Chemical constituents of Simarouba versicolor

ARRIAGA, ANGELA M.C.; MESQUITA, ALDENOR C. DE; POULIQUEN, YVONE B.M.; LIMA, ROBERTO A. DE; CAVALCANTE, SERGIO H.; CARVALHO, MARIO G. DE; SIQUEIRA, JOSÉ A. DE; ALEGRIO, LEILA V.; BRAZ-FILHO, RAIMUNDO

doi:10.1590/S0001-37652002000300004

Abstracts

From the roots, stems and fruits of Simarouba versicolor (Simaroubaceae) were isolated quassinoids (3, 5-7), triterpenoids (8-14), a mixture of steroids (15-17), the flavonoid kaempferol (18) and the squalene derivative 11,14-diacetoxy-7,10; 15,18-diepoxy-6,19-dihidroxy-6,7,10,11,14,15,18,19-octahydrosqualene (19). Spectral data were used for structural characterization.

Simarouba versicolor; Simaroubaceae; quassinoids; triterpenoids; steroids; flavonoid; squalene derivative

Das raízes, galhos e frutos de Simarouba versicolor foram isolados quassinóides (3, 5-7), triterpenóides (8-14), uma mistura de esteróides (15-17), o flavonóide canferol (18) e o derivado esqualênico 11,14-diacetoxi-7,10;15,18-diepóxi-6,19-diidroxi-6, 7, 10.11, 14, 15, 18, 19-octaidroesqualeno (19). Dados espectrais foram usados para caracterização estrutural.

Simarouba versicolor; Simaroubaceae; quassinóides; triterpenóides; esteróides; flavonóide; derivado esqualênico

Chemical constituents of Simarouba versicolor

ANGELA M.C. ARRIAGA¹, ALDENOR C. DE MESQUITA¹, YVONE B.M. POULIQUEN¹,

ROBERTO A. DE LIMA², SERGIO H. CAVALCANTE², MARIO G. DE CARVALHO³,

JOSÉ A. DE SIQUEIRA³, LEILA V. ALEGRIO³ and RAIMUNDO BRAZ-FILHO⁴

¹Departamento de Química Orgânica e Inorgânica, Centro de Ciências,

Universidade Federal do Ceará, Cx. Postal 12200, 60021-970 Fortaleza, Ceará, Brasil

²Departamento de Química, Universidade Federal de Alagoas, Maceió, Alagoas, Brasil

³Departamento de Química - ICE, Universidade Federal Rural do Rio de Janeiro

Seropédica, Rio de Janeiro, Brasil

⁴Setor de Química de Produtos Naturais - LCQUI - CCT, Universidade Estadual do Norte Fluminense

28015-620 Campos, Rio de Janeiro, Brazil

Manuscript received on March 20, 2001; accepted for publication on December 3, 2001;

contributed by RAIMUNDO BRAZ-FILHO^* * Correspondence to: Raimundo Braz-Filho E-mail: braz@uenf.br Member of Academia Brasileira de Ciências

ABSTRACT

From the roots, stems and fruits of Simarouba versicolor (Simaroubaceae) were isolated quassinoids (3, 5-7), triterpenoids (8-14), a mixture of steroids (15-17), the flavonoid kaempferol (18) and the squalene derivative 11,14-diacetoxy-7,10; 15,18-diepoxy-6,19-dihidroxy-6,7,10,11,14,15,18,19-octahydrosqualene (19). Spectral data were used for structural characterization.

Key words: Simarouba versicolor, Simaroubaceae, quassinoids, triterpenoids, steroids, flavonoid, squalene derivative.

INTRODUCTION

Some species of the small family Simaroubaceae (28 genera containing 25 species of tropical and semitropical shrubs and trees) have furnished wood for construction and others have been used in folk medicine. In the last few years, the therapeutic purposes have increased because of its antimalarial, antiinflammatory, antileukemic, antifeedant, and antiviral activities (Engler and Prantl 1872). In Brazil, the Simaroubaceae family is represented by the genera Quassia and Picrolemma, in the Amazonian Region, Castela and Picrasma, in the south of the country, and Simaba, Simarouba and Picrolemma which are present throughout Brazil (Hall et al. 1983). Species of the genus Simarouba have been reported previously as bioproducers of anticancer, antiviral, antimalaric, antiinflammatory (Polonsky 1973), insecticide and amoebacide agents (Polonsky 1985). This latter species has been used in the traditional medicine and is very known in China and Mexico.

