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Synthesis of aminosterols and their derivatives
Synthesis of aminosterols and their derivatives ShaWlah,*
R. K. Singh,* Malik Jamaluddin,*H. Ogura,t and H. Takayanagit
*Steroid Research Laboratory. Department of Chemistry, Aligarh Muslim University, Aligarh, India; fSchoo1 of Pharmaceutical Sciences, Kitasato University, Minato-ku, Tokyo, Japan.
Reactions of steroidal epoxides such as 5,6ar-epoxyJa-cholestane (Z) and its 3@chloro (ZZ) and 3/?acetoxy (ZZZ)analogs with urea in dimethylformamide afforded 6/3-amino-Jar-cholestan-5-01 (IV-VI), 6P-amino-N-formyl-Sc-cholestan-5-01 along with the Sa-cholestaneJ,6@diol analog also afforded the N-carboxyl
(VII-IX), and 6j3-amino-N-amido-Sc-cholestan-5-01 (X-XZZ), (XZZZ-XV). In addition to these compounds, the 3/3-acetoxy derivative {XVZ). (Steroids 55:120-122, 1990)
Keywords: steroids; aminosterols; aminosterol derivatives
Introduction
The reports of the synthesis and nonhormonal biologic activities (such as tranquilizing, anticonvulsant, anesthetic, ant&rhythmic, and sedative) of aminosterols and their derivatives1-6 prompted us to synthesize these compounds. Different investigators use different routes to synthesize aminosterols. Most commonly, the oxirane ring is opened by sodium azide to give azido alcohols, which on reduction with lithium aluminum hydride produce aminosterols. In the present study, we attempted to synthesize these compounds by treating some of the steroidal epoxides in the cholestane series, such as 5,&-epoxySo-cholestane (I)7 and its 3p-chloro (ID8 and 3/3acetoxy (III)9 analogs, with urea and obtained some interesting compounds. The structures of the compounds obtained were established on the basis of their analytic and spectral data (Figures 1 and 2). Experimental Ail melting points are uncorrected. The infrared (IR) spectra were determined in Nujol with a Perkin-Elmer 237 spectrophotometer. Nuclear magnetic resonance (NMR) spectra were run in CDC& on a Varian A-60 D instrument with Me,$i as the internal standard. The mass spectra were measured on an AJMES-9 mass spectrometer. Thin-layer chromatography (TLC) Address reprint requests to Dr. Shaliullah, Steroid Research Laboratory, Department of Chemistry, Aligarh Muslim University, Aligarh 202 002, India. Received June 9, 1989; revised August 24, 1989.
120
Steroids, 1990, vol. 55, March
plates were coated with silica gel (60 to 120 mesh). A 20% aqueous solution of perchloric acid was used as a spraying agent. Light petroleum refers to a fraction of boiling point (bp) 60 to 80 C. Anhydrous sodium sulfate was used as the drying agent. Nuclear magnetic resonance values are given in ppm (s, singlet; d, doublet; dd, double doublet; br, broad; m, multiplet centered. Reaction of 5,6mepoxy-5cu-cholestane with urea: general procedure:
(I)
