Preliminary Communication

Transition-metal/Lewis acid free synthesis of acyl benzothiophenes via C-C bond forming reaction

Sarbani Pal¹, Mohammad Ashrafuddin Khan¹, P Bindu^1,2 and PK Dubey²

¹  Department of Chemistry, MNR Post Graduate College, Kukatpally, Hyderabad-500072, India

²  Department of Chemistry, JNT University, Kukatpally, Hyderabad-500072, India

Beilstein Journal of Organic Chemistry 2007, 3:35doi:10.1186/1860-5397-3-35

The electronic version of this article is the complete one and can be found online at: http://bjoc.beilstein-journals.org/content/3/1/35

Received:	29 September 2007
Accepted:	25 October 2007
Published:	25 October 2007

© 2007 Pal et al; licensee Beilstein-Institut
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

< previousfull textnext >

Abstract

A simple and single-step synthesis of 2- and 3-acyl substituted benzothiophenes has been described via environmentally benign acylation of benzothiophene with in situ generated acyl trifluoroacetates. Both aliphatic and aromatic carboxylic acids participated in trifluoroacetic anhydride/phosphoric acid mediated C-C bond forming reactions under solvent-free conditions affording acyl benzothiophenes in good overall yields.

Background

Benzothiophene derivatives possessing an acyl group as one of the substituents on the five-membered ring are of immense medicinal value because of their promising pharmacological properties. For example, Raloxifene, [2-(4-hydroxyphenyl)-6-hydroxybenzo[b]thien-3-yl] [4-[2-(1-iperidinyl)ethoxy]phenyl]-methanone hydrochloride (A, Figure 1), is representative of a class of compounds known as selective estrogen receptor modulators[1] (SERMs) that possess estrogen agonist-like actions on bone tissues and serum lipids while displaying potent estrogen antagonist properties in the breast and uterus. A most common example of SERM is tamoxifen which has been the therapy of choice in the endocrine treatment of all stages of hormone-dependent breast cancer and in the primary and secondary chemoprevention of breast cancer. Recently, raloxifene showed promising results in clinical trial and is expected to provide an alternative to current hormone replacement therapy (HRT) that has been causally linked to breast cancer.[2] Another compound B (Figure 1) was identified as a thrombin inhibitor that could be utilized in the chronic treatment of thrombotic disorders.[3] Apart from medicinal interest, acyl derivatives of benzothiophene have synthetic value and a variety of diversity based benzothiophene derivatives have been prepared using these compounds. [4-12]

While a number of methods are known for the synthesis of acyl benzothiophenes [13-20] many of them however, are only suitable for the preparation of certain specific compounds, namely, acetyl, propanoyl and benzoyl derivatives. Some of these syntheses require complicated reaction conditions e.g. the use of an expensive transition metal catalyst along with toxic carbon monoxide gas[13] or unstable diazo compounds,[18] or pyrophoric BuLi,[19,20] or a multistep synthesis of starting material.[14] The simplest and straightforward method for the synthesis of acyl benzothiophenes appeared to be the Friedel Crafts acylation reaction [21-24] which however, involved the use of excess AlCl