JPS6354341A - Optical resolution process - Google Patents

Abstract

PURPOSE:To enable optical resolution of (+ or -)-alpha-ethylbenzylamine and (+ or -)-2- benzamidocyclohexanecarboxylic acid salt at a low cost, by preferentially crystallizing a pair of hardly soluble diastereomer salt from a supersaturated solution of the above compounds. CONSTITUTION:A supersaturated solution of (+ or -)-alpha-ethylbenzylamine (EBA) and (+ or -)-cis-2-benzamidocyclohexanecarboxylic acid (cis acid) salt is added with a small amount of a seed crystal of a hardly soluble diastereomer salt of either one of (+)-EBA.(-)-cis acid salt or (-)-EBA.(+)-cis acid salt to effect the preferential crystallization of the same kind of diastereomer salt. The obtained diastereomer salt is separated into a base and an acid using an alkali and an acid to obtain (+)-EBA and (-)-cis acid or (-)EBA and (+)-cis acid useful as an optical resolution agent for racemic acid or racemic base in high resolution efficiency and high optical purity.

Description

Detailed Description of the Invention (Industrial Application Field) The present invention relates to α-ethylbenzylamine (hereinafter abbreviated as EBA) and/or cis-2-penzamide cyclohexanecarboxylic acid (hereinafter abbreviated as eis acid). ) is related to the optical resolution method. EBA' is a compound produced exclusively by chemical synthesis methods, and its uses include:
The optically active form is expected to be used as an optical resolution agent for racemic acid. On the other hand, cis acid is a compound useful as an optical resolving agent for optical activity f, 1st function < racemic base, especially (
Since it is useful for the optical resolution of ±)-a-naphthylethylamine (JP-A-58-24545), it has been desired to develop a method to easily obtain its active form.

(Prior Art and Problems) Conventionally, as an optical resolution method for (±)-EBA, a method using l-malic acid as an optical resolution agent [A, J.

Little et al., Journal of Chemical Society, 336 (1940)],
Alternatively] a method using acetylbromo L-tyrosi [
H, D, DeWitt et al., Journal of American Chemical Society (J, Am, Chern-8oe,
), 73.5782 (, 1951 is reported,
However, these methods utilize naturally occurring and relatively easily available optically active acids as resolving agents, and in order to obtain pure optically active substances, it is necessary to repeat recrystallization, resulting in low yields. It also had some drawbacks, such as not being expensive. Conventionally, as a method for obtaining an activated form of eis acid, a method is known in which a benzylamine salt of eis acid is prioritized (Patent Publication No. 59-3470).

(Means for Solving the Problems) As a result of various studies to obtain optically active forms of (±)-EBA and (±)-cis acid, the present inventors found that (±)-EBA
The salt of BA and (±)-eis acid is a mixture of a pair of sparingly soluble salts, namely (+)-EBA, (-)-eis acid salt and (
-)-EBA was found to exist as a racemic mixture of (+)-eis acid jjK, and furthermore, from a supermodified solution of (±)-EBA and (±)-eis acid, (+)-EBA
l)-eis acid salt or (-)-EBA-(
The present inventors have discovered that a salt of EBA and eis acid with high optical purity can be obtained with high separation efficiency by preferentially crystallizing the Eit-soluble salt of the +)-eis acid salt, and have completed the present invention.

That is, the present invention provides (+)-EBA・(−)-eis acid from a solution containing (±)-EBA and (±)-eis acid.
This method is characterized by preferentially producing salts of acid or (-)-EBA/(+)-eis salts alternately. The produced salts are subjected to solid-liquid separation, and then these salts are liberated. (
+)-or (-)-EBA and (-)-or (+
)-eis acid and optically active EB.
This is an innovative separation method that allows A and cis acids to be obtained simultaneously, and according to this method, (±)-EBA and (±)
-Eis acid can be optically resolved smoothly, efficiently, and continuously, which is an excellent effect. Furthermore, the present invention provides that (+)-EBA, (-)-EBA and
, (+)-eis acid, and (-)-cis acid).

In carrying out the present invention, (±)-EBA at 4t
and (±)-cis acid, (+)-
EBA -(-)-cis acid salt or (-)-EBA
Although it is possible to apply a simple alternating first crystallization method in which seed crystals of -(+)-cis salts are inoculated, in addition,
For example, (±)-EBA (or (±)-cis acid)
When resolving (±)-EBA (or (±)-c
is acid), and at the same time, the (±)-eis acid (or (±)-EBA) used as the resolving agent was also optically resolved, resulting in an optically active cis acid in an amount greater than that used as the resolving agent. Simultaneous mutual optical separation is possible in which (or EBA) can be recovered. In the present invention, EBA and ci
In order to prepare a solution containing s-acid, solvents such as water, methanol, ethanol, 1-propanol, 2-propanol, acetone, and ethyl methyl ketone can be used alone or in combination. It is particularly preferable to use water, methanol, and 2-propanol, which are solvents that have a high solubility and are inexpensive. Also, (+)-EBA
・(-)-eis acid salt or (-)-EBA ・(+
)-Eis salt in solution, (±)-E
When only BA and (±)-eis acid are present in equimolar amounts,
Although it is necessary to inoculate seed crystals, EBA and EIS
When the concentration of at least one of the optically active acids is high, inoculation of seed crystals is not necessarily necessary. However, inoculation is generally preferable because it allows a highly optically pure, poorly soluble diastereomeric salt to be obtained more efficiently. Also, add (
±)-EBA and (±)-eis acid may be added as is in equimolar amounts, or (±)-EBA・(±)-ci
It may be added in the form of s-acid. Obtained in this way (
+)-EBA・(-)-cis acid salt or (-)-E
After recrystallizing BA-(+)-cis acid salt if necessary, it is treated with a water-soluble base, the liberated amine is extracted with an organic solvent, and then distilled to produce (+)-EBA or (-)-EBA is obtained.