A mixture of 5,&-epoxy-5ar-cholestane (I) (2.5 g, 6.5 mmol) and urea (2 g, 32.5 mmol) (1: 5 mol) was dissolved in dimethylformamide (100 ml) and the solution was heated under retlux for 8 hours. The progress of reaction was monitored with TLC until all the starting material was consumed. After the completion of the reaction, the reaction mixture was poured into water and extracted with ether. The ethereal layer was washed with water several times to remove unreacted urea and dried over anhydrous sodium sulfate. The solvent was evaporated in a water bath to yield a residue in the form of an oily mass which was chromatographed over silica gel (75 g). Elution with petroleum ether/ether (15 : 1) yielded 6@mino-5o-cholestan-5-01 (IV) (0.380 g, 0.94 mmol, 14.55%), mp 137 C, vmax 3,480 (NH, OH), 1,280, and 1,040 cm-r (C-O). The NMR spectrum showed peaks at 6 4.4 (m, NH& 4.1 (s, OH, exchangeable with deuterium oxide), 3.4 (m, 6-H, W1/2 = 6 Hz), 1.1 (s, 19-H), 0.65 (s, 18-H), 0.85, and 0.77 (other methyl protons). Analysis calculated for C27HdsNO (M+ 403): C, 80.39; H, 12.16; N, 3.45. Found: C, 80.37; H, 12.14; N, 3.43. 8
1990 Butterworth Publishers
Table 1
Physical and analytical data of the products
Product
mp (C) 173
V
151-153
VIII
175-177
XI
XIV Vl
ProdUCt
Infrared spectra (Nujol) vmax (cm-9
Molecular formula
Analysis calculated
Found (%I
13.32
C&H~NOCl (M’ 437/439)
C, 74.65 H, 10.97 N, 3.20
73.94 10.94 3.14
V
C&H,NO,Cl (M+ 465/467)
C, 72.18 H, 10.31 N, 3.00
72.05 10.27 3.01
VIII
C~HaN202Cl (M’ 4801482)
c, 69.92 H, 10.19 N, 5.82
69.99 10.20 5.73
c27H4YO&l
c, 73.86 H, 10.71
73.82 10.61
C,HnNOs (M+ 461)
c, 75.48 H, 11.06 N, 3.03
C&Hs,NO, (M+ 489)
7.21
10.84
7.35
226-228
13.26
256-258
XII
Spectral data of the products
Yield 4%)
1258
200-203
IX
Table 2
7.69
10.77
4.46 (m, NH,), 4.3 (m, 3-H, W?/2 = 17 Hz), 3.5 (m, 6-H W112 = 6 Hz), 2.75 (8, OH)” ?.2-0.70t 8.1 (s, CHO), 4.9 (M. ~~~~~~H~H), 1,700 -NH*-CHO), 4.2 k OH!‘, (-NH-I&O), 1,236, 3.48 (m, 3-H, 6-H)‘ 1,210, 1,035 (C-0). 730 ?.?5-0.70t
3,590.3,445 (NH. OH), 1,230 and 1,050 (C-O), 730 (C-Cl)
(C-c%
XI
3,646, 3,466 (-NH, OH), 1,696, 1,515 (NHCONH2), 1,020 (C-O), 725 (C-Cl)
75.41 11.05 3.05
VI
3,466 (NH,OH),1,730
c, 73.61 H, 10.42 N, 2.86
73.63 10.40 2.81
IX
C&HwN20, (M’ 504
C, 71.42 H, 10.31 N, 5.55
71.21 10.21 5.32
XV
208”
7.52
C~HsoO,
C, 75.32 H, 10.82
75.21 10.75
XVI
Oil
10.12
&Hs,NOs (M+ 461)
C, 71.28 H, 10.09 N, 2.77
71.26 10.07 2.42
Nuclear magnetic resonance spectra (CDCI,/TMS) 6 (ppm)
y..l)# ?.290,?,040
XII
XVI
3,500(-NH and OH), 1,740 (OAC). 1,680, 1,546 (NH, CHO), 1,286 (acetate) and 1,040 (C-0) 3,466 (-NH, OH), 1,730 lCH&OO). 1,680 and 1,520 (-NHCONH,), 1,270, 1,050 (C-O) 3,480 I-NH. OH), 1,736 ~OAc),l,72O, WOW, 1,296, 1,036 (C-0)
6.5 lm, -NH*-CONH2), 4.15 (d, -NH-CO-N/&, J = 8 Hz), 4.3 (m, 3-H, W?/2 = 17 Hz), 3.6 (m, 6-H), 2.75 (s, OH)*, ?.?5-0.70t 5.2 (m, 3-H), W?/2 = 18 Hz), 4.24 (m, NH,), 4.0 (m. 6-H). 2.80 (s, OH)“, 2.0 (s, OAc), I.?-0.65t 8.1 (s, CHO), 5.2 (m, 3-H), W112 = 18 Hz), 4.9 (m, -NH*CHO), 3.9 (m. 6-H), 2.75 (s, -OH)*, 2.0 (s, OAc1, ?.?3-0.70t 5.15 (m, 3-H, W112 = 18 Hz), 4.73 (d, -NH-CO-NH2, J i 7 Hz), 4.2 (m, -NH*CONH2), 4.1 (m, 6-H). 2.4 (s, OH)*, 2.0 (s, OAc), l.l-0.65t 9.35 ibr, s. COOH), 5.2 (m, -NH*COOH1,4.86 (m. 3-H. W112 = 18 Hz), 4.2 (m, 6-H), 3.0 (s, OH)*, 2.0 (s, OAc), ?.?3-0.70t
l Exchangeable with deuterium oxide. t Angular and side-chain methyl protons.