Epilupeol (1), four quassinoids (2-5) and b-sitosterol (15) were previously isolated from the leaves and stems of a specimen of Simarouba versicolor collected in the State of Paraná, Brasil (Ghosh et al. 1977).

The present paper deals with the isolation of the known quassinoids (3, 5-7), triterpenoids (8-14), a mixture of steroids (15-17), the flavonoid kaempferol (18) and a squalene derivative (19) from specimens of Simarouba versicolor collected in Cascavel (stems and fruits) and Pacatuba (roots) in the State of Ceará, in the northeastern of Brazil. This region has a very distinct climate, which is different from the place where the specimen was collected for the previous investigation. The structuresof the compounds reported in this paper were established on the basis of spectral data, including 2D NMR experiments of 19.

RESULTS AND DISCUSSION

The secondary metabolites isolated from Simarouba versicolor, known quassinoids(3, 5-7), triterpenoids (8-14), a mixture of steroids (15-17), the flavonoid kaempferol (18) and squalene derivative (19), were identified by their IR, MS, ¹H and ¹³C NMR data, including preparation of some acetyl derivatives (11a, 12a, 13a, 14a and 18a) and comparison with literature data (Merrien and Polonsky 1971, Connolly and McCrindle 1971, Polonsky et al. 1975, Kupchan and Lacadie 1975, Jolad et al. 1981, Suzuki et al. 1985, Hashimoto et al. 1988a,b). The characterization of the squalene derivative 19 involved additional results obtained by interpretation of homonuclear and heteronuclear 2D shift-correlated spectra facilitated by comparison with data reported in the literature (Itokawa et al. 1991, Morita et al. 1993). The compounds isolated from S. versicolor (Fig. 1) reported in this paper were previously obtained from plants classified in the same or other genera of Simaroubaceae or other families.

11-Acetylamarolide (3) was isolated from a specimen of S. versicolor collected in Paraná, state located in the South of Brazil (Ghosh et al. 1977).

Glaucarubinone (5) (Alves-de-Lima et al. 1983, Alves-de-Lima et al. 1984, Polonsky et al. 1975) and glaucarubin (6) (Mesquita et al. 1997, Polonsky et al. 1975) were previously obtained from Simarouba glauca (Buckingham 1994a).

2'-Actylglaucarubin (7) (Alves-de-Lima et al. 1984) and tirucalla-7,24-dien-3-one (8) (Alves-de-Lima et al. 1983, Siqueira et al. 1985) were reported as bioproducts from S. amara (Buckingham 1994b).

20,24 - Epoxy - 25 - hydroxydammaran - 3 - one (ocotillone, 9) (Alves-de-Lima et al. 1982, Siqueira et al. 1985) was reported in the literature as a constituent of Dipterus hispidus and Dryanobulanops spp., The CH-24 epimer, cabraleone, has been isolated from Cabralea polytricha (Buckingham 1994c). The relative configurations of carbon atoms C-20 and CH-24 of 9 were deduced by comparison of the chemical shifts of CH-24 (d_C 83.56) and CH₃-21 (d_C 23.75). The significant differences among values reported in the literature for these carbons (Fig. 2) in ocotillone [ 9: d_C 84.3 (CH-24) and d_C 23.3 (CH₃-21)] and cabraleone [24-epiocotillone: d_C 87.4 (CH-24) and d_C 26.3 (CH₃-21)], two CH-24 epimeric compounds (Tanaka and Yahara 1978), were used to characterize the compound isolated from S. versicolor as identical to 9. The lower chemical shifts of CH-24 (d_C 83.56) and CH₃-21 (d_C 23.75) observed in the ¹³C NMR spectrum of 9 when compared with the corresponding values of cabraleone (Fig. 2) can be explained by the reciprocal g-effects of these carbon atoms in 9.

24,25-Epoxy-23-hydroxytirucall-7-en - 3 - one (nilocitin, 10) (Alves-de-Lima et al. 1982, Siqueira et al. 1985) was previously isolated from Simaba cedron, Simaroubaceae (Vieira et al. 1998).

