Bidirectional modulation of isoflurane potency by intrathecal tetrodotoxin and veratridine in rats.

BACKGROUND AND PURPOSE: Results from several studies point to voltage-gated Na(+) channels as potential mediators of the immobility produced by inhaled anaesthetics. We hypothesized that the intrathecal administration of tetrodotoxin, a drug that blocks Na(+) channels, should enhance anaesthetic potency, and that concurrent administration of veratridine, a drug that augments Na(+) channel opening, should reverse the increase in potency. EXPERIMENTAL APPROACH: We measured the change in isoflurane potency for reducing movement in response to a painful stimulus as defined by MAC (minimum alveolar concentration of anaesthetic required to abolish movement in 50% of subjects) caused by intrathecal infusion of various concentrations of tetrodotoxin into the lumbothoracic subarachnoid space of rats, and the change in MAC caused by the administration of a fixed dose of tetrodotoxin plus various doses of intrathecal veratridine. KEY RESULTS: Intrathecal infusion of tetrodotoxin (0.078-0.63 microM) produced a reversible dose-related decrease in MAC, of more than 50% at the highest concentration. Intrathecal co-administration of veratridine (1.6-6.4 microM) reversed this decrease in a dose-related manner, with nearly complete reversal at the highest veratridine dose tested. CONCLUSIONS AND IMPLICATIONS: Intrathecal administration of tetrodotoxin increases isoflurane potency (decreases isoflurane MAC), and intrathecal administration of veratridine counteracts this effect in vivo. These findings are consistent with a role for voltage-gated Na(+) channel blockade in the immobility produced by inhaled anaesthetics.

The convulsant and anesthetic properties of cis-trans isomers of 1,2-dichlorohexafluorocyclobutane and 1,2-dichloroethylene.

UNLABELLED: The differences in potencies of optical isomers of anesthetics support the hypothesis that anesthetics act by specific receptor interactions. Diastereoisomerism and geometrical isomerism offer further tests of this hypothesis but have not been explored. They are the subject of this report. We quantified the nonimmobilizing and convulsant properties of the cis and trans diastereomers of the nonimmobilizer 2N (1,2-dichlorohexafluorocyclobutane). Although the lipophilicity of the diastereomers predicts complete anesthesia at the partial pressures applied, neither diastereomer had anesthetic activity alone, and the cis form may have a small (10%) capacity to antagonize anesthesia, as defined by additive effects on the MAC (the minimum alveolar concentration required to suppress movement to a noxious stimulus in 50% of rats) of desflurane. Both diastereomers produced convulsions, the cis form being nearly twice as potent as the trans form: convulsant 50% effective dose (mean +/- SD) was 0.039 +/- 0.009 atmospheres (atm) for the purified cis and 0.064 +/- 0.009 atm for the purified trans isomer. The MAC value for cis-1,2-dichloroethylene equaled 0.0071 +/- 0.0006 atm, and MAC for trans-1,2-dichloroethylene equaled 0.0183 +/- 0.0031 atm. In qualitative accord with the Meyer-Overton hypothesis, the greater cis potency was associated with a greater lipophilicity. However, the product of MAC x solubility differed between the cis and trans isomers by 40%-50%. We conclude that neither the cis nor trans isomers of 2N have anesthetic properties, but isomerism does influence 2N's convulsant properties and the anesthetic properties of dichloroethylene. These isomeric effects may be as useful in defining receptor-anesthetic interactions as those found with optical isomers. IMPLICATIONS: Cis-trans isomerism can influence the convulsant properties of the nonimmobilizer 2N (1,2-dichlorohexafluorocyclobutane) and the anesthetic properties of dichloroethylene. Such isomeric effects may be as useful as those found with optical isomers in defining receptor-anesthetic interactions.

The effect of rigidity, shape, unsaturation, and length on the anesthetic potency of hydrocarbons.