3
(I) (II) (III)
3
3
(IV)
H
(VII)
H
Cl
(v)
Cl
(VIII)
Cl
WC
(VI)
OAC
H
Agur8
1
(lx)
OAC
Further elution with light petroleum ether/ether (10 : 1) furnished 6jWunino-N-formyl-Sac-cholestan-501 (VII) (0.220 g, 0.5 1 mmol, 7.88%), as shining crystals, mp 121 C, vmax 3,500 (-NH, OH), 1,700 and 1,535 (NHCHO), and 1,230 and 1,030 cm-’ (C-O). The NMR spectrum showed bands at 6 8.03 (s, CHO), 4.73 (m, NB-CHO; exchangeable with deuterium oxide), 3.5 (m, 6-H), 2.85 (s, OH, exchangeable with deuterium oxide), 1.1 (s, 19-H), 0.7 (s, M-H), 0.91, and 0.83 (other methyl protons). Analysis calculated for C,&NOZ @I+ 431): C, 7;;5; H, 11.36;N, 3.28. Found: C, 78.00; 11,11.34; N, .
.
Elution with light petroleum ether/ether (5 : 1) afforded 6@amino-N-amido-Sa-cholestan-5-01 (X), recrystallized from light petroleum (0.315 g, 0.71 mmol, 10.33%), mp 148 C, ~max 3,450 (NH, OH), 1,690 and 1,510 (NHCONH& and 1,235 and 1,045 cm-’ (C-O). The NMR spectrum gave peaks at 6 4.63 (m, NHCONHd, 4.15 (m, dH), 3.1 (s, OH, exchangeable with deuterium oxide), 1.0 (s, 19-H), 0.73 (s, 18-H), 0.92, and 0.86 (other methyl protons). Analysis calculated for C&H&&& (W 446): C, Steroids, 1990, vol. 55, March
121
Papers on the epoxide ring from the /?-face followed by transdiaxial ring opening, were responsible for the formation of the rest of the products (Figure 3). Different modes of hydrolysis of the amide group in compounds (X-XII) resulted in aminosterols (IV-VI), its N-formy1 (VII-IX), and N-carboxyl derivatives (XVI). Formation of N-carboxyl derivatives with epoxides (I) and (II) in traces cannot be ruled out. Scheme 1 illustrates the formation of the products. Figure 3
Acknowledgments The authors are grateful to Professors M. S. Ahmad and S. M. Osman, Ohioan, ~p~rnent of Chemis-
try, for necessary facilities and useful discussion. Financial assistance from CSIR (New Delhi), is gratefully acknowledged. References 1.
2. 3. (XII)
w.Tf R = H,
Cl,
OAc
Scheme 1
75.33; H, 11.21; N, 6.27. Found: C, 74.34; H, 11.20; N, 6.30. Further elution with light petroleum ether/ether (1: 1) provided Sa-cholestane-5,6p-did (XIII) recrystallized from light petroleum (0.170 g, 0.42 mmol, 6.51%), mp 122 to 123 C (reported,rO mp 125 to 127 C). Reactions of epoxides (II and III) with urea were performed under identical conditions (the same counts of reactant and reagent were used). Physical, analytic, and spectral data are given in Tables 1 and 2. Results and discussion It was suggested that the 6-N-amido derivatives (X-
XIII), which were initially formed due to attack of urea
122
Steroids, 1990, vol. 55, March
4. 5. 6. 7, 8.
