Organic Syntheses, CV 3, 586
Submitted by V. Deulofeu and T. J. Guerrero.
Checked by Homer Adkins, Harold H. Geller, and Everett E. Bowden.
1. Procedure
A.
5-(3-Methoxy-4-hydroxybenzal)creatinine (I). In a
large Pyrex test tube (51 mm. outside diameter and 200 mm. long) is placed an intimate mixture of
11.3 g. (0.1 mole) of creatinine [Org. Syntheses Coll. Vol. 1, 172 (1941)] and
24 g. (0.16 mole) of vanillin. The tube is placed in an
oil bath, which is then heated to 170°, and the mixture is melted while it is constantly agitated (Note
1). The temperature of the mixture reaches 155° in about 10 minutes; reaction then begins, and water is evolved. After 3–5 minutes longer, evolution of water ceases, and the mixture solidifies. The tube is heated for 3 minutes more, and then it is removed from the bath and allowed to cool.
When the temperature has fallen to 50–60°,
50 ml. of ethanol is added and the mixture is heated gently by occasional immersion in the warm oil bath. The solid partially disintegrates and forms a suspension. The suspension is filtered, and the solid remaining in the tube is warmed with a second
50-ml. portion of ethanol. This operation is repeated until all the orange-colored condensation product has been transferred to the filter. The material on the filter is then washed with three successive 30-ml. portions of water at 60°.
After drying, the crude product weighs
24 g. (
95%), melts at
261–263°, and is suitable for use in the next step. A pure product, which melts at
273°, may be obtained by recrystallizing the crude material from
acetic acid.
B.
5-(3-Methoxy-4-hydroxybenzyl)creatinine (II). To a suspension of
24 g. (0.1 mole) of the crude condensation product in 150 ml. of water, contained in a
500-ml. beaker, there is added, with continuous agitation,
180 g. of 3% sodium amalgam (Note
2). The amalgam is added in six portion, at intervals of 5 minutes. The solid dissolves, and the initial orange-red color of the solution slowly fades as the reduction proceeds. With good agitation, decolorization is complete in 45–60 minutes, if the starting material is pure. When the crude condensation product is used, the color of the solution fades to a faint, but permanent, yellow tint, which should mark the end point of the reduction.
The solution is decanted from the
mercury and filtered from suspended impurities. The filtrate is stirred and is acidified with
hydrochloric acid to
pH 6.6,
phenol red being used as the indicator (Note
3). After standing for 2 hours at 0°, the mixture is filtered and the solid is washed with a little cold water and dried. The product (free base) is microcrystalline, weighs
17.5–18 g. (
72–74%), and usually melts at
167–169° (Note
4). After solidification from fusion, the substance melts at
226–228°. When recrystallized from water, the substance melts at
231–233°. The crude product may be used for the subsequent hydrolysis.
C.
N-Methyl-(3-methoxy-4-hydroxyphenyl)alanine (III). In a
2-l. round-bottomed flask (Note
5),
18 g. (0.07 mole) of the crude reduction product is refluxed for 12 hours with a solution of
180 g. of crystalline barium hydroxide in 270 ml. of water. The hot solution is diluted with 1.2 l. of water, and the
barium is precipitated by addition of
250–270 ml. of 6 N sulfuric acid (Note
6). The precipitated
barium sulfate is separated by centrifuging and washed with two 100-ml. portions of water; the combined water; solutions are evaporated under reduced pressure at 50° to a volume of about 50 ml. The acid solution is made alkaline to litmus by addition of about
10 ml. of a 12% solution of ammonium hydroxide in water. After standing for 24 hours at 0°, the mixture is filtered, and the solid is washed with cold water and dried. The yield is
12 g. (
74%) (Note
7). On rapid heating, the solid melts at
273–275°. When recrystallized from water, the substance melts at
276–278°. The crude product may be used for the next step.
D.
N-Methyl-3,4-dihydroxyphenylalanine (IV). In a
carbon dioxide atmosphere,
12 g. (0.05 mole) of the methoxy compound is boiled gently for 3 hours with
24 g. of red phosphorus and a mixture of
60 ml. of acetic anhydride and
60 ml. of hydriodic acid (sp. gr. 1.7). The
phosphorus is then removed by filtration and washed with
25 ml. of 50% acetic acid. The filtrates are combined and, in a current of
carbon dioxide, are evaporated to a syrup at 50° under 35 mm. pressure. A 60-ml. portion of warm water is then added, and the solution is evaporated as before. The residue is dissolved in 100 ml. of water, and dilute
ammonia (10% by volume) is added until the solution does not change Congo red paper to blue (Note
8). The mixture is allowed to stand for 2 hours at 0°, and then the white crystalline precipitate is filtered. The precipitate is washed on the funnel with a little water containing
sulfur dioxide, and is dried by washing with
ethanol and
ether. The product weighs
9.5 g. (
82%). When slowly heated it becomes slightly brown at 230° and melts at
282–283°; when rapidly heated it becomes slightly brown at 255–260° and melts at
290–292°.
This material may be purified by boiling 1 g. of it with 50 ml. of water containing
sulfur dioxide, filtering the solution, and keeping the filtrate at 0° for 24 hours. The purified product (
0.74 g.), when slowly heated, becomes slightly brown at 245° and melts at
287°; when rapidly heated it becomes slightly brown at 260° and melts at
298–300°.
2. Notes
1. Sometimes the evolution of water is too rapid, and there is excessive foaming. The reaction may be moderated by removing the tube from the oil bath.
2. The amalgam may be made by adding
5-mm. cubes of sodium (5.4 g.) to
175 g. of mercury, warmed to 30–40°, and contained in a
mortar or
Erlenmeyer flask. The mortar is covered with an asbestos board having a small hole in the center. The cubes of
sodium are fixed on the end of a pointed
glass rod and are quickly pushed through this hole beneath the surface of the
mercury. A more convenient method is described in Fieser,
Experiments in Organic Chemistry, 2nd Ed., 1941, D. C. Heath and Company, Boston, p. 419.
3. The solution becomes dark in color if allowed to stand overnight.
4. In some cases the melting point may be as low as 98°; but after melting and solidifying, the substance melts at
226–228°.
5. A large flask should be used, since the mixture foams during the hydrolysis.
6. An excess of acid must be added to make certain that all the amino acid is in solution.
7. The yield can be increased slightly by evaporation of the mother liquor.
8. If the solution is made too alkaline, colored impurities precipitate. Neutralization must be performed carefully since the end point to Congo red is reached just before the colored impurities precipitate.
3. Discussion
N-Methylaminoaromatic acids have been prepared by a variety of methods: by the reaction between
methylamine and an
α-bromo acid;
4 by condensing
methylhydantoin with aromatic aldehydes;
5 by condensation of
creatinine6 or
benzoyl sarcosine with aromatic aldehydes;
7 by methylation of the toluenesulfonyl derivative of the amino acid;
8 and by substituting
methylamine for
ammonia in the Strecker synthesis.
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