Organic Syntheses, CV 6, 64
Submitted by R. S. Brinkmeyer, E. W. Collington, and A. I. Meyers
1.
Checked by R. E. Ireland and R. R. Schmidt, III.
1. Procedure
Methyl iodide, in high concentrations for short periods or in low concentrations for long periods, can cause serious toxic effects in the central nervous system. Accordingly, the American Conference of Governmental Industrial Hygienists
3 has set 5 p.p.m., a level which cannot be detected by smell, as the highest average concentration in air to which workers should be exposed for long periods. The preparation and use of
methyl iodide should always be performed in a well-ventilated fume
hood. Since the liquid can be absorbed through the skin, care should be taken to prevent contact.
A
1-l., three-necked, round-bottomed flask equipped with a 500-ml. dropping funnel (Note
1), a
mechanical stirrer, and an
argon inlet tube is charged with
80 g. (0.33 mole) of N,4,4-trimethyl-2-oxazolinium iodide (Note
2). The system is flushed with
argon;
150 ml. of dry tetrahydrofuran (Note
3) is added, and the stirred suspension is cooled in an
ice bath. Meanwhile, to a cooled solution of freshly prepared
2-methoxyphenylmagnesium bromide (0.414 mole) (Note
4) is added
150 g. (146 ml., 0.828 mole) of dry hexamethylphosphoric triamide (Note
5). This solution is then transferred under an
argon atmosphere to the
500-ml. dropping funnel with the aid of an
argon-pressurized siphon. The solution is slowly run into the cooled suspension, whereupon the methiodide salt dissolves. When the addition is complete, the reaction mixture is stirred at room temperature overnight.
The suspension is slowly poured into
600 ml. of saturated ammonium chloride solution which has previously been cooled to 10–15°, and the mixture is extracted with three
250-ml. portions of diethyl ether. Concentration of the combined extracts gives the crude addition product (Note
6), which is added to 200 ml. of ice-cold water and quickly acidified with cold
3 N hydrochloric acid. The acidic solution is rapidly extracted with
300 ml. of cold hexane, and the extract is discarded. The aqueous solution is then made basic by the addition of
aqueous 20% sodium hydroxide solution (Note
7), and the mixture is extracted with three
250-ml. portions of ether. Concentration of the combined ethereal extracts affords
70–75 g. of crude
oxazolidine (Note
8).
A
1-l., round-bottomed flask is charged with
72 g. of the crude oxazolidine in 600 ml. of water, and
201.6 g. (1.6 moles) of hydrated oxalic acid is added. The mixture is heated under reflux for 1 hour, cooled, treated with 600 ml. of water to dissolve precipitated
oxalic acid, and extracted with three
100-ml. portions of ether. The combined ethereal extracts are washed with
50 ml. saturated sodium hydrogen carbonate, dried over
anhydrous potassium carbonate, and concentrated, giving
30–35 g. of crude aldehyde. Distillation of this material at
70–75° (1.5 mm.) gives pure
o-anisaldehyde (
22.8–26.3 g.;
51–59%), m.p.
35.5–38° (Note
9).
2. Notes
1. The dropping funnel should be equipped so that the transfer of the Grignard reagent to it can be carried out under a positive
nitrogen pressure.
2.
4,4-Dimethyl-2-oxazoline is commercially available from Columbia Organic Chemicals, 912 Drake Street, Columbia, South Carolina, or may be prepared as follows. A
250-ml., three-necked flask is charged with
89.14 g. (1.001 mole) of 2-amino-2-methylpropanol and cooled in an
ice bath. The amine is carefully neutralized with
52.3 g. (1.25 mole) of 90.6% formic acid over a 1-hour period. A
magnetic stirring bar is added, the flask is fitted with a
short path distillation head, and the reaction mixture is placed in a
silicon oil bath which is rapidly heated to 220–250°. The azeotropic mixture of water and
oxazoline distills over a period of 2–4 hours and is collected in an ice-cooled flask containing
ether. The aqueous layer is separated, saturated with
sodium chloride, and extracted with three
50-ml. portions of ether. The combined ethereal extracts are dried over
potassium carbonate and filtered. The
ether is removed at 35–40° at atmospheric pressure, and
4,4-dimethyl-2-oxazoline is collected as the temperature rises above 85°, yielding
56.7–62.7 g. (
57–63%) of a colorless mobile liquid, b.p.
99–100° (758 mm.).
The checkers found that if the azeotropic mixture is distilled more slowly from the reaction mixture at a pot temperature of 175–195°, the yield is greatly reduced and large amounts of polymeric material are formed.
N,4,4-Trimethyl-2-oxazolinium iodide is prepared by adding
49.5 g. (0.500 mole) of 4,4-dimethyl-2-oxazoline to an excess of cold
methyl iodide (182 g., 78.2 ml., 1.28 moles) in a
500-ml. flask and stirring at room temperature under
argon for 20 hours. The light brown solid is suction filtered and dissolved in
350 ml. of dry acetonitrile. The methiodide salt is precipitated by the addition of
750 ml. of dry ether to this
acetonitrile solution. The purified salt is again suction filtered, and the white solid is washed with
250 ml. of dry ether and finally dried under vacuum, giving
96 g. (
80%) of the methiodide, m.p.
215° (dec.). The salt can be stored in an inert atmosphere without deterioration.
7. Ice may be added to keep the mixture cool during the neutralization.
9.
o-Anisaldehyde is commercially available from Aldrich Chemical Co. and Eastman Organic Chemicals, Eastman Kodak Co.
3. Discussion
This procedure illustrates a general method for the preparation of aryl, benzyl, alkynyl, and vinyl aldehydes.
9 Table I gives the aldehydes which have been prepared from the corresponding Grignard reagents by conditions similar to those described here.
TABLE I
ALDEHYDES FROM N,4,4-TRIMETHYL-2-OXAZOLINIUM IODINE
|
Grignard Reagent |
Aldehyde |
Yield, % |
|
C6H5MgBr |
C6H5CHO |
69 |
C6H5CH2MgCl |
C6H5CH2CHO |
87 |
C6H5CH=CHMgBr |
C6H5CH=CHCHO |
64 |
C6H5 CMgBr |
C6H5C CCHO |
51 |
2-CH3OC6H4MgBr |
2-CH3OC6H4CDO |
70a |
|
|
This method does not allow the formylation of aliphatic Grignard or organolithium reagents, since in these cases, the enhancement in base strength in the presence of
hexamethylphosphoric triamide produces side reactions due to proton abstraction.
The present method is simple, proceeds easily and in good yield. The starting materials are readily available. The method is of particular value for the ready preparation of C-1 deuterated aldehydes using the
2-deuterio-N,4,4-trimethyl-2-oxazolinium iodide.
9 Also, since
14C-labeled formic acid is routinely available, this provides easy access to isotopically labeled aldehydes.
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