We previously hypothesized that anesthesia results from an action on two sites separated by 5 A. The hypothesis relied on the finding that fluorinated alkanes having active anesthetic sites at each end of the molecule produce anesthesia as long as the total number of carbon atoms in their structure does not exceed five (i.e., approximately 5 A), and on the sustaining of the 5-A separation by the rigidity produced by fluorination. In this study, we tested an alternative hypothesis: that the site of action cannot accommodate a rigid compound, particularly a rectilinear compound, having more than five carbon atoms, and that rigidity itself might limit the anesthetic potency of larger compounds. We tested the anesthetic potency of 11 hydrocarbons in which rigidity was increased by unsaturation. In 72 rats exposed to such compounds, we found that unsaturation, rigidity, or both produced by unsaturation either did not change (double bonds) or increased (triple bonds) potency for a given number of carbon atoms. For example, we found that the rectilinear, rigid 2,4-trans-trans-hexadiene was no less potent (minimum alveolar anesthetic concentration [MAC] 0.042 +/- 0.002 atm; mean +/- SD) than the flexible 1,5-hexadiene (0.047 +/- 0.005 atm) or n-hexane (0.0467 +/- 0.0055 atm) and that 3-hexyne was more potent (MAC 0.0146 +/- 0.0014 atm) than n-hexane (MAC 0.0467 +/- 0.0055 atm). We conclude that the site of anesthetic action can accommodate straight rigid structures of up to six carbons in length.

The concentration of isoflurane required to suppress learning depends on the type of learning.

BACKGROUND: Recent reports suggest that one type of learning, fear conditioning to context, requires more neural processing than a related type, fear conditioning to tone. To determine whether these types of learning were differentially affected by anesthesia, the authors applied isoflurane during the training phases of fear conditioning paradigms for freezing to context and freezing to tone. METHODS: The authors trained seven groups of eight rats to fear tone by administering a tone (conditioned stimulus) while breathing various concentrations of isoflurane from 0.00 to 0.75 minimum alveolar concentration (MAC; one concentration per group) separated by 0.12-MAC steps. On the succeeding day, and in the absence of isoflurane, the authors presented the tone (without shock) in a different context (different cage shape and odor) and measured the time each rat froze (became immobile). Six other groups of eight rats were trained to fear context by applying the shock in the absence of a tone but in the presence of environmental cues such as cage shape, texture, and odor. Fear to context was determined the succeeding day by returning the rat to the training cage (without shock) and measuring duration of freezing. Control groups (16 per group) received 0.75 MAC isoflurane but no foot shocks. Group scores were compared using analysis of variance, and the ED50 values for quantal responses of individual rats were calculated using logistic regression. RESULTS: Conditioning to context occurred at 0.00 and 0.13 MAC (P < 0.05 compared with unshocked control) but not 0.25 MAC; the ED50 was 0.25 +/- 0.03 MAC (mean +/- SEM). In contrast, conditioning to tone occurred at 0.48 MAC (P < 0.05) but not 0.62 MAC; the ED50 was 0.47 +/- 0.02 MAC (P < 0.01 for the difference between ED50 values). CONCLUSIONS: Suppression of fear conditioning to tone required approximately twice the isoflurane concentration that suppressed fear conditioning to context. Thus, the concentration of anesthetic required to suppress learning may depend on the neural substrates of learning. Our results suggest that isoflurane concentrations greater than 0.5 MAC may be needed to suppress both forms of fear conditioning.

The anesthetic potencies of alkanethiols for rats: relevance to theories of narcosis.

UNLABELLED: Meyer and Overton suggested that anesthetic potency correlates inversely with lipophilicity. Thus, MAC times the olive oil/gas partition coefficient equals an approximately constant value of 1.82 +/- 0.56 atm (mean +/- SD). MAC is the minimum alveolar concentration of anesthetic required to eliminate movement in response to a noxious stimulus in 50% of subjects. Although MAC times the olive oil/gas partition coefficient also equals an approximately constant value for normal alkanols from methanol through octanol, the value (0.156 +/- 0.072 atm) is 1/10th that found for conventional anesthetics. We hypothesized that substitution of sulfur for the oxygen in n-alkanols would decrease their saline/gas partition coefficients (i.e., decrease polarity) while sustaining lipid/gas partition coefficients. Further, we hypothesized that these changes would produce products of MAC times olive oil partition coefficients that approximate those of conventional anesthetics. To test these predictions, we measured MAC in rats, and saline and olive oil solubilities for the series H(CH(2))(n)SH, comparing the results with the series H(CH(2))(n)OH for compounds having three to six carbon atoms. As hypothesized, the alkanethiols had similar oil/gas partition coefficients, 1000-fold smaller saline gas partition coefficients, and MAC values 30 times greater than for comparable alkanols. Such findings are consistent with the notion that the greater potency of many alkanols (greater than would be predicted from conventional inhaled anesthetics and the Meyer-Overton hypothesis) results from their greater polarity. IMPLICATIONS: The in vivo anesthetic potency of alkanols and alkanethiols correlates with their lipophilicity and hydrophilicity.

Fractional distillation of acid contaminants from sevoflurane.

