Org. Synth. 1925, 4, 49
DOI: 10.15227/orgsyn.004.0049
NICOTINIC ACID
Submitted by S. M. McElvain
Checked by J. B. Conant and B. B. Corson.
1. Procedure
In a 5-l. round-bottomed flask is placed 4 kg. (2816 cc.) of c.p. concentrated nitric acid (sp. gr. 1.42) (Note 1). To this is added, in 25-cc. portions, 210 g. (1.23 moles) of nicotine (Note 2). The addition should be made carefully in order that local heating may not occur and material be lost. After each addition of nicotine, the flask should be shaken in order to insure a homogeneous solution. The addition of the nicotine causes the temperature of the liquid to rise somewhat but not sufficiently to cause evolution of nitrogen dioxide. The flask is placed on a steam bath under a hood and heated until the liquid reaches a temperature of 70°. It is then removed and the reaction allowed to continue spontaneously (Note 3), sufficient heat being evolved to cause the liquid to boil. The boiling ceases after one hour, but the flask is replaced upon the steam bath for ten to twelve hours, during which time there is a more or less continuous evolution of oxides of nitrogen.
The contents of the flask are then poured into an evaporating dish and evaporated almost to dryness on the steam bath (about ten hours). The purification which follows is best carried out with the product of two runs such as have been described above.
After the evaporation of most of the liquid, the nicotinic acid nitrate from two runs is transferred to a 1.5-l. beaker, 400 cc. of distilled water is added (Note 4), and the mixture is heated until complete solution results. On cooling, the nicotinic acid nitrate separates as yellow granular crystals and is filtered off. To obtain it absolutely pure, it may be recrystallized in a way similar to that just described but with the use of animal charcoal. It contains one molecule of water of crystallization and has a melting point of 190–192° (corr.). The yield is 420–460 g. 83–91 per cent of the theoretical amount).
The 420–460 g. of crude nicotinic acid nitrate from two runs (not necessarily dry) is dissolved in 900 cc. of boiling water in a 3-l. beaker, and 800 g. of crystalline disodium phosphate (Na2HPO4 · 12H2O) is added with constant stirring. The resulting thick mixture is stirred and heated almost to boiling for five minutes and then allowed to cool. The mixture is finally chilled to 0° by an ice bath. It is well to stir occasionally during the crystallization to prevent the formation of too solid a cake of crystalline material. The nicotinic acid is filtered off upon a 15-cm. Büchner funnel and washed with three 100-cc. portions of cold water.
The yield is 260–300 g. of material containing a small amount of mineral salts but otherwise nearly pure. It can be purified further by recrystallization from 2.5 to 3.5 l. (Note 4) of hot water, 150–180 g. of material, which melts at 230–232° (corr.), being obtained. The yield of recrystallized material is 50–60 per cent of the theoretical amount, based upon the nicotine employed.
The recrystallization is the least satisfactory part of this procedure and involves the greatest apparent loss of material; the product before recrystallization is sufficiently pure for most purposes. By evaporation of the mother liquors, 40–45 g. of pure nicotinic acid may be obtained, making the total yield of pure material 190–225 g. (63–74 per cent of the theoretical amount); in addition, a small amount of somewhat less pure material is recovered (Note 5).
2. Notes
1.
Fuming
nitric acid, the use of which is advised in the literature, is not so convenient and gives no better results than concentrated
nitric acid.
2.
A product of 100 per cent purity gives no better results than does the crude 95 per cent material used in this experiment.
Care should be exercised in handling nicotine because of its high toxicity.
3.
If the
nicotine and
nitric acid mixture is merely placed on a steam bath and allowed to heat without control of the temperature, an occasional run will react violently, with loss of material.
4.
The amounts of solvent given for the various recrystallizations are those which result in the best yields, and it is advisable to follow them as closely as possible.
5.
Nicotinic acid hydrochloride may be obtained directly from the nitrate by heating on a steam bath
460 g. of crude nitrate with
1 l. of concentrated hydrochloric acid (sp. gr.
1.19). After six to eight hours, the evolution of gas ceases and the liquid is evaporated under diminished pressure. The dry salt is again treated with
500 cc. of hydrochloric acid and heated for five hours and then evaporated as before.
After the salt has been obtained again, it is dissolved in 400 cc. of hot water and the solution diluted with four times its volume of 95 per cent alcohol. Upon cooling and stirring, the hydrochloride, melting at 273–274°, is obtained in a yield of 245–250 g. (63–65 per cent of the theoretical amount). An additional quantity of 75–80 g. may be obtained from the mother liquors.
3. Discussion
Nicotinic acid can be prepared by oxidation of
nicotine with
nitric acid,
1 potassium permanganate2 or
chromic acid,
3 and by carbonation of the
lithium derivative made from 3-bromopyridine.
4
This preparation is referenced from:
Appendix
Chemical Abstracts Nomenclature (Collective Index Number);
(Registry Number)
oxides of nitrogen
disodium phosphate (Na2HPO4 · 12H2O)
lithium derivative made from 3-bromopyridine
alcohol (64-17-5)
hydrochloric acid (7647-01-0)
nitric acid (7697-37-2)
potassium permanganate (7722-64-7)
chromic acid (7738-94-5)
nitrogen dioxide (10102-44-0)
Nicotinic acid (59-67-6)
nicotine (22083-74-5)
nicotinic acid nitrate
Nicotinic acid hydrochloride (636-79-3)
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