21,24-Epoxy-23,25-dihydroxytirucall-7-en-3 -one (bourjutinolone A, 11) (Siqueira et al. 1985) and 21,24-epoxy-3,23,25-trihydroxytirucall-7-ene (3-episapelin A, 12) (Siqueira et al. 1985) were also isolated from Simaba cedron, Simaroubaceae (Vieira et al. 1998), Trichilia hispida, Meliaceae (Jolad et al. 1981), Entandrophragma angolense and E. utile, Meliaceae (Okorie and Taylor 1977). The relative configurations of the stereogenic carbon atoms CH-23 and CH-24 of 11 were established by comparative analysis of the ¹³C chemical shifts 37.51 (CH-20), 70.06 (CH₂-21), 36.44 (CH₂-22), 64.57 (CH-23), 86.44 (CH-24) and 74.05 (C-25) and values described in the literature (Jolad et al. 1981, Vieira et al. 1998) for bourjutinolone A (11), in combination with the value of the coupling constant (J = 9.0 Hz) observed in the ¹H NMR spectra of 11 and its acetyl derivative 11a, as summarized in Figure 3. Analogous analysis using data obtained by ¹H NMR spectra of 12 and its acetyl derivative 12a (Fig. 4) was employed to identify episapelin A (12).

21,23-Epoxy-21 b,24,25-trihydroxytirucall- 7-en-3-one (13) and 21,23-epoxy-21 a,24,25-trihydroxytirucall-7-en-3-one (14) were isolated as a mixture, clearly recognizable by the signals observed in the ¹³C NMR spectrum at d_C 102.00/96.97 (13/14) and 83.50/78.70 (13/14) attributed to the methine carbons CH-21 and CH-23, respectively (Fig. 5). The lower chemical shifts of CH-21 (d_C 96.97) and CH-23 (d_C 78.70) in the epimer 14 (major component) can be explained by a g-effect on CH-23 by the hydroxyl group located at CH-21 and on CH-21 by the methine carbon CH-24 (Siqueira et al. 1985). Compound 14 was previously obtained from Samadera madagascariensis, Simaroubaceae (Merrien and Polonsky 1971), when it was mainly characterized through ¹H NMR spectral data. On the basis of the relative intensities of the signals corresponding to H-21 in the ¹H NMR spectrum the epimer 13 (minor component) was now estimated as < 10% in the mixture isolated from Simarouba versicolor.

The presence of steroids 15-17 in a mixture was mainly deduced by ¹³C NMR spectral data, which involved comparison with values reported in the literature (Blunt and Stother 1977, Chaurasia and Wichtl 1987). The peaks at m/z 414 ([M]⁺. of 15), 412 ([M]⁺. of 17) and 400 ([M]⁺. of 16) observed in the mass spectrum was also used for the identification of these compounds.

The flavonol kaempferol (18) obtained as its acetyl derivative ( 18a) (Arriaga et al. 1994) is frequently isolated of plants.

The number of linked hydrogens for each carbon signal of 19 (mp 149.8-153.2^oC) was deduced by comparative analysis of HBBD (30 singlet signals corresponding to 34 carbon atoms) and DEPT-¹³C NMR [signals corresponding to 8 quaternary carbons (including two carbonyl of acetyl groups at d_C 170.92 and 170.78, which were also suggested by IR spectrum), 5 representing 6 methine carbons (two sp² and four oxygenated), 10 methylene carbons and 9 representing 10 methyl carbons (two of acetyl groups at d_C 21.13 and 21.07, in accordance with the singlet signals observed in the ¹H NMR at d_H 2.03 and 2.04)] spectra (Table I). These data in combination with results obtained by ¹H NMR (1D and 2D ¹H-¹H-COSY) and by heteronuclear 2D ¹H-¹³C-COSY-ⁿJ_CH (n=1, direct correlation via one bond - HETCOR - ¹³C detected, conventional method; n=2 and 3, long-range spin-spin interaction - COLOC - ¹³C detected, conventional method) spectra and comparison with values reported in literature for eurylene (19) (Itokawa et al. 1991, Morita et al. 1993) were used to complete ¹H and ¹³C chemical shift assignments unambiguously. The differences observed in the comparison of the ¹³C chemical shifts (Table I) may be attributed to mistakes previously reported using CDCl₃ as solvent (Itokawa et al. 1991), which was also used in our experiments, or to a solvent effect when the comparative analysis involves data obtained in CDCl₃ and pyridine-d₅ (Morita et al. 1993), as summarized in Table I. The ¹³C NMR spectral data obtained in pyridine-d₅ (Morita et al. 1993) were used to eliminate the mistakes observed in the previous attribution when was used CDCl₃ (Itokawa et al. 1991). However, the mistakes corresponding to CH₃-25/CH₃-30 (d_C 17.58 and not 25.7 or 25.8), shielded as consequence of the g-effect attributed to CH₂-4/CH₂-21, and CH₃-1/CH₃-24 (d_C 25.24 and not 17.6 or 17.7), free of this g-effect, were maintained (Table I). On the basis of this g-effect, the ambiguous assignments may now be eliminated, as shown in Table I. The results obtained by ¹H-¹H-NOE difference spectra (Table I) were also used to confirm these data and to obtain stereochemical information on some stereogenic carbon atoms of 19. The absolute configuration of eurylene (19), mp 146-148^oC, [a]_D +4.32º, was established by X-ray analysis and Mosher's method (Itokawa et al. 1991, Morita et al. 1993).