On two occasions, sevoflurane distributed for clinical practice has been found to be contaminated with compounds thought to include hydrogen fluoride (HF) and silicon tetrafluoride (SiF(4)). Both compounds can produce pulmonary injury. However, injury would require fractional distillation of the compounds during the course of sevoflurane vaporization. We hypothesized that such distillation would occur and that the compounds would vaporize more rapidly than would sevoflurane. Thus, we tested whether fractional distillation occurs during vaporization of sevoflurane containing HF or SiF(4), or from sevoflurane containing HF converted to other compounds by contact with glass. Vaporization of < 10% of the sevoflurane distilled 65%-99% of these compounds, SiF(4) distilling most rapidly, HF (converted to other acidic compounds, including SiF(4)) distilling nearly as rapidly, and HF slowest. Nuclear magnetic resonance studies indicated that HF interaction with glass changed all HF to three other compounds, one being SiF(4) and the others being unknown. HF and SiF4 distill from sevoflurane more rapidly than sevoflurane is vaporized. Measurement of acidity after sevoflurane administration may not reveal a previous presence of such contaminants.

Absorbents differ enormously in their capacity to produce compound A and carbon monoxide.

UNLABELLED: Concern persists regarding the production of carbon monoxide (CO) and Compound A from the action of carbon dioxide (CO(2)) absorbents on desflurane and sevoflurane, respectively. We tested the capacity of eight different absorbents with various base compositions to produce CO and Compound A. We delivered desflurane through desiccated absorbents, and sevoflurane through desiccated and moist absorbents, then measured the resulting concentrations of CO from the former and Compound A from the latter. We also tested the CO(2) absorbing capacity of each absorbent by using a model anesthetic system. We found that the presence of potassium hydroxide (KOH) and sodium hydroxide (NaOH) increased the production of CO from calcium hydroxide (Ca[OH](2)) but did not consistently affect production of Compound A. However, the effect of KOH versus NaOH was not consistent in its impact on CO production. Furthermore, the effect of KOH versus NaOH versus Ca(OH)(2) was inconsistent in its impact on Compound A production. Two absorbents (Amsorb) [Armstrong Medica, Ltd, Coleraine, Northern Ireland], composed of Ca(OH)(2) plus 0.7% polyvinylpyrrolidine, calcium chloride, and calcium sulfate; and lithium hydroxide) produced dramatically lower concentrations of both CO and Compound A. Both produced minimal to no CO and only small concentrations of Compound A. The presence of polyvinylpyrrolidine, calcium chloride, and calcium sulfate in Amsorb appears to have suppressed the production of toxic products. All absorbents had an adequate CO(2) absorbing capacity greatest with lithium hydroxide. IMPLICATIONS: Production of the toxic substances, carbon monoxide and Compound A, from anesthetic degradation by carbon dioxide absorbents, might be minimized by the use of one of two specific absorbents, Amsorb (Armstrong Medica, Ltd., Coleraine, Northern Ireland) (calcium hydroxide which also includes 0.7% polyvinylpyrrolidine, calcium chloride, and calcium sulfate) or lithium hydroxide.

Mouse strain modestly influences minimum alveolar anesthetic concentration and convulsivity of inhaled compounds.

UNLABELLED: In this study, we measured the minimum alveolar anesthetic concentration (MAC) in several mouse strains, including strains used in the construction of genetically engineered mice. This is important because defined genetic modifications are used increasingly to test mechanisms of inhaled anesthetic action, and background variability in MAC can potentially influence the interpretation of these studies. We investigated the effect of strain on MAC for desflurane, isoflurane, halothane, ethanol, the experimental anesthetic 1-chloro-1,2,2-trifluorocyclobutane, and convulsive 50% effective dose (the dose required to produce convulsions in 50% of animals) of the nonimmobilizer 1,2-dichlorohexafluorocyclobutane. These drugs were studied in eight inbred strains, including both laboratory and wild mouse strains (129/J, 129/SvJ, 129/Ola Hsd, C57BL/6NHsd, C57BL/6J, DBA/2J, Spret/Ei, and Cast/Ei), one hybrid strain (B6129F2/J, derived from the C57BL/6J and 129/J strains), and one outbred strain (CD-1). To test our ability to detect effects in a genetically modified mouse, we compared these data with those for a mouse lacking the gamma (neuronal) isoform of the protein kinase C gene (PKCgamma). We also assessed whether amputating the tail tip of mice (a standard method of obtaining tissue for genetic analysis) increased MAC (e.g., by sensitization of the spinal cord). MAC and convulsant 50% effective dose values differed modestly among strains, with a range of 17% to 39% from the lowest to highest values for MAC using conventional anesthetics, and up to 48% using the experimental anesthetic 1-chloro-1,2,2-trifluorocyclobutane. Convulsivity to the nonimmobilizer varied by 47%. Amputating the tail tip did not affect MAC. PKCgamma knockout mice had significantly higher MAC values than control animals for isoflurane, but not for halothane or desflurane, which implies that protein phosphorylation by PKCgamma can alter sensitivity to isoflurane. IMPLICATIONS: Anesthetic potency differs by modest amounts among inbred, outbred, wild, and laboratory mouse strains. Absence of the neural form of protein kinase C increases minimum alveolar anesthetic concentration for isoflurane, indicating that protein phosphorylation by the gamma-isoform of protein kinase C (PKCgamma) can influence the potency of this anesthetic.