9.
10. 11.
Butenandt A, ‘I’scheming K, Hanisch G (1935). A new substitute for the androsterone group. Chem her 68:2097--2102. Hewett CL. Savaae DS (1968). Aminosteroids part III. ‘2 and 3-amino-Sa&dro&tes: .I &em Sot C:l134-1140. Overbeek GA, Bonta IL (lP64). Steroids that act on the nervous system. hormonal Steroids 1:493-500. Baters E, Monroy G, Ringold HJ (1961). Steroids CLVII’ 6 aminoandrostanes. J Org Chem 2&878-880. Selye S (1%3). The steroids. In: Franks AWT (ed) Encycfopaedia of Endocrinology, Section 1. Montreal, Synoptic Charts IV, p. 30. Atkinson RM, Davis B, Pratt MA, Tomiah EG (1965). Action of some steroids on the central nervous system.of the mouse II. ~a~acolo~y. J Med Chem 8~426-427. Fieser LF, F&er M (1959). Oxidation. In: Steroids. Reinhold, New York, pp. 189-250. Shoppee CW, Bridge Water RJ, Jones DN, Summers GHR (1956). Steroids and Walden inversion, Part XxX111. The configurations of the coprostanyl halides. J Chem Sot 2492249P. Henbest HB, Wrigley IT (1957). Aspects of stereochemistry IX. Formation of ~uorohyd~ns from the cholesteryl S,depoxides and boron trifluoride-ether complex. J Chem Sot 476% 4768. Reich H, Walker FE, Collins RW (1951). A4-Cholestene&one and related compounds. J Org Chem 16~1753-1760. Fieser LF, Rajagopalan S (lP49). Selective oxidation with Nbromosuccinimide II. Cholestane-3~,5a,6&triol. J Am Chem sot 7l:3938-3941.
R. K. Singh,* Malik Jamaluddin,*H. Ogura,t and H. Takayanagit
*Steroid Research Laboratory. Department of Chemistry, Aligarh Muslim University, Aligarh, India; fSchoo1 of Pharmaceutical Sciences, Kitasato University, Minato-ku, Tokyo, Japan.
Reactions of steroidal epoxides such as 5,6ar-epoxyJa-cholestane (Z) and its 3@chloro (ZZ) and 3/?acetoxy (ZZZ)analogs with urea in dimethylformamide afforded 6/3-amino-Jar-cholestan-5-01 (IV-VI), 6P-amino-N-formyl-Sc-cholestan-5-01 along with the Sa-cholestaneJ,6@diol analog also afforded the N-carboxyl
(VII-IX), and 6j3-amino-N-amido-Sc-cholestan-5-01 (X-XZZ), (XZZZ-XV). In addition to these compounds, the 3/3-acetoxy derivative {XVZ). (Steroids 55:120-122, 1990)
Keywords: steroids; aminosterols; aminosterol derivatives
Introduction
The reports of the synthesis and nonhormonal biologic activities (such as tranquilizing, anticonvulsant, anesthetic, ant&rhythmic, and sedative) of aminosterols and their derivatives1-6 prompted us to synthesize these compounds. Different investigators use different routes to synthesize aminosterols. Most commonly, the oxirane ring is opened by sodium azide to give azido alcohols, which on reduction with lithium aluminum hydride produce aminosterols. In the present study, we attempted to synthesize these compounds by treating some of the steroidal epoxides in the cholestane series, such as 5,&-epoxySo-cholestane (I)7 and its 3p-chloro (ID8 and 3/3acetoxy (III)9 analogs, with urea and obtained some interesting compounds. The structures of the compounds obtained were established on the basis of their analytic and spectral data (Figures 1 and 2). Experimental Ail melting points are uncorrected. The infrared (IR) spectra were determined in Nujol with a Perkin-Elmer 237 spectrophotometer. Nuclear magnetic resonance (NMR) spectra were run in CDC& on a Varian A-60 D instrument with Me,$i as the internal standard. The mass spectra were measured on an AJMES-9 mass spectrometer. Thin-layer chromatography (TLC) Address reprint requests to Dr. Shaliullah, Steroid Research Laboratory, Department of Chemistry, Aligarh Muslim University, Aligarh 202 002, India. Received June 9, 1989; revised August 24, 1989.