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EXPERIMENTAL

GENERAL EXPERIMENTAL PROCEDURE

Melting points (mp) were measured on a Mettler (FP-52) micro-melting point apparatus and are uncorrected; IR spectra were recorded on a Perkin-Elmer 720 spectrophotometer; ¹H and ¹³C NMR spectra (1D and 2D) were run on Bruker AC-200 (¹H: 200 MHz; ¹³C: 50 MHz) and Varian XL 100 (¹H: 100 MHz; ¹³C: 25 MHz) spectrometers, using CDCl₃ and pyridin-d₅ as solvents; EIMS were recorded on Micro Mass instrument at 70 eV.

PLANT MATERIAL

The roots, stems and fruits of S. versicolor were collected in Pacatuba in 1981 and Cascavel in 1997, respectively, Ceará State, Brazil and were identified by Professors Afranio Fernandes and E. Nunes, Departamento de Biologia, Universidade Federal do Ceará (UFC), Fortaleza, Ceará, Brasil. A voucher specimen (number 20.795) has been deposited at Prisco Bezerra Herbarium, Departamento de Biologia, UFC.

EXTRACTION AND ISOLATION

Dry and powdered roots (480g) were extracted, at room temperature, with hexane and following with acetone. The residue obtained from the acetone extract, after evaporation of the solvent under vacuum, was chromatographed on a silica gel column to give the compounds 5 to 13, 19 and a mixture of the steroids 15, 16 and 17 (Alves-de-Lima et al. 1982, Alves-de-Lima et al. 1983, Alves-de-Lima et al. 1984, Siqueira et al. 1985).

The air-dried and powdered stems of S. versicolor (4.0 kg) were extracted with hot EtOH in a Soxhlet system. The organic layer was concentrated to give residue SVE (96.0g) which was filtered through 200g of silica gel 60 (Merck, 230-400 mesh) by elution with hexane, chloroform, ethyl acetate and methanol, furnishing after evaporation of the solvent SVH (13.4g), SVC (14.0g), SVAE (12.7g) and SVM (49.5g). SVH (7.5g) which were chromatographed over silica gel 60 (Merck, 230-400 mesh) column and eluted with hexane, chloroform and ethyl acetate. The fractions eluted with CH₃Cl/EtOAc mixture of increasing polarity, afforded 19 (50.0 mg, mp. 149.8-153.2^oC). SVC (5.6g) which was chromatographed over silica gel 60 (Merck, 230-400 mesh) column and eluted with hexane, chloroform and ethyl acetate mixtures of increasing polarity. The CH₃Cl/EtOAc (20%) fraction furnished 3 (50.0 mg, mp. 158.1-159.3^oC) after recrystallization from methanol. SVAE (7.0 g) was chromatographed over silica gel 60 (Merck, 230-400 mesh) using pure hexane, mixture of hexane and chloroform, chloroform, ethyl acetate and methanol as solvents. The fractions eluted with EtOAc afforded colorless crystals (30.0 mg) of 6 (mp. 240.6-241.6^oC).

