DE1036256B - Process for the production of rhodanhydrins of the steroid series - Google Patents

Description

Process for the production of rhodanhydrins of the steroid series Rhodanhvdrine of the steroid series have not yet been described in the literature. One has Rhodan steroids have already been produced, but either halogenated steroids have been used used as starting materials and in these the halogen against the rhodan group Reaction with Alkalirhodaniden exchanged, or treated 3-ketosteroids under UV exposure with dirhodan. Neither method resulted in rhodanhydrins.

It has now been found that rhodanhvdrines can be obtained in a simple reaction the steroid series can be achieved by starting from steroid epoxies and this is treated with hydrofluoric acid, expediently in excess; here will split the epoxy bond with the addition of the rhodanic acid.

The starting materials here are epoxies of the steroid series, with the steroid molecule can be saturated or unsaturated and other substituents such as oxygen and / or hydroxyl groups and have a side chain on the carbon atom can carry. Preferably 9 ß, 11ß- and 5a, 6 a-Epoxy are used with the an excess of hydrofluoric acid. Here are formed predominantly 9a- and 6ß-Rhodansteroi, de. One can proceed in such a way that the thiocyanate acid in an inert organic solvent, in which the epoxy d is also dissolved, such as. B. ether, act on the epoxy leaves. This method is particularly suitable for easily split epoxies, such as B. the 5 a, 6 a-epoxies. However, it is more advantageous in a two-phase system to work. Concentrated, aqueous hydro thodanic acid (about 25%) for application to the steroid epoxide, which in an indifferent organic, with Water immiscible solvent, preferably a halogenated hydrocarbon, such as methylene chloride or chloroform, is dissolved. By shaking for several hours at Room temperature, expediently with exclusion of light and in a nitrogen atmosphere, the introduction of the rhodan residue is achieved.

This method offers an advantage over the use of essential hydrohalic acid the following advantages: a) better solubility of most steroid epoxides in the halogenated ones Hydrocarbons versus ethers; 1 »higher concentrations of aqueous hydrothodanic acid compared to what is possible in ether; c) the possibly sensitive steroid is being opposed to the single-phase method with non-steroids always kept separate from the acid, since Reaction only takes place in the phase interface. It is here with a bigger one Worked excess of concentrated, aqueous hydrohalic acid. Even though the highly concentrated, aqueous hydrofluoric acid is very decomposable (under other decomposition into hydrogen sulfide, hydrogen cyanide and formation of polyrhodane), The epoxide cleavage occurs only through the much stronger thiocyanate acid instead of. The formation of polyrhadane is reduced by working under nitrogen. The formed poly rhodan can easily be removed.

It has also been found that the breakdown of epoxides by steroids under particularly gentle conditions, this works with the rhodanic acids Salts of organic bases, predominantly tertiary bases such as pyridine, in a solvent heated to reflux. Here, the pyridinium rhodanide is also used in excess, z. B. 5 moles applied. As a solvent, for. B. alcohols, especially ethanol, Acetone and the like. But it can also be a tertiary base used for salt formation.

The splitting of simple aliphatic or cyclic alkylene oxides with ethereal hydrofluoric acid is known per se. Here were the alkylene oxides applied in excess and, after the reaction has ended, the excess oxide is distilled off. Apart from the fact that one cannot conclude from this that they are so complicatedly constituted and compounds accessible to various rearrangements, such as steroids, the well-known Method would be applicable, the method according to the invention differs precisely because the thiocyanate acid is used in excess here will; distilling off the epoxies, as provided by the known method, is involved the steroid compounds are out of the question anyway.

Because of the pharmaceutically interesting 6- and 9-positions , these pseudohalogen compounds according to the invention are of considerable interest both as such and as intermediate compounds for the introduction of -SH, -SS, -S-alkyl, -S 03H, -OH groups. The rhodanhydrins can also be converted into unsaturated rhodan steroids by splitting off water.

Example 1 6 ß-Rhodan-cholestan-3 ß, 5 a-diol 1.00 g of 5 x, 6-oxidocholestan-3 ß-ol are dissolved in 40 ml of methylene chloride and mixed with 13.5 ml of an ethereal solution of rhodanic hydrogen: (molar ratio of epoxide / acid = 1: 5). It is left to stand in the dark at room temperature for 48 hours. The organic phase is washed rhodanide-free and neutral with NaH C 03 solution and then with water and dried over Nag S 04. After the residue has been concentrated and triturated with acetone, 0.65 g of 6 ß-rhodan-cholestan-3 ß, 5 a-diol, which, after recrystallizing twice from ethyl acetate, melt at 183 to 184 ° C.