120
Steroids, 1990, vol. 55, March
plates were coated with silica gel (60 to 120 mesh). A 20% aqueous solution of perchloric acid was used as a spraying agent. Light petroleum refers to a fraction of boiling point (bp) 60 to 80 C. Anhydrous sodium sulfate was used as the drying agent. Nuclear magnetic resonance values are given in ppm (s, singlet; d, doublet; dd, double doublet; br, broad; m, multiplet centered. Reaction of 5,6mepoxy-5cu-cholestane with urea: general procedure:
(I)
A mixture of 5,&-epoxy-5ar-cholestane (I) (2.5 g, 6.5 mmol) and urea (2 g, 32.5 mmol) (1: 5 mol) was dissolved in dimethylformamide (100 ml) and the solution was heated under retlux for 8 hours. The progress of reaction was monitored with TLC until all the starting material was consumed. After the completion of the reaction, the reaction mixture was poured into water and extracted with ether. The ethereal layer was washed with water several times to remove unreacted urea and dried over anhydrous sodium sulfate. The solvent was evaporated in a water bath to yield a residue in the form of an oily mass which was chromatographed over silica gel (75 g). Elution with petroleum ether/ether (15 : 1) yielded 6@mino-5o-cholestan-5-01 (IV) (0.380 g, 0.94 mmol, 14.55%), mp 137 C, vmax 3,480 (NH, OH), 1,280, and 1,040 cm-r (C-O). The NMR spectrum showed peaks at 6 4.4 (m, NH& 4.1 (s, OH, exchangeable with deuterium oxide), 3.4 (m, 6-H, W1/2 = 6 Hz), 1.1 (s, 19-H), 0.65 (s, 18-H), 0.85, and 0.77 (other methyl protons). Analysis calculated for C27HdsNO (M+ 403): C, 80.39; H, 12.16; N, 3.45. Found: C, 80.37; H, 12.14; N, 3.43. 8
1990 Butterworth Publishers
Table 1
Physical and analytical data of the products
Product
mp (C) 173
V
151-153
VIII
175-177
XI
XIV Vl
ProdUCt
Infrared spectra (Nujol) vmax (cm-9
Molecular formula
Analysis calculated
Found (%I
13.32
C&H~NOCl (M’ 437/439)
C, 74.65 H, 10.97 N, 3.20
73.94 10.94 3.14
V
C&H,NO,Cl (M+ 465/467)
C, 72.18 H, 10.31 N, 3.00
72.05 10.27 3.01
VIII
C~HaN202Cl (M’ 4801482)
c, 69.92 H, 10.19 N, 5.82
69.99 10.20 5.73
c27H4YO&l
c, 73.86 H, 10.71
73.82 10.61
C,HnNOs (M+ 461)
c, 75.48 H, 11.06 N, 3.03
C&Hs,NO, (M+ 489)
7.21
10.84
7.35
226-228
13.26
256-258
XII
Spectral data of the products
Yield 4%)
1258
200-203
IX
Table 2
7.69
10.77