The elimination of sodium and potassium hydroxides from desiccated soda lime diminishes degradation of desflurane to carbon monoxide and sevoflurane to compound A but does not compromise carbon dioxide absorption.

UNLABELLED: Normal (hydrated) soda lime absorbent (approximately 95% calcium hydroxide [Ca(OH)2], the remaining 5% consisting of a mixture of sodium hydroxide [NaOH] and potassium hydroxide [KOH]) degrades sevoflurane to the nephrotoxin Compound A, and desiccated soda lime degrades desflurane, enflurane, and isoflurane to carbon monoxide (CO). We examined whether the bases in soda lime differed in their capacities to contribute to the production of these toxic substances by degradation of the inhaled anesthetics. Our results indicate that NaOH and KOH are the primary determinants of degradation of desflurane to CO and modestly augment production of Compound A from sevoflurane. Elimination of these bases decreases CO production 10-fold and decreases average inspired Compound A by up to 41%. These salutary effects can be achieved with only slight decreases in the capacity of the remaining Ca(OH)2 to absorb carbon dioxide. IMPLICATIONS: The soda lime bases used to absorb carbon dioxide from anesthetic circuits can degrade inhaled anesthetics to compounds such as carbon monoxide and the nephrotoxin, Compound A. Elimination of the bases sodium hydroxide and potassium hydroxide decreases production of these noxious compounds without materially decreasing the capacity of the remaining base, Ca(OH)2, to absorb carbon dioxide.

Polyhalogenated methyl ethyl ethers: solubilities and anesthetic properties.

UNLABELLED: The several potent inhaled anesthetics released for clinical use in the past four decades have been halogenated ethers, and, with one exception, methyl ethyl ethers. In the present report, we detail some structural and physical properties associated with anesthetic potency in 27 polyhalogenated methyl ethyl ethers. We obtained new data for 22 compounds. We used response/nonresponse of rats to electrical stimulation of the tail as the anesthetic end point (i.e., we measured the minimum alveolar anesthetic concentration [MAC]). For compounds that did not produce anesthesia when given alone (they only produced excitation/convulsions), we studied MAC by additivity studies with desflurane. We obtained MAC values for 20 of 22 of the studied ethers, which gave products of MAC x oil/gas partition coefficient ranging from 1.27 to 18.8 atm, compared with a product of 1.82+/-0.56 atm for conventional inhaled anesthetics. Despite solubilities in olive oil and application of partial pressures predicted by the Meyer-Overton hypothesis to provide anesthesia, 2 of 22 ethers (CCIF2OCCIFCF3 and CCIF2OCF2CClF2) had no anesthetic (immobilizing) effect when given alone, did not decrease the anesthetic requirement for desflurane, and had excitatory properties when administered alone. As with other inhaled anesthetics, anesthetic potency seemed to correlate with both polar and nonpolar properties. These ethers, representing structural analogs of currently used clinical volatile anesthetics, may be useful in identifying and understanding the mechanisms by which inhaled anesthetics act. IMPLICATIONS: The several potent, inhaled, polyhalogenated methyl ethyl ether anesthetics released for clinical use in the past four decades seem to have specific useful characteristics that set them apart from other methyl ethyl ethers. Properties of this class of compounds have implications for the future development of anesthetics and the mechanisms by which they act.

Minimum alveolar anesthetic concentration of fluorinated alkanols in rats: relevance to theories of narcosis.

