DE1184764B - Process for the preparation of 3-acetyl-10- (3'-dialkylaminopropyl) -phenthiazines - Google Patents

Description

Process for the preparation of 3-acetyl-10- (3'-dialkylaminopropyl) -phenthiazines It is known that phenthiazine can be obtained on the nitrogen by means of basic groups Can substitute radicals if you phenthiazine in the presence of basic agents that able to replace the hydrogen atom of the imino group by alkali metal, with tertiary aminoalkyl halides. Here the implementation is customary in aromatic hydrocarbons, such as benzene, toluene or xylene, as solvents carried out at their boiling point.

Phenthiazines, which also have acetyl groups in the nucleus, have not been obtained in the above-mentioned way because of the known sensitivity of carbonyl compounds versus alkaline reagents under the reaction conditions mentioned a uniform reaction was not to be expected. In fact, it turns out that the Conversion of 3-acetylphenthiazine under the above reaction conditions to the desired, compounds substituted on the nitrogen by radicals containing basic groups succeeds only in unsatisfactory yield.

Surprisingly, it has now been found that 3-acetyl-10- (3 = dialkylaminopropyl) -phenthiazines of the general formula can be obtained in a simple manner and in high yields where B denotes a dimethylamino or diethylamino group, if 3-acetylphenthiazine is reacted with the corresponding 3-dialkylamino-1-halopropane in the presence of sodium amide at a moderately elevated temperature in dimethylformamide as solvent. The surprisingly smooth course of the reaction can be explained by the fact that the intermediate alkali compound of 3-acetylphenthiazine forms very quickly in dimethylformamide even at room temperature and is easily soluble in this solvent, so that the reaction with the corresponding 3-dialkylamino-l -halopropane takes place in a homogeneous medium and is consequently terminated in a short time even at a moderately elevated temperature.

If the dimethylformamide is replaced by the previously common solvents, like benzene, toluene or xylene, the reaction proceeds in a heterogeneous phase and requires higher reaction temperatures and longer reaction times, wherein the unreacted sodium amide contained in the reaction mixture on the acetyl group attacks and so preferably gives rise to undesirable by-products.

The replacement of the sodium amide by that in the technical literature as a condensing agent recommended when introducing basic side chains in the 1-position of phenthiazines Sodium ethylate does not lead to the desired temperature range in the claimed temperature range Implementation. When the reaction temperature is increased, undesirable effects also occur Side reactions such as condensation on the acetyl group with resinification.

In executing the new process, the reaction components combined in dimethylformamide as a solvent and a short time to 60 to 80 ° C heated. Particularly favorable results are obtained when working at room temperature from 3-acetylphenthiazine and sodium amide in dimethylformamide as solvent initially the sodium compound of 3-acetylphenthiazine and then the tertiary Aminoalkyl halide added at elevated temperature. Instead of the corresponding free 3-dialkylamino-1-halogenpropanes can also be used their salts, the excess of sodium amide necessary to neutralize the acid of the salt must be added.

The new process thus permits 3-acetyl-10- (3'-dialkylaminopropyl) -phenthiazines of the general formula given above, which are pharmacologically active as such or can be used as intermediate products for the construction of pharmaceuticals easy to manufacture and with high yields. example 1 3-Acetyl- (3'-dimethylaminopropyl) -phenthiazine In a solution of 12 g of 3-acetylphenthiazine 2.5 g finely powdered in 100 cc of dimethylformamide while stirring and cooling with ice water Sodium amide entered. The reaction mixture immediately turns brown-black and gradually becomes more viscous. After half an hour, the mixture is heated to 80 ° C. and at this temperature with further stirring a solution of 7.2 g of 3-dimethylamino-1-chloropropane added dropwise over the course of an hour. The mixture is stirred for a further 1/2 hour at 80 ° C. and distilled then - the solvent is removed in vacuo, the residue is taken up in dilute hydrochloric acid up and sucks off the unsolved. 3.2 g of almost pure 3-acetylphenthiazine are obtained in this way return. The aqueous solution is made alkaline with dilute sodium hydroxide solution and the separated oil is absorbed into ether. After drying and distilling off the Solvent leaves 10.5 g of a viscous red Ul, which is taken up in alcohol and is precipitated as acid oxalate with a small excess of oxalic acid. You get so 12.5 g of almost pure, yellowish colored acid oxalate of 3-acetyl-10- (3'-dimethylaminopropyl) -phenthiazine; F. 186 to 187C (from methanol). Yield: 85% of theory (taking into account of the recovered raw material).

Example 2 3-Acetyl-1- (3'-diethylaminopropyl) -phenthiazine `12 g of 3-acetylphenthiazine, 2.2 g of sodium amide and 9 g of 3-diethylamino-l-chloropropane are stirred in 50 cc of dimethylformamide at 80 ° for 1 hour C heated. Working up is carried out in the manner described in Example 1. 12 g of 3 - acetyl -1- (Y- diethylaminopropyl) - phenthiazine are obtained; Bp 245 to 250 ° C; acid oxalate F 145 to 146 C (from alcohol). In addition, 2.5 g of unchanged 3-acetylphenthiazine are recovered. Yield: 88% of theory (taking into account the recovered starting material).

Claims (2)

Claims: 1. Process for the preparation of 3-acetyl-10- (3'-dialkylaminopropyl) -phenthiazines of the general formula where B denotes a dimethylamino or diethylamino group, characterized in that 3-acetylphenthiazine is reacted with the corresponding 3-dialkylamino-1-halopropanes in the presence of sodium amide at a moderately elevated temperature in dimethylformamide as solvent. 2. The method according to claim 1, characterized by a reaction temperature of 60 to 80'C. Publications under consideration Published documents of Belgian patent No. 542 352; British Patent No. 731016, Journal of the American Chemical Society, Vol. 74, 1952, pp. 2273 and 2274.