4.46 (m, NH,), 4.3 (m, 3-H, W?/2 = 17 Hz), 3.5 (m, 6-H W112 = 6 Hz), 2.75 (8, OH)” ?.2-0.70t 8.1 (s, CHO), 4.9 (M. ~~~~~~H~H), 1,700 -NH*-CHO), 4.2 k OH!‘, (-NH-I&O), 1,236, 3.48 (m, 3-H, 6-H)‘ 1,210, 1,035 (C-0). 730 ?.?5-0.70t
3,590.3,445 (NH. OH), 1,230 and 1,050 (C-O), 730 (C-Cl)
(C-c%
XI
3,646, 3,466 (-NH, OH), 1,696, 1,515 (NHCONH2), 1,020 (C-O), 725 (C-Cl)
75.41 11.05 3.05
VI
3,466 (NH,OH),1,730
c, 73.61 H, 10.42 N, 2.86
73.63 10.40 2.81
IX
C&HwN20, (M’ 504
C, 71.42 H, 10.31 N, 5.55
71.21 10.21 5.32
XV
208”
7.52
C~HsoO,
C, 75.32 H, 10.82
75.21 10.75
XVI
Oil
10.12
&Hs,NOs (M+ 461)
C, 71.28 H, 10.09 N, 2.77
71.26 10.07 2.42
Nuclear magnetic resonance spectra (CDCI,/TMS) 6 (ppm)
y..l)# ?.290,?,040
XII
XVI
3,500(-NH and OH), 1,740 (OAC). 1,680, 1,546 (NH, CHO), 1,286 (acetate) and 1,040 (C-0) 3,466 (-NH, OH), 1,730 lCH&OO). 1,680 and 1,520 (-NHCONH,), 1,270, 1,050 (C-O) 3,480 I-NH. OH), 1,736 ~OAc),l,72O, WOW, 1,296, 1,036 (C-0)
6.5 lm, -NH*-CONH2), 4.15 (d, -NH-CO-N/&, J = 8 Hz), 4.3 (m, 3-H, W?/2 = 17 Hz), 3.6 (m, 6-H), 2.75 (s, OH)*, ?.?5-0.70t 5.2 (m, 3-H), W?/2 = 18 Hz), 4.24 (m, NH,), 4.0 (m. 6-H). 2.80 (s, OH)“, 2.0 (s, OAc), I.?-0.65t 8.1 (s, CHO), 5.2 (m, 3-H), W112 = 18 Hz), 4.9 (m, -NH*CHO), 3.9 (m. 6-H), 2.75 (s, -OH)*, 2.0 (s, OAc1, ?.?3-0.70t 5.15 (m, 3-H, W112 = 18 Hz), 4.73 (d, -NH-CO-NH2, J i 7 Hz), 4.2 (m, -NH*CONH2), 4.1 (m, 6-H). 2.4 (s, OH)*, 2.0 (s, OAc), l.l-0.65t 9.35 ibr, s. COOH), 5.2 (m, -NH*COOH1,4.86 (m. 3-H. W112 = 18 Hz), 4.2 (m, 6-H), 3.0 (s, OH)*, 2.0 (s, OAc), ?.?3-0.70t
l Exchangeable with deuterium oxide. t Angular and side-chain methyl protons.
3
(I) (II) (III)
3
3
(IV)
H
(VII)
H
Cl
(v)
Cl
(VIII)
Cl
WC
(VI)
OAC
H
Agur8
1
(lx)
OAC
Further elution with light petroleum ether/ether (10 : 1) furnished 6jWunino-N-formyl-Sac-cholestan-501 (VII) (0.220 g, 0.5 1 mmol, 7.88%), as shining crystals, mp 121 C, vmax 3,500 (-NH, OH), 1,700 and 1,535 (NHCHO), and 1,230 and 1,030 cm-’ (C-O). The NMR spectrum showed bands at 6 8.03 (s, CHO), 4.73 (m, NB-CHO; exchangeable with deuterium oxide), 3.5 (m, 6-H), 2.85 (s, OH, exchangeable with deuterium oxide), 1.1 (s, 19-H), 0.7 (s, M-H), 0.91, and 0.83 (other methyl protons). Analysis calculated for C,&NOZ @I+ 431): C, 7;;5; H, 11.36;N, 3.28. Found: C, 78.00; 11,11.34; N, .
.