UNLABELLED: The Meyer-Overton hypothesis predicts that the potency of conventional inhaled anesthetics correlates inversely with lipophilicity: minimum alveolar anesthetic concentration (MAC) x the olive oil/gas partition coefficient equals a constant of approximately 1.82 +/- 0.56 atm (mean +/- SD), whereas MAC x the octanol/gas partition coefficient equals a constant of approximately 2.55 +/- 0.65 atm. MAC is the minimum alveolar concentration of anesthetic required to eliminate movement in response to a noxious stimulus in 50% of subjects. Although MAC x the olive oil/gas partition coefficient also equals a constant for normal alkanols from methanol through octanol, the constant (0.156 +/- 0.072 atm) is one-tenth that found for conventional anesthetics, whereas the product for MAC x the octanol/gas partition coefficient (1.72 +/- 1.19) is similar to that for conventional anesthetics. These normal alkanols also have much greater affinities for water (saline/gas partition coefficients equaling 708 [octanol] to 3780 [methanol]) than do conventional anesthetics. In the present study, we examined whether fluorination lowers alkanol saline/gas partition coefficients (i.e., decreases polarity) while sustaining or increasing lipid/gas partition coefficients, and whether alkanols with lower saline/gas partition coefficients had products of MAC x olive oil or octanol/gas partition coefficients that approached or exceeded those of conventional anesthetics. Fluorination decreased saline/gas partition coefficients to as low as 0.60 +/- 0.08 (CF3[CF2]6CH2OH) and, as hypothesized, increased the product of MAC x the olive oil or octanol/gas partition coefficients to values equaling or exceeding those found for conventional anesthetics. We conclude that the greater potency of many alkanols (greater than would be predicted from conventional inhaled anesthetics and the Meyer-Overton hypothesis) is associated with their greater polarity. IMPLICATIONS: Inhaled anesthetic potency correlates with lipophilicity, but potency of common alkanols is greater than their lipophilicity indicates, in part because alkanols have a greater hydrophilicity--i.e., a greater polarity.

Nonimmobilizers and transitional compounds may produce convulsions by two mechanisms.

UNLABELLED: Some inhaled compounds cause convulsions. To better appreciate the physical basis for this property, we correlated the partial pressures that produced convulsions in rats with the lipophilicity (nonpolarity) and hydrophilicity (polarity) of 45 compounds: 3 n-alkanes, 18 n-haloalkanes, 3 halogenated aromatic compounds, 3 cycloalkanes and 3 halocycloalkanes, 13 halogenated ethers, and 2 noble gases (He and Ne). In most cases, convulsions were quantified by averaging the alveolar partial pressures just below the pressures that caused and slightly higher pressures that did cause clonic convulsions (ED50). The ED50 did not correlate with hydrophilicity (the saline/gas partition coefficient), nor was there an obvious correlation with molecular structure. For 80% of compounds (36 of 45), the ED50 correlated closely (r2 = 0.99) with lipophilicity (the olive oil/gas partition coefficient). Perhaps because they block the effect of GABA on GABA(A) receptors, five compounds were more potent than would be predicted from their lipophilicity. Conversely, four compounds may have been less potent than would be predicted because they (like conventional inhaled anesthetics) enhance the effect of GABA on GABA(A) receptors. IMPLICATIONS: Nonimmobilizers and transitional compounds may produce convulsions by two mechanisms. One correlates with lipophilicity (nonpolarity), and the other correlates with an action on GABA(A) receptors.

Rat strain minimally influences anesthetic and convulsant requirements of inhaled compounds in rats.

UNLABELLED: We assessed the effect of rat strain on susceptibility to anesthesia and convulsions produced by inhaled compounds. We determined the minimum alveolar anesthetic concentration (MAC) of desflurane and nitrous oxide, and the convulsive 50% effective dose (ED50) of 1,2-dichlorohexafluorocyclobutane, flurothyl, and difluoromethyl-1-chlorotetrafluoroethyl ether in five strains (three inbred [Long Evans, Sprague-Dawley, and Wistar] and two outbred [Fischer and Brown Norway]). Strain had slight effects on anesthetic potency, the strains with the highest MAC values (Long Evans and Brown Norway) having values < or =28% greater than the strains with the lowest values (Sprague Dawley and Wistar). MAC for nitrous oxide correlated directly with MAC for desflurane as a function of strain. MAC for either desflurane or nitrous oxide correlated inversely with the convulsive ED50 of 1,2-dichlorohexafluorocyclobutane, but correlated poorly (and directly) with the convulsive ED50 of the remaining compounds. Convulsivity varied little as a function of strain (greatest difference 21%) and did not vary consistently as a function of strain. No consistent difference was seen between inbred versus outbred strains. IMPLICATIONS: Rat strain has a minimal effect on the potency of inhaled anesthetics or the convulsant activity of inhaled compounds. It seems that the sites acted on by inhaled compounds to produce anesthesia and convulsions are conserved across common rat strains.