(The product recrystallized from acetone contains crystal acetone and melts at 176 to 177 ° C.) Analysis: C2. H47 02N S Calculated .... C 72.8, H 10.26, N 3.07, S 6.9%; found . ... C 73.1, H 10.3, N 3.05, S 6.5%. [a] D '= -51.8 (methylene chloride; d; c = 0.01) IR:.? ';'; ° '= 2.90 / 2.96 / 3.52 / 4.63 / 6.80-6.86 / 7.28 / 7.58 / 8 .08 / 8.65 / 8.95 / 9.30 / 9.70 / 9.95 / 10.35 / 10.88 / 13.48 p ..

Example 2 6 ß-Rhodan-cholestan-3 ß, 5 a-diol 7.50 g of 5 a, 6-oxidocholestan-3 ß-ol are dissolved in 200 ml of ethanol or in 150 ml of acetone or in 75 ml of pyridine and mixed with 10.6 g of pyridinium thiocyanate (molar ratio of epoxy / salt = 1: 5). In the case of the ethanolic or acetone solution, the mixture is heated for 3 hours Reflux to the boil while the pyridine solution is heated to 80 ° C. for 3 hours. The solvents are then possibly distilled off under reduced pressure; the residue is mixed with water and extracted with methylene chloride or chloroform. The organic phase is washed free of rhodanide or pyridine with water and dried over sodium sulfate. Yield = 5.35 g after recrystallization once from acetone; F. = 173 to 174 ° C.

Example 3 6 ß-Rhodan-cholestan-3 ß, 5 a-diol 2.00 g of 5 a, 6-oxidocholestan-3 ß-ol are dissolved in 100 ml of methylene chloride or chloroform and placed under nitrogen in the dark with 90 ml of an approximately 25% strength aqueous rhodanic hydrogen solution for 18 hours shaken at room temperature. Subsequently, the excess hydrothodanic acid blunted with solid sodium bicarbonate to a weakly acidic reaction; thereon It is useful to suck off the precipitated polyrhodane. After separating the organic Phase is extracted twice with methylene chloride, and the combined extracts are washed with sodium bicarbonate solution and water rhodanide-free and neutral and dries over Sodium sulfate.

Yield after trituration with acetone = 1.76 g; F. = 174 to 176 ° C. After recrystallization from ethyl acetate, the temperature rose to 183 to 184 ° C.

Example 4 9 α-Rhodan-11 β-hydroxy-17 α-methyltestosterone 1.50 g of 9β, 11-oxido-17a-methyltestosterone are dissolved in 75 ml of methylene chloride or chloroform and shaken with 60 ml of an approximately 25% aqueous rhodanic hydrogen solution under nitrogen in the dark for 18 hours at room temperature. The excess hydrothodanic acid is then truncated with solid sodium bicarbonate; the precipitated polyrhodane is expediently suctioned off. The organic and the aqueous phase are separated; then it is re-extracted with meth_vlenchlorid. In a customary work-up, the organic extracts are washed until neutral with sodium bicarbonate solution and water, free of rhodanide, and dried over sodium sulfate. The crude product is recrystallized from ethyl acetate; Yield 1.35 g, m.p. = 133 to 140 ° C.

By recrystallization from ethyl acetate and from acetone-hexane 0.68 g of 9a-rhodan-11 ß-hydroxy-17 a-methyltestosterone with a melting point of 148 ° to 149 ° C (decomposition) obtained.

Analysis: C21 H20 03 NS calculated. .. C 67.17, H 7.79, N 3.73, S 8.53%; found . . . . C 67.6, H 7.9, N 3.9, S 8.4 0/0. [a] D = -I-196 (acetone; c = 0.01) IR: R "= 2.92! 3.05 (shoulder) / 3.43 / 4.68 / 5.99 / 6.18 / 8.08 / 9.37 / 10.56 / 11.58 / 13.15 / -13.20p,. UV: e2'4'2 "'= 14910. Example s 9 a-Rhodan-hvdrocortisone-21-acetate 5.50 g of 9β, 11-oxido-d4-pregnen-17a, 21-diol-3,20-dione-21-acetate are dissolved in 275 ml of methylene chloride or chloroform and mixed with 220 ml of an approximately 25% strength aqueous rhodanic hydrogen solution Shaken in the dark under nitrogen for 18 hours at room temperature. The work-up corresponds to that given in Example 4. The crude product gives, rubbed with methanol, 3.66 g of crystalline 9a-rhodan-hydrocortisone-21-acetate (9a-rhodan-d'4-pregnen-11ß, 17a, 21-triol-3,20-dione-21 acetate); after recrystallizing twice from acetone / hexane, the compound melts with decomposition at 153 to 155 ° C.

A sample recrystallized again from glacial acetic acid shows otherwise the same physical and analytical data have a melting point of 165 to 167 ° C (decomposition).

