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.

Polyhalogenated and perfluorinated compounds that disobey the Meyer-Overton hypothesis.

Fourteen polyhalogenated, completely halogenated (perhalogenated), or perfluorinated compounds were examined for their anesthetic effects in rats. Anesthetic potency or minimum alveolar anesthetic concentration (MAC) was quantified using response/nonresponse to electrical stimulation of the tail as the end-point. For compounds that produced excitable behavior, and/or did not produce anesthesia when given alone, we determined MAC by additivity studies with desflurane. Nine of 14 compounds had measurable MAC values with products of MAC x oil/gas partition coefficient ranging from 3.7 to 24.8 atm. Because these products exceed that for conventional inhaled anesthetics (1.8 atm), they demonstrate a deviation from the Meyer-Overton hypothesis. Five compounds (CF3CCIFCF3, CF3CCIFCCIFCF3, perfluorocyclobutane, 1,2-dichloroperfluorocyclobutane, and 1,2-dimethylperfluorocyclobutane) had no anesthetic effect when given alone, had excitatory effects when given alone, and tended to increase the MAC for desflurane. These five compounds had no anesthetic properties in spite of their abilities to dissolve in lipids and tissues, to penetrate into the central nervous system, and to be administered at high enough partial pressures so that they should have an anesthetic effect as predicted by the Meyer-Overton hypothesis. Such compounds will be useful in identifying and differentiating anesthetic sites and mechanisms of action. Any physiologic or biophysical/biochemical change produced by conventional anesthetics and deemed important for the anesthetic state should not be produced by nonanesthetics.

Effect of n-alkane kinetics in rats on potency estimations and the Meyer-Overton hypothesis.

Neither lipophilicity nor vapor pressure of larger n-alkanes appear to correlate with their anesthetizing partial pressures in inspired gas. Such results suggest that the Meyer-Overton hypothesis and Ferguson's rule may not apply to these compounds. An alternative explanation might be that a large difference in inspired-to-arterial partial pressure exists, i.e., that the inspired partial pressure misrepresents the effective partial pressure. To test this explanation, we investigated the kinetics of five consecutive even-numbered n-alkanes (C2H6 to C10H22) in rats. The ratio of end-tidal-to-inspired (PA/PI), arterial-to-end-tidal (Pa/PA), and arterial-to-inspired (Pa/PI) partial pressures decreased with increasing carbon chain length, consistent with our separate finding that blood solubility increased. Using Pa/PI and the minimum inspired concentration (MIC) obtained previously, we calculated the true effective potency, minimum alveolar anesthetic concentration (MAC); of these n-alkanes as (Pa/PI)(MIC). This markedly improved, but did not perfectly correct, the correlation of MAC with lipid solubility (the Meyer-Overton hypothesis) and vapor pressure (Ferguson's rule). A coefficient of variation of 76.7% was found for the product of MAC and the olive oil/gas partition coefficient. More importantly, the correlation of the logarithm of MAC and oil solubility had a slope of -0.724 (i.e., deviated from -1.0), whereas the slope for eight conventional anesthetics was -1.046 (approached-1.0). These data imply that olive oil does not adequately mimic the nature of the anesthetic site of action of n-alkanes.

Anesthesia by n-alkanes not consistent with the Meyer-Overton hypothesis: determinations of the solubilities of alkanes in saline and various lipids.

Because deviations from the Meyer-Overton rule may provide insights into the attributes of the anesthetic site of action, we characterized the solubility of the n-alkanes in various hydrophobic solvents (n-tetradecane, olive oil, n-octanol, and lecithin) as well as saline using variations on standard techniques. Increasing alkane chain length correlated with a decrease in solubility in saline and an increase in solubility in the hydrophobic solvents. The product of solubility in the hydrophobic solvents x the partial pressure (in atmospheres) required to produce anesthesia (i.e., the Meyer-Overton rule) did not produce a constant for any one of these solvents. The means and standard deviations for the products were: tetradecane, 65 +/- 103; olive oil, 33 +/- 63; n-octanol, 64 +/- 129; and lecithin, 16 +/- 26. Thus, our data suggest that the n-alkanes (especially those longer than n-heptane) do not follow the Meyer-Overton rule.

The neuromuscular effects of desflurane, alone and combined with pancuronium or succinylcholine in humans.

The neuromuscular effects of desflurane administered alone were studied in ten healthy human volunteers aged 20-27 yr. Also, the dose-response relationships of pancuronium and succinylcholine in surgical patients during anesthesia with desflurane (n = 13) were compared to those during isoflurane anesthesia (n = 14). In the volunteers, we measured the mechanical response of the adductor pollicis muscle to stimulation of the ulnar nerve in a train-of-four (TOF) sequence at 2 Hz and at tetanic frequencies of 50, 100, and 200 Hz, each administered for 5 s. Amplitudes of the first response (T1) in each TOF sequence and the ratios of the fourth TOF response (T4) to the first were similar at 3, 6, and 9% desflurane and decreased significantly only at 12% (P less than 0.05). Desflurane concentrations of 3-12% caused tetanic fade (greater than 10% decrement in amplitude) at 50, 100, and 200 Hz. The addition of N2O and the duration of anesthetic exposure did not alter desflurane's neuromuscular effects. The only neuromuscular variable influenced by CO2 was T1 amplitude, which decreased as arterial CO2 tension (PaCO2) increased. The doses of pancuronium that depressed T1 amplitude by 50% (ED50) were similar during anesthesia with 1.25 MAC desflurane, 10.5 +/- 2.8 micrograms/kg (mean +/- SD) and 1.25 MAC isoflurane, 12.3 +/- 5.0 micrograms/kg. The ED50 doses of succinylcholine were similar during anesthesia with desflurane 132 +/- 76 micrograms/kg and isoflurane 123 +/- 36 micrograms/kg. We conclude that desflurane significantly depresses neuromuscular function and augments the action of pancuronium and succinylcholine to a degree similar to that of isoflurane.