Minimum alveolar concentrations of noble gases, nitrogen, and sulfur hexafluoride in rats: helium and neon as nonimmobilizers (nonanesthetics)

UNLABELLED: We assessed the anesthetic properties of helium and neon at hyperbaric pressures by testing their capacity to decrease anesthetic requirement for desflurane using electrical stimulation of the tail as the anesthetic endpoint (i.e., the minimum alveolar anesthetic concentration [MAC]) in rats. Partial pressures of helium or neon near those predicted to produce anesthesia by the Meyer-Overton hypothesis (approximately 80-90 atm), tended to increase desflurane MAC, and these partial pressures of helium and neon produced convulsions when administered alone. In contrast, the noble gases argon, krypton, and xenon were anesthetic with mean MAC values of (+/- SD) of 27.0 +/- 2.6, 7.31 +/- 0.54, and 1.61 +/- 0.17 atm, respectively. Because the lethal partial pressures of nitrogen and sulfur hexafluoride overlapped their anesthetic partial pressures, MAC values were determined for these gases by additivity studies with desflurane. Nitrogen and sulfur hexafluoride MAC values were estimated to be 110 and 14.6 atm, respectively. Of the gases with anesthetic properties, nitrogen deviated the most from the Meyer-Overton hypothesis. IMPLICATIONS: It has been thought that the high pressures of helium and neon that might be needed to produce anesthesia antagonize their anesthetic properties (pressure reversal of anesthesia). We propose an alternative explanation: like other compounds with a low affinity to water, helium and neon are intrinsically without anesthetic effect.

The effect of anesthetic duration on kinetic and recovery characteristics of desflurane versus sevoflurane, and on the kinetic characteristics of compound A, in volunteers.

UNLABELLED: This study documents the differences in kinetics of 2 h (n = 7) and 4 h (n = 9) of 1.25 minimum alveolar anesthetic concentration (MAC) of desflurane (9.0%) versus (on a separate occasion) sevoflurane (3.0%), both administered in a fresh gas inflow of 2 L/min. These data are extensions of our previous 8-h (n = 7) studies of these anesthetics. By 10 min of anesthetic administration, average inspired (F(I)) and end-tidal concentration (F(A)) (F(I)/F(A); the inverse of the more commonly used F(A)/F(I)) decreased to less than 1.15 for both anesthetics, with the difference from 1.0 nearly twice as great for sevoflurane as for desflurane. During all sevoflurane administrations, F(A)/F(I) for Compound A [CH2F-O-C(=CF2) (CF3); a vinyl ether resulting from the degradation of sevoflurane by Baralyme] equaled approximately 0.8, and the average inspired concentration equaled approximately 40 ppm. Compound A is of interest because at approximately 150 ppm-h, it can induce biochemical and histological evidence of glomerular and tubular injury in rats and humans. During elimination, F(A)/F(A0) for Compound A (F(A0) is the last end-tidal concentration during anesthetic administration) decreased abruptly to 0 after 2 h and 4 h of anesthesia and to approximately 0.1 (F(A) approximately 3 ppm) after 8 h of anesthesia. In contrast, F(A)/F(A0) for desflurane and sevoflurane decreased in a conventional, multiexponential manner, the decrease being increasingly delayed with increasing duration of anesthetic administration. F(A)/F(A0) for sevoflurane exceeded that for desflurane for any given duration of anesthesia, and objective and subjective measures indicated a faster recovery with desflurane. Times (mean +/- SD) to initial response to command (2 h 10.9 +/- 1.2 vs 17.8 +/- 5.1 min, 4 h 11.3 +/- 2.1 vs 20.8 +/- 4.8 min, 8 h 14 +/- 4 vs 28 +/- 8 min) and orientation (2 h 12.7 +/- 1.6 vs 21.2 +/- 4.6 min, 4 h 14.8 +/- 3.1 vs 25.3 +/- 6.5 min, 8 h 19 +/- 4 vs 33 +/- 9 min) were shorter with desflurane. Recovery as defined by the digit symbol substitution test, P-deletion test, and Trieger test results was more rapid with desflurane. The incidence of vomiting was greater with sevoflurane after 8 h of anesthesia but not after shorter durations. We conclude that for each anesthetic duration, F(I) more closely approximates F(A) with desflurane during anesthetic administration, F(A)/F(A0) decreases more rapidly after anesthesia with desflurane, and objective measures indicate more rapid recovery with desflurane. Finally, it seems that after 2-h and 4-h administrations, all Compound A taken up is bound within the body. IMPLICATIONS: Regardless of the duration of anesthesia, elimination is faster and recovery is quicker for the inhaled anesthetic desflurane than for the inhaled anesthetic sevoflurane. The toxic degradation product of sevoflurane, Compound A, seems to bind irreversibly to proteins in the body.