The fruits (500.0g) were crushed and extracted with hot ethanol in a Soxhlet system. The organic layer was concentrated to give SVFE (11.8g). This residue was chromatographed on 100.0g silica gel 60 (Merck, 230-400 mesh) and eluted with hexane, chloroform, ethyl acetate and methanol to furnish SVFAE (9.0g) and SVFM (2.7g). SVFAE (3.2g) was acetylated with Ac₂O (32 mL) in the presence of pyridine (16 mL), at room temperature and stirred overnight. After the usual procedures, the product was extracted with Me₂O and chromatographed on a silica gel 60 (Merck, 230-400 mesh) column and eluted with hexane, chloroform, ethyl acetate and methanol. After recrystallization from MeOH, the CH₃Cl/EtOAc (10%) fraction furnished the acetyl derivative 17a (50.0 mg, mp. 182.6-185.0^oC).

ACKNOWLEDGMENTS

The authors are grateful to FUNCAP, FAPERJ and CNPq for grants and research fellowships; to Professor Afranio Fernandes and E. Nunes, Departamento de Biologia, Universidade Federal do Ceará (UFC), Fortaleza, Ceará, Brasil for the botanical identification and to Prof. E.R. Silveira for the NMR spectra recorded by the technician Daniel Esdras Uchoa (M.Sc.).

RESUMO

Das raízes, galhos e frutos de Simarouba versicolor foram isolados quassinóides (3, 5-7), triterpenóides (8-14), uma mistura de esteróides (15-17), o flavonóide canferol (18) e o derivado esqualênico 11,14-diacetoxi-7,10;15,18-diepóxi-6,19-diidroxi-6, 7, 10.11, 14, 15, 18, 19-octaidroesqualeno (19). Dados espectrais foram usados para caracterização estrutural.

Palavras-chave: Simarouba versicolor, Simaroubaceae, quassinóides, triterpenóides, esteróides, flavonóide, derivado esqualênico.

POLONSKY J. 1985. Quassinoid Bitter Principles II. Fortschr Chem Org Nat 47: 221-264.

ALVES-DE-LIMA R, CAVALCANTE SH, BRAZ-FILHO R AND ALEGRIO LV. 1982. Constituintes químicos de Simarouba versicolor Cięncia e Cultura 34 (supl.): 519-519.
ALVES-DE-LIMA R, CAVALCANTE SH, ALEGRIO LV, GERALDO-DE-CARVALHO M AND BRAZ-FILHO R. 1983. Constituintes químicos de Simarouba versicolor Cięncia e Cultura 35 (supl.): 447447.
ALVES-DE-LIMA R, CAVALCANTE SH, BRAZ-FILHO R; GERALDO-DE-CARVALHO M, SIQUEIRA PS AND ALEGRIO LV. 1984. Quassinóides de Simarouba versilcolor Cięncia e Cultura 36 (supl.): 541-541.
ARRIAGA AMC, MESQUITA AG AND BRAZ-FILHO R. 1994. Estudo químico dos frutos de Simarouba versicolor Livros de Resumos-SBQ: PN-85.
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HALL IH, LEE KH, IMAKURA Y, OKANO M AND JOHNSON A. 1983. Antiinflammatory Agents. III. Structure-activity relationships of brusatol and related quassinoids. J Pharm Sci 72: 1282-1284.
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KUPCHAN SM AND LACADIE JÁ. 1975. Dehydroailanthinone, a New Antileukemic Quassinoid from Pierreodendron kerstingii J Org Chem 40: 654-657.
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*

Correspondence to: Raimundo Braz-Filho

E-mail:

braz@uenf.br

Member of Academia Brasileira de Ciências

Publication Dates

Publication in this collection
09 Oct 2002
Date of issue
Sept 2002

History

Accepted
03 Dec 2001
Received
20 Mar 2001

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] ALVES-DE-LIMA R, CAVALCANTE SH, BRAZ-FILHO R AND ALEGRIO LV. 1982. Constituintes químicos de Simarouba versicolor Cięncia e Cultura 34 (supl.): 519-519.

[2] ALVES-DE-LIMA R, CAVALCANTE SH, ALEGRIO LV, GERALDO-DE-CARVALHO M AND BRAZ-FILHO R. 1983. Constituintes químicos de Simarouba versicolor Cięncia e Cultura 35 (supl.): 447447.

