane and nitrous oxide concentrations from vaporizers, in exhaled and inhaled gas mixtures, in body fluids and tissues is necessary to control anaesthetic concentrations, and thus, the relevant and adverse effects successfully. Therefore, a literature review, with particular emphasis on gas chromatography would provide important information for investigators in the search for a suitable analytical method for the analysis of multi-component mixtures of anaesthetic gases.     

Effects of isoflurane, halothane, and enflurane on myocardial flow and energy stores in the perfused rat heart

The effect of three volatile anesthetics (halothane, enflurane, and isoflurane) on coronary flow and metabolic state of isolated rat hearts was studied. These anesthetics are coronary dilators and their effects are dose dependent. At 2 MAC (minimum alveolar concentration), isoflurane, enflurane, and halothane increase coronary flow by 114 +/- 5.9, 93 +/- 6.1, and 77 +/- 6.4%, respectively (p less than 0.001). At these concentrations, they also have a modest but significant metabolic effect causing a 30% reduction in myocardial ATP and phosphocreatine levels, with no significant modification in ADP and AMP concentrations. Energy charge and lactate/pyruvate ratio were also unaffected by these anesthetics. The vascular and metabolic effects were reversible within 2 and 30 min, respectively. Perfusion of the hearts with a Krebs-Henseleit solution without Pi did not interfere with the vascular and the metabolic effect of the anesthetics; however, in this case, ATP and phosphocreatine concentration did not return to control levels after their discontinuation despite full recovery of the vascular effect. These data suggest that the volatile anesthetics have direct coronary vascular and myocardial metabolic effects and that these effects occur independently.     

Partitioning of four modern volatile general anesthetics into solvents that model buried amino acid side-chains.

Partitioning of four modern inhalational anesthetics (halothane, isoflurane, enflurane, and sevoflurane) between the gas phase and nine organic solvents that model different amino acid side-chains and lipid membrane domains was performed in an effort to define which microenvironments present in proteins and lipid bilayers might be favored. Compared to a purely aliphatic environment (hexane), the presence of an aromatic-, alcohol-, thiol- or sulfide group on the solvent improved anesthetic partitioning, by factors of 1.3-5.2 for halothane, 1.7-5.6 for isoflurane, 1.7-7.6 for enflurane, and 1.5-7.3 for sevoflurane. The most favorable solvent for halothane partitioning was ethyl methyl sulfide, a model for methionine. Enflurane and isoflurane partitioned most extensively into methanol, a model for serine, and sevoflurane into ethanol, a model for threonine. Isoflurane also partitioned favorably into ethyl methyl sulfide. The results suggest that volatile general anesthetics interact better with partly polar groups, which are present on amino acids frequently found buried in the hydrophobic core of proteins, compared to purely aliphatic side-chains. Furthermore, if an anesthetic molecule was located in a saturated region of a phospholipid bilayer membrane, there would be an energetically favorable driving force for it to move into several higher dielectric microenvironments present on membrane proteins. The results provide evidence that proteins rather than lipids are the likely targets of volatile general anesthetics in biological membranes.     

Effect of 2,6-Diisopropylphenol and Halogenated Anesthetics on Tetraphenylphosphonium Uptake by Rat Brain Synaptosomes: Determination of Membrane Potential

The effect of 2,6-diisopropylphenol (propofol) in comparison to that of the halogenated anesthetics enflurane, isoflurane, and halothane on tetrapenylphosphonium uptake by rat brain synaptosomes was studied. A direct method to separately measure the synaptosomal and the mitochondrial transmembrane potential by using the tetraphenylphosphonium cation (TPP⁺) was utilized. The latter is a lipophylic charged molecule which distributes between two compartments according to the transmembrane electrical potential in the presence or absence of 60 mM KCl as a synaptosomal membrane depolarizing agent. After previously reporting the damages induced by general anesthetics on isolated mitochondria, the aim of this paper was to study their possible action on the synaptosomal membrane potential and whether or not drugs concentrations damaging isolated mitochondria are also effective on synaptosomal mitochondria. The results indicated that, in the presence of glucose, mitochondria included in synaptosomes were able to maintain a transmembrane potential of 202 ± 8 mV (mean ± SD) while the synaptosomal membrane showed a potential of 78 ± 8 mV (mean ± SD). When anesthetic concentrations (0.6–1 mM propofol, 10–40 M enflurane, 30–50 M isoflurane, 8–15 M halothane) that impair mitochondrial energy metabolism were used, the synaptosomal transmembrane potential was maintained and, in addition, a slight increase of the TPP⁺ taken up was observed as the anesthetic concentration was increased.     

