Methoxyflurane, 2,2-dichloro-
1,1- difluoro-1-methoxyethane,is a colorless
liquid with a fruity odor. It is produced industrially
by the addition of methanol to 1,1-dichloro-
2,2-difluoroethylene in the presence of sodium
methoxide .
Methoxyflurane is used as a clinical anesthesia (inhalation).
2,2-Dichloro-1,1-difluoroethyl methyl ether is used as a lipid soluble anesthetic agent. It is a neuromuscular blocking agent given concurrently to get the desired degree of muscular relaxation. Further, it is a powerful analgesic agent.
Methoxyflurane is a very potent and highly lipid soluble anesthetic agent. Methoxyflurane causes deep sedation and it has been used as a patient controlled analgesic for painful procedures in children. Methoxyflurane is a significant respiratory depressant.
ChEBI: An ether in which the two groups attached to the central oxygen atom are methyl and 2,2-dichloro-1,1-difluoroethyl.
Into a reactor equipped with agitator and temperature control jacket is charged approximately 100 lb (about 3 lb mols) of methanol, technical. This methanol is used in excess, and so it is both a reactant and a solvent in the synthesis.
Approximately 1 US gallon of ion exchange resin beads wet with methanol is then added to the methanol. This is in the hydroxide form with at least 0.7 milliequivalent OH- per milliliter of wet beads. Approximately 190 lb of 1,1- dichloro-2,2-difluoroethylene (about 1.44 lb mols) is then added to the reactor and, within it, to the 100 lb of methanol through a sparge pipe while the beads are kept in suspension by agitation. Coolant is run through the jacket of the reactor during this addition because the reaction is exothermic. The temperature in the reaction medium is kept at 10° to 20°C, to prevent side reactions and to minimize losses of the dichlorodifluoroethylene, which boils at 17°C. Reaction time is affected by the rate of heat removal and the reaction normally takes from 4 to 8 hours, using the stated quantities and conditions. After the dichlorodifluoroethylene is added, the resin is checked for residual alkalinity. If the resin is alkaline to phenolphthalein, it is assumed to have been of sufficient capacity and is removed from the CH3OCF2CHCI2-methanol mixture. If it is not alkaline to phenolphthalein, additional resin is added to insure complete reaction.
Essentially the same procedure can be carried out, employing as alkali any strongly alkaline substance, such as caustic soda in methanol solution. Control of the reaction rate may be accomplished by the rate of the addition of reactants and the amount of cooling applied to the reaction mixture. Agitation is employed to insure efficient contact of the reactants.
After removal of the resin catalyst, the excess methanol is extracted out of the mixture using three separate water washes, suitably of 25 gallons each. The water layer is decanted off, leaving product as an immiscible organic layer, after each wash. The 2,2-dichloro-1,1-difluoroethyl methyl ether containing intolerable unsaturated impurities may be purified and stabilized by a treatment with oxidizing agents such as air, oxygen, ozone, peroxy compounds, or other similar oxidizing agents, with subsequent removal of the decomposition or oxidation products and distilling if desired.
Methoxyflurane (Penthrane) is the most potent inhalational
agent available, but its high solubility in tissues limits
its use as an induction anesthetic. Its pharmacological
properties are similar to those of halothane with some
notable exceptions. For example, since methoxyflurane
does not depress cardiovascular reflexes, its direct myocardial
depressant effect is partially offset by reflex
tachycardia, so arterial blood pressure is better maintained.
Also, the oxidative metabolism of methoxyflurane
results in the production of oxalic acid and fluoride concentrations
that approach the threshold of causing renal
tubular dysfunction. Concern for nephrotoxicity has
greatly restricted the use of methoxyflurane.
Methoxyflurane is a volatile liquid (bp=105°C) with a highblood:gas partition coefficient and thus a slow induction andprolonged recovery. Approximately 75% of the drug undergoesmetabolism yielding dichloroacetate, difluoromethoxyacetate,oxalate, and fluoride ions. The intrarenal inorganicfluoride concentration, as a result of renal defluorination, maybe responsible for the nephrotoxicity seen with methoxyflurane.Both the concentration of F- generated and the durationfor which it remained elevated were factors in the developmentof methoxyflurane nephrotoxicity. Methoxyfluranewas removed from the U.S. market in 2000 because of saferalternatives. Both isoflurane and enflurane produce less fluorideion upon metabolism than methoxyflurane.
Clear colorless liquid with a sweet fruity odor.
2,2-DICHLORO-1,1-DIFLUOROETHYL METHYL ETHER may be sensitive to prolonged exposure to light.
Methoxyflurane exhibited low to very lowacute toxicity via inhalation, slightly lowerthan that of ethrane. Oral toxicity was low tomoderate depending on the species. Inhala tion of its vapors at 1.5–2% by volumeconcentrations in air can cause anesthesia inhumans. The toxic symptoms are similar tothose of ethrane, and the target organs areprimarily the central nervous system, kidney,and liver. At subanesthetic concentrations of0.3–0.5% by volume in air, its exposure tohumans for 1 hour resulted in the onset oflow toxicity. The sites of biological effectswere in the kidney.
LC50 value, inhalation (mice): 17,500 ppm/2 hr
LD50 value, oral (mammals): 3600 mg/kg
The liquid may be an irritant to theeyes. The teratomeric properties of this com pound were observed in rats and mice. Thesymptoms were embryo deaths and develop mental abnormalities in the urogenital andmusculoskeletal systems.
No carcinogenic actions in animals orhumans have been reported. The histidinereversion–Ames test for mutagenicity wasinconclusive.
2,2-DICHLORO-1,1-DIFLUOROETHYL METHYL ETHER is combustible.
Methoxyflurane is seldom used because of its propensity to cause renal toxicity. It is
the most potent agent, and it has the highest solubility in blood. Induction
and recovery would be expected to be slow. Chemically, it is rather unstable, and as much as 50%
of an administered dose can be metabolized. Toxic metabolites significantly limit its utility as a
general anesthetic.
Veterinary Drugs and Treatments
Methoxyflurane is an inhalant anesthetic, but it is rarely used today
primarily due to its potential for causing nephrotoxicity, slow onset
of action (a short-acting barbiturate is often used as an induction
agent), and prolonged recovery time. However, it does produce
some muscle
relaxation and analgesia, even at relatively low concentrations
and can be administered without a precision vaporizer
as it will vaporize to a maximum of about 3%.