[3] ALVES-DE-LIMA R, CAVALCANTE SH, BRAZ-FILHO R; GERALDO-DE-CARVALHO M, SIQUEIRA PS AND ALEGRIO LV. 1984. Quassinóides de Simarouba versilcolor Cięncia e Cultura 36 (supl.): 541-541.

[4] ARRIAGA AMC, MESQUITA AG AND BRAZ-FILHO R. 1994. Estudo químico dos frutos de Simarouba versicolor Livros de Resumos-SBQ: PN-85.

[5] BLUNT JW AND STOTHER JB. 1977.13C NMR Spectra of Steroids - A Survey and Commentary. Org Magn Reson 9: 439-464.

[6] BUCKINGHAM J. ED. 1994a. Dictionary of Natural Products, Chapman & Hall, London, vol. 3, p. 2555. 1994b, Vol. 5, p. 5638. 1994c. Vol. 2, p. 2063.

[7] CHAURASIA N AND WICHTL M. 1987. Sterols and Steryl Glycosides from Urtica dioica J Nat Prod 50: 881-885.

[8] CONNOLLY JD AND MCCRINDLE R. 1971. Tetranortriterpenoids and Related Substances. Part III. The Constitution of Grandifoliolenone, an apo-Tirucallol Derivative from Khaya grandifoliola (Meliaceae). J Chem Soc (C): 1715-1718.

[9] ENGLER A AND PRANTL K. 1872. Simaroubaceae. Mart Fl Bras. Munchen 12: 198-202.

[10] GHOSH PC, LARRAHONDO JE, QUESNE PW AND RAFFAUF RF. 1977. Antitumor Plants. IV. Constituents of Simarouba versicolor J Nat Prod 40: 364-369.

[11] HALL IH, LEE KH, IMAKURA Y, OKANO M AND JOHNSON A. 1983. Antiinflammatory Agents. III. Structure-activity relationships of brusatol and related quassinoids. J Pharm Sci 72: 1282-1284.

[12] HASHIMOTO M, HARIGAYA H, YANAGIYA M AND SHIRAHAMA H. 1988a. A Short Step Synthesis of Teurilene. Stereocontrolled Sequential Double Cyclization of the C₃₀-tetraenetetraol to the Tandem Tetrahydrofuran System. Tetrahedron Letters 29: 5947-5948.

[13] HASHIMOTO M, YANAGIYA M AND SHIRAHAMA H. 1988b. Total Synthesis of meso-Triterpene Ether, Teurilene. Chem Letters: 645-646.

[14] ITOKAWA H, KISHI E, MORITA H, TAKEYA K AND IITAKA Y. 1991. Eurylene, a New Squalene-type Triterpene from Eurycoma longifolia Tetrahedron Letters 32: 1803-1804.

[15] JOLAD SD, HOFFMANN JJ, SCHRAM KH, COLE R, TEMPESTA MS AND BATES RB. 1981. Constituents of Trichilia hispida (Meliaceae). 4. Hispidols A and B, Two New Tirucallane Triterpenoids. J Org Chem 46: 4085-4088.

[16] KUPCHAN SM AND LACADIE JÁ. 1975. Dehydroailanthinone, a New Antileukemic Quassinoid from Pierreodendron kerstingii J Org Chem 40: 654-657.

[17] MERRIEN A AND POLONSKY J. 1971. The Natural Occurrence of Melianodiol and Its Diacetate in Samadera madagascariensis (Simaroubaceae): Model Experiments on Melianodiol Direct towards Simarolide. J C S Chem Commun: 261-262.

[18] MESQUITA AG, ARRIAGA AMC, OLIVEIRA FA AND BRAZ-FILHO R. 1997. Quassinóide de Simarouba versicolor Livros de Resumos-SBQ: PN-028.

[19] MORITA H, KISHI E, TAKEYA K, ITOKAWA H AND IITAKA Y. 1993. Squalene Derivatives from Eurycoma longifolia Phytochemistry 34: 765-771.

[20] OKORIE DA AND TAYLOR DAH. 1977. Triterpenes from seeds of Entandrophragma species. Phytochemistry 16: 2029-2030.

[21] POLONSKY J. 1973. Quassinoid Bitter Principles. Fortschr Chem Org Nat 30: 101-150.

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