Elution with light petroleum ether/ether (5 : 1) afforded 6@amino-N-amido-Sa-cholestan-5-01 (X), recrystallized from light petroleum (0.315 g, 0.71 mmol, 10.33%), mp 148 C, ~max 3,450 (NH, OH), 1,690 and 1,510 (NHCONH& and 1,235 and 1,045 cm-’ (C-O). The NMR spectrum gave peaks at 6 4.63 (m, NHCONHd, 4.15 (m, dH), 3.1 (s, OH, exchangeable with deuterium oxide), 1.0 (s, 19-H), 0.73 (s, 18-H), 0.92, and 0.86 (other methyl protons). Analysis calculated for C&H&&& (W 446): C, Steroids, 1990, vol. 55, March
121
Papers on the epoxide ring from the /?-face followed by transdiaxial ring opening, were responsible for the formation of the rest of the products (Figure 3). Different modes of hydrolysis of the amide group in compounds (X-XII) resulted in aminosterols (IV-VI), its N-formy1 (VII-IX), and N-carboxyl derivatives (XVI). Formation of N-carboxyl derivatives with epoxides (I) and (II) in traces cannot be ruled out. Scheme 1 illustrates the formation of the products. Figure 3
Acknowledgments The authors are grateful to Professors M. S. Ahmad and S. M. Osman, Ohioan, ~p~rnent of Chemis-
try, for necessary facilities and useful discussion. Financial assistance from CSIR (New Delhi), is gratefully acknowledged. References 1.
2. 3. (XII)
w.Tf R = H,
Cl,
OAc
Scheme 1
75.33; H, 11.21; N, 6.27. Found: C, 74.34; H, 11.20; N, 6.30. Further elution with light petroleum ether/ether (1: 1) provided Sa-cholestane-5,6p-did (XIII) recrystallized from light petroleum (0.170 g, 0.42 mmol, 6.51%), mp 122 to 123 C (reported,rO mp 125 to 127 C). Reactions of epoxides (II and III) with urea were performed under identical conditions (the same counts of reactant and reagent were used). Physical, analytic, and spectral data are given in Tables 1 and 2. Results and discussion It was suggested that the 6-N-amido derivatives (X-
XIII), which were initially formed due to attack of urea
122
Steroids, 1990, vol. 55, March
4. 5. 6. 7, 8.
9.
10. 11.
Butenandt A, ‘I’scheming K, Hanisch G (1935). A new substitute for the androsterone group. Chem her 68:2097--2102. Hewett CL. Savaae DS (1968). Aminosteroids part III. ‘2 and 3-amino-Sa&dro&tes: .I &em Sot C:l134-1140. Overbeek GA, Bonta IL (lP64). Steroids that act on the nervous system. hormonal Steroids 1:493-500. Baters E, Monroy G, Ringold HJ (1961). Steroids CLVII’ 6 aminoandrostanes. J Org Chem 2&878-880. Selye S (1%3). The steroids. In: Franks AWT (ed) Encycfopaedia of Endocrinology, Section 1. Montreal, Synoptic Charts IV, p. 30. Atkinson RM, Davis B, Pratt MA, Tomiah EG (1965). Action of some steroids on the central nervous system.of the mouse II. ~a~acolo~y. J Med Chem 8~426-427. Fieser LF, F&er M (1959). Oxidation. In: Steroids. Reinhold, New York, pp. 189-250. Shoppee CW, Bridge Water RJ, Jones DN, Summers GHR (1956). Steroids and Walden inversion, Part XxX111. The configurations of the coprostanyl halides. J Chem Sot 2492249P. Henbest HB, Wrigley IT (1957). Aspects of stereochemistry IX. Formation of ~uorohyd~ns from the cholesteryl S,depoxides and boron trifluoride-ether complex. J Chem Sot 476% 4768. Reich H, Walker FE, Collins RW (1951). A4-Cholestene&one and related compounds. J Org Chem 16~1753-1760. Fieser LF, Rajagopalan S (lP49). Selective oxidation with Nbromosuccinimide II. Cholestane-3~,5a,6&triol. J Am Chem sot 7l:3938-3941.