Analysis: C24 H3106 N S Calculated C 62.40, H 6.78, O 2Q, 83, N 3.05, S 6.94%; found C62.0, H6.9, 0.21.0, N3.2, S6.7%. [a1 ö = -162.2 (methanol; c = 0.01) IR: / 4 @ y, Br = 2.82 / 2.88 / 3.40 / 4.67 / 5.72 / 5.80 / 5.97 / 6.18 / 7.27 / 8 .08 / 9.55 / 11.57 / 12.82 / 13.23 @ ,.

5 (r O Il L V: 8 = 1z = 15150.

To identify the Rhodanhydrin steroids was among other things the intense and sharp IR band at 4.63 to 4.68 #t was used.

The rhodanhydrin steroids described tend to add crystal solvents; Crystal acetone and crystal ethyl acetate were observed.

Example 6 5-Rhodan-allopregnan-3 ß, 6 ß-diol-20-one 1 g of 5 ß, 6-oxidopregnan-3 ß-ol-20-one are dissolved in 50 ml of methylene chloride or chloroform and shaken with 40 ml of a 25% aqueous rhodanic hydrogen solution for 17 hours at room temperature under nitrogen in the dark. The work-up corresponds to that given in Example 4; 1.3 g crude yield. The crude product crystallizes after trituration with hexane and a little acetone. After two recrystallization from ethyl acetate / hexane, 0.35 g of pure, crystalline product with a melting point of 161 to 162 ° C. (decomposition) is obtained. Analysis: C22 H33 03N S Calculated ... C67.46, H8.49, N3.57, S 8.19%; found .... C67.4, H8.6, N3.6, S8.2, 0/0.

[a] 18 = -1-14 ° (methylene chloride.; c = 0.01) IR = AKB = 2.96-299 @, (0H) / 4.67 p, (-SCN) / 5.88 @, (20 - CO).

Example ? 16 ß-Rhodan-Q5-pregnen-3 ß, 17 a-diol-20-one-3,17-diacetate 10g of 16 a, 17-oxido-Q5-pregnen-3 ß-ol-20-one-3-acetate are dissolved in 215 ml of glacial acetic acid and with a glacial acetic acid- rhodanic hydrogen solution (mixture of 10.7 g of 100% sulfuric acid, 130 ml of glacial acetic acid and 10 g dry sodium rhodanide) added within 20 minutes with vigorous stirring at room temperature; it is worked under flowing nitrogen. The mixture is then heated to a bath temperature of 100 to 105 ° C. for 11/2 hours with stirring. The mixture is cooled in an ice bath and stirred into plenty of ice water (about 2.5 l). The precipitated compound is filtered off with suction, washed thoroughly with ice water, dissolved in methylene chloride, filtered and dried over sodium sulfate. After concentration in vacuo, 11.8 g of crude compound are obtained.

The crude product (3-monoacetate) is crystallized twice from methanol or by simple partitioning between dimethyl sulfoxide / ether-hexane, pre-cleaned; the 17a O H group of the pre-cleaned product is marked with Acetic anhydride acetylated in the presence of p-toluenesulfonic acid. According to the usual Working up and recrystallizing twice from methanol gives 3.3 g of des 3,17-diacetate; F. = 235.5 to 237 ° C.

Analysis: C28 H35 05N S Calculated ... C65.96, H7.45, N2.96, S 6.77%; found . ... C 66.0, H 7.9, N 3.2, S 6.7 0/0. 1a] 18 = + 18 ° methylene chloride; c = 0.01) IR = A >> δ; = 4.67 #t (- S CN) / 5.78 #t (3 and 17-acetate; C = O) / 5.86 #t (shoulder) 20 - C0 / 8.03 8.18 #t (shoulder) acetate / 9.67 p, (acetate) / weak OH band at 2.95 #t. The concentrations given for the specific rotations c refer to [g / ml].

Claims (7)

PATENT CLAIMS: 1. A process for the production of rhodanhydrins of the steroid series, characterized in that a steroid epoxide is split with excess rhodanic acid or its salts of organic bases, preferably in the dark and in an inert atmosphere such as nitrogen. 2. Procedure according to claim 1, characterized in that the splitting of the epoxies in homogeneous system. 3. The method according to claim 1 and 2, characterized in that that the splitting of the dissolved in an inert organic solvent Makes epoxies with ethereal hydrofluoric acid. 4. The method according to claim 1 and 2, characterized in that the splitting is carried out with an alcoholic or acetone solution of hydrochloric acid salts of tertiary bases, such as Pyridine. 5. The method according to claim 1, characterized in that one splitting the epoxy in the inhomogeneous system. 6. The method according to claim 1 and 5, characterized in that steroid epoxies in an indifferent, organic, water-immiscible solvent with a large excess of a high percentage, aqueous hydrofluoric acid at room temperature in a nitrogen atmosphere be treated. 7. The method according to claims 1, 5 and 6, characterized in that that as organic, water-immiscible solvents halogenated hydrocarbons, such as methylene chloride or chloroform, can be used.