In addition, cis acid that exists as an alkali salt in an aqueous solution is
By treating this aqueous solution with a mineral acid such as hydrochloric acid or sulfuric acid, a (-)-eis acid salt or a (+)-eis acid can be obtained. Next, the present invention will be explained in more detail with reference to Examples.

Example 1゜(±)-EBA-(±)-ci in 10 ml of methanol
2.60 g (6.8 mmol) of s-acid was added and heated to completely dissolve. After being left at room temperature and cooled to 40°C, 11 mg of seed crystals of (-)-EBA/(+)-cis acid salt ([α + 27.7° (c = 1, methanol)) were inoculated, and the temperature was kept at room temperature. After standing overnight at (20°C), the crystals that crystallized were filtered off. - as the second crystallization of O, 1,5 g (-)
-EBA(+)-eis acid salt was obtained. [α]D+
21.9° (c=1, methanol) 9 Addition of (±)-, EBA-(±)-eis acid salt 0.31 g to the mother liquor
was added and heated to completely dissolve. Leave at room temperature, 30°
After cooling to C (+)-EI3A・c)-cts
Acid tA seed crystal ([al ”,' -26,4° (c=
1. 10 mg of methanol) was inoculated and left overnight. The precipitated crystals were filtered to obtain 0.42 g of (+)-EBA-(-)-eis acid as the second crystallization. [Q]
D-2i, 8° (c=1, methanol) and the following similar operations were repeated to obtain the following results.

Number of crystallizations Crystallized salt Yield [α]p(e=1.
meta/-ru) 3rd time (-)-EBA=(+)-eis
Acid 0.40g + 23.8゜4th time (+
)-EBA-(-)-eis acid 0.32g
(+)-EB obtained by operation at -25.2° or more
A.(-)-cis acid salt 0.74g in methanol 6ml
Recrystallized from 0.32g of purified (+)-EBA・(-
)-eis acid salt was obtained. mp 182-188°C1[
α127 Q8.8° (c=1, methanol). By adding 0.8 ml of 1 N aqueous sodium hydroxide solution to this purified (+)EBA・(-)-cis acid salt, extracting with ether, and distilling off the solvent of the organic layer under reduced pressure, (+)-
94 mg of EBA was obtained. [Q]D+6.6° (c=1°, 5.99% ethanol), optical purity was 100%. After the ether extraction, concentrated hydrochloric acid was added to the aqueous layer to make it Bongo Red acidic.

By filtering the deposited precipitate, (-)-cis acid 0
．． 20g was obtained. rrxp 205-207°C1[α
] o −36.4° (c=1.99% ethanol), and the optical purity was 100%. In addition, by the same operation, from 0.55 g of crude (-)-EBA・(+)-eis acid salt to 0.
．． 35 g of purified (-)-EBA-(+)-cis acid salt was obtained. +27.4° (c=1, methanol).

[By releasing it by C+, (-)-EBA
116 mg, [o] 30-6.5° (C=2.99
% ethanol) optical purity 98%, and 0.22 g of (
+)-cis acid, mp202-205°C1[. ]”,
,' +35.6° (c = 0.8.99% ethanol), yielding an optical purity of 98%.

(blank below)

Claims (3)

[Claims] (1) Add a small amount of (+)-α to a supersaturated solution of a salt of an optical isomer mixture of α-ethylbenzylamine and an optical isomer mixture of cis-2-benzamidocyclohexanecarboxylic acid.
A sparingly soluble dia of either -ethylbenzylamine/(-)-cis-2-benzamide cyclohexanecarboxylate or (-)-ethylbenzylamine/(+)-cis-2-benzamide cyclohexanecarboxylate A seed crystal of a stereomer salt is inoculated to precipitate a diastereomer salt of the same type as the seed crystal, and then the diastereomer salt obtained is treated with an alkali and an acid to form (+)-α-ethylbenzylamine and (- An optical resolution method characterized by separating )-cis-2-benzamidocyclohexanecarboxylic acid or (-)-α-ethylbenzylamine from (+)-cis-2-benzamidocyclohexanecarboxylic acid. (2) (+)-α-ethylbenzylamine/(-)-cis-2-benzamide cyclohexanecarboxylate and (-)-α-ethylbenzylamine/(+)-cis-2
- The inoculations of benzamide cyclohexane carboxylic acid salts are carried out alternately, during which time (±)-α-ethylbenzylamine and (±)-cis-2-benzamide cyclohexane carboxylic acid are added to the solution. 1
Section method. (3) (±)-α-ethylbenzylamine and (±)-
In a solution containing cis-2-benzamidocyclohexanecarboxylic acid, (+)-α-ethyl bezylamine, (
-)-α-ethylbenzylamine, (+)-cis-2-
Benzamidocyclohexanecarboxylic acid or (-)-
The method according to claim 2, which is carried out by increasing the concentration of at least one of cis-2-benzamidocyclohexanecarboxylic acids.