Ventilatory effects of the nonimmobilizer 1,2-dichlorohexafluorocyclobutane (2N) in swine.

UNLABELLED: Nonimmobilizers (inhaled compounds that do not suppress movement in response to a noxious stimulus) resemble anesthetics in their capacity to suppress memory, but unlike anesthetics, they can cause convulsions. Higher concentrations of nonimmobilizers may cause death, even with apparent suppression of convulsions by the concurrent administration of conventional inhaled anesthetics. We hypothesized that nonimmobilizers can depress ventilation and can cause death by adding to the depression of ventilation produced by conventional anesthetics. To test these hypotheses, we administered 1,2-dichlorohexafluorocyclobutane (2N) to four pigs anesthetized with desflurane. The addition of 2N decreased PaCO2 and tended to increase the slope of the ventilatory response to imposed increases in PETCO2. Limited results from study of two other nonimmobilizers (2,3-dichlorooctafluorobutane and perfluoropentane), in two pigs each, were consistent with the findings for 2N. However, experimental limitations (e.g., toxicity of 2,3-dichlorooctafluorobutane, and hypoxia from perfluoropentane) confound interpretation of these latter results. Our findings do not support our hypotheses--2N (and presumably all nonimmobilizers) seems to be a respiratory stimulant, not a depressant. IMPLICATIONS: A new class of inhaled compounds, nonimmobilizers, allow tests of how inhaled anesthetics act. Nonimmobilizers may act like anesthetics (e.g., impair learning) or may not (e.g., do not prevent movement in response to a noxious stimulus). The present work shows that, unlike anesthetics,nonimmobilizers do not depress breathing.

In rats breathing from a nonrebreathing system, substitution of desflurane for isoflurane toward the end of anesthesia incompletely restores the time of recovery toward that of desflurane.

UNLABELLED: The lower solubility of desflurane allows a more rapid emergence from anesthesia than after anesthesia with the more soluble but less expensive anesthetic, isoflurane. Some practitioners use isoflurane for maintenance of anesthesia, crossing over to desflurane later in maintenance in an attempt to combine the cost-effectiveness of isoflurane with the rapid emergence from desflurane. We hypothesized that this maneuver would not accomplish its goals. Twenty-four male Sprague-Dawley rats received 1.2 minimum alveolar anesthetic concentration (MAC) of desflurane for the final 15, 30, or 60 min of a 2-h, 1.2-MAC isoflurane anesthetic in a nonrebreathing anesthesia system. We measured the time from cessation of anesthetic administration to the time each rat righted himself twice. Immediately after righting for the second time, we tested each rat's ability to remain atop a rotating rod (Rota-Rod) for 60 s continuously. Early (righting reflex) and late (Rota-Rod) recovery occurred more rapidly (P < 0.001) after 120 min of anesthesia with desflurane alone than after 120 min of anesthesia with isoflurane alone. A cross-over period of 30 min or longer produced a righting reflex time that did not differ from that found with desflurane alone, but a 15-min cross-over did not. Progressively longer cross-over periods led to proportionally better Rota-Rod performance, but no cross-over duration produced the rapidity of recovery seen with desflurane alone. We concluded that in a nonrebreathing system, switching to desflurane during the last 30 min of anesthesia substantially improved early recovery but produced a much smaller improvement in later recovery. IMPLICATIONS: The newer inhaled anesthetics offer the advantage of lower solubility, and thus more rapid emergence from anesthesia, than do the older inhaled anesthetics. However, they can be more expensive to use. This study demonstrates that substituting the newer anesthetic, desflurane, toward the end of anesthesia for an older anesthetic of greater solubility, isoflurane, does not produce recovery comparable to that of desflurane alone. Furthermore, this technique can be more costly than using desflurane throughout anesthesia.

Dehydration of Baralyme increases compound A resulting from sevoflurane degradation in a standard anesthetic circuit used to anesthetize swine.