Effect of temperature and some common metals on the stability of volatile anaesthetic–Entonox mixtures

Thermal stability of pressurised ready-to-use volatile liquid anaesthetic mixtures (halothane, isoflurane and enflurane) in Entonox (commercially available premixed 50% N₂O, 50% O₂ mixture) were investigated at temperatures of 20, 258, 400, 503 and 602°C on glass, stainless steel, copper and aluminium by gas chromatography and GC–MS. It was found that most of the decomposition products formed were halogenated compounds and the observed thermal stabilities in glass, stainless steel and copper allowed a thermal treatment up to 250°C without any decomposition problem. Aluminium was found to be the most effective metal at causing decomposition of the anaesthetic mixtures even at lower temperatures.     

Fetal development in mice exposed to isoflurane

The developmental toxicity of trace (0.006%), subanesthetic (0.06%), and light anesthetic (0.6%) exposure to isoflurane was examined in Swiss/Webster mice. No adverse effects were demonstrated following exposure of dams to 0.006% (n = 26) and 0.06% (n = 27) isoflurane for 4 hr daily on days 6-15 of pregnancy. Exposure to 0.6% isoflurane (n = 23) for the same period resulted in significantly decreased fetal weight, decreased skeletal ossification, minor hydronephrosis, and increased renal pelvic cavitation. The incidence of cleft palate also was significantly increased, abnormalities occurring in 12.1% of fetuses and affecting 11 of 23 litters. This incidence was considerably higher than that of the combined treatment and colony control groups (0.75%) and those that we have found in previous experiments with this mouse strain following exposure to halothane (1.2%) or enflurane (1.9%).     

Comparison of the effects of volatile anesthetics in varying concentrations on brain energy metabolism with brain ischemia in rats

The effects of varying concentrations and types of volatile anesthetics on neurochemical sequelae of brain ischemia were evaluated in the rat. Rats were assigned to treatment defined by a 3×3 design (anesthetic type and dose) with 5 rats/cell. Each group received halothane, enflurane, or isoflurane 0.5, 1.0, or 2.0 MAC (minimal alevolar concentration). This was followed by preischemic plasma glucose sampling, 5 min hypotension (30 mmHg) and 5 min decapitation cerebral ischemia. Preischemia plasma glucose increased with increasing anesthetic concentration and was highest in the isoflurane groups, varying from a low (±SD) of 7.19±1.79 mol/ml in the 0.5 MAC halothane group to a high of 12.68±3.65 mol/ml in the 2.0 MAC isoflurane group. End-ischemic brain lactate correlated with preischemic plasma glucose (r=0.5, =0.5). We conclude that increasing concentration of volatile anesthesia with iv phenylephrine blood pressure support produces higher levels of plasma glucose and brain lactate with cerebral ischemia.     

Electromyographic activity of expiratory muscles in the rat

We examined the participation of expiratory muscles on breathing in the rat. The experiments were performed on 16 male rats in halothane [1.5%] or urethane [1.3 g/kg i.p.] anaesthesia. We recorded the electromyographic [EMG] activity of intercostal and abdominal muscles with a concentric needle electrode during quiet breathing, breathing against increased pressure in the airways and during the expiration reflex. In halothane anaesthesia the EMG expiratory phasic activity was observed only in internal intercostal muscles in 40% of spots examined during quiet breathing and in 58.5% when breathing against increased pressure. The EMG activity during the expiratory reflex was difficult to evaluate. In the abdominal muscles permanent EMG activity was found in 66% of trials. In urethane anaesthesia no phasic expiratory EMG activity was observed in intercostal or abdominal muscles. In abdominal muscles in 9% of trials a permanent activity was found.     

Sister-chromatid exchanges in operating room personnel.

Sister-chromatid exchange (SCE) analysis was carried out in 67 operating room personnel (anaesthetists M.D.; anaesthesia nurses and anaesthesia unit technicians) exposed to waste anaesthetic gases such as halothane, nitrous oxide and isoflurane and in 50 healthy unexposed controls. The SCE frequencies were increased significantly in operating room personnel as compared to controls. A significant increase in SCEs was found in non-smoking operating room personnel as compared to non-smoking controls. This study supports the existence of an association between occupational exposure to mutagens and an increase in SCEs in lymphocytes.