UNLABELLED: In a model anesthetic circuit, dehydration of Baralyme brand carbon dioxide absorbent increases degradation of sevoflurane to CF2=C(CF3)OCH2F, a nephrotoxic vinyl ether called Compound A. In the present study, we quantified this increase using "conditioned" Baralyme in a circle absorbent system to deliver sevoflurane anesthesia to swine. Mimicking continuing oxygen delivery for 2 days after completion of an anesthetic, we directed a conditioning fresh gas flow of 5 L/min retrograde through fresh absorbent in situ in a standard absorbent system for 40 h. The conditioned absorbent was subsequently used (without mixing of the granules) in a standard anesthetic circuit to deliver sevoflurane to swine weighing 78 +/- 2 kg. The initial inflow rate of fresh gas flow was set at 10 L/min with the vaporizer at 8% to achieve the target end-tidal concentration of 3.0%-3.2% sevoflurane in approximately 20 min. The flow was later decreased to 2 L/min, and the vaporizer concentration was decreased to sustain the 3.0%-3.2% value for a total of 2 h (three pigs) or 4 h (eight pigs). Inspired Compound A increased over the first 30 +/- 60 min to a peak concentration of 357 +/- 49 ppm (mean +/- SD), slowly decreasing thereafter to 74 +/- 6 ppm at 4 h. The average concentration over 2 h was 208 +/- 25 ppm, and the average concentration over 4 h was 153 +/- 19 ppm. Pigs were killed 1 or 4 days after anesthesia. The kidneys from pigs anesthetized for both 2 h and 4 h showed mild inflammation but little or no tubular necrosis. These results suggest that dehydration of Baralyme may produce concentrations of Compound A that would have nephrotoxic effects in humans in a shorter time than would be the case with normally hydrated Baralyme. IMPLICATIONS: The vapor known as Compound A can injure the kidney. Dehydration of Baralyme, a standard absorbent of carbon dioxide in inhaled anesthetic delivery systems, can cause a 5- to 10-fold increase in Compound A concentrations produced from the inhaled anesthetic, sevoflurane, given at anesthetizing concentrations in a conventional anesthetic system.

Effects of inhaled nonimmobilizer, proconvulsant compounds on desflurane minimum alveolar anesthetic concentration in rats.

UNLABELLED: Anesthetics depress the central nervous system, whereas nonimmobilizers (previously called nonanesthetics) and transitional compounds having the same physical properties (e.g., solubility in lipid) do not produce anesthesia (nonimmobilizers) or are less potent anesthetics than might be predicted from their lipophilicity (transitional compounds). Potential explanations for the absent or decreased anesthetic effect of nonimmobilizer and transitional compounds include the theories that the nonimmobilizers are devoid of anesthetic effect and that transitional compounds have a decreased capacity to produce anesthesia; that the effects of these compounds are not apparent because the concentrations examined are too low; or that anesthesia, or lack thereof, results from a balance between depression and excitation (all nonimmobilizer and transitional compounds produce convulsions). To examine these issues further, we tested the effect of various multiples of the convulsive 50% effective dose (ED50) of three nonimmobilizers and one transitional compound on the minimum alveolar anesthetic concentration (MAC) of desflurane in rats. The nonimmobilizer 2,3-dichlorooctafluorobutane (NI-1), from 0.7 to 1.1 times its convulsive ED50, increased the MAC of desflurane by 14%-27%, but at 1.6 times its convulsive ED50 caused no change in MAC; the nonimmobilizer 1,2-dichlorohexafluorocyclobutane (NI-2) did not change MAC at concentrations up to its convulsant ED50, but it increased MAC by 25% and 36% at 1.3 and 1.7 times its convulsant ED50, respectively. The nonimmobilizer flurothyl (NI-3) decreased the MAC of desflurane by 20% +/- 6% (mean +/- SD) at 0.5 times its convulsant ED50, but it caused no change at higher partial pressures (up to 7.8 times its convulsant ED50), and the transitional compound CF3CCl2-O-CF2Cl (T-1) significantly decreased MAC by 16% +/- 7% at 0.8 times its convulsant ED50, but the 6%-8% decreases in MAC at 0.4 and 1.6 times its convulsant ED50 were not significant. Thus, neither nonimmobilizer nor transitional compounds produced a consistent dose-related effect on the MAC of desflurane, and any changes were small. These results suggest that the excitation produced by transitional compounds or nonimmobilizers does not explain their limited ability or inability to produce anesthesia. The data are consistent with a decreased anesthetic efficacy of transitional compounds and the lack of efficacy of nonimmobilizers. IMPLICATIONS: Inhaled compounds that do not cause anesthesia (nonimmobilizers) are used to test theories of anesthetic action. Their use presumes that a trivial explanation, such as cancelling stimulatory and depressant effects, does not explain the absence of anesthesia. The present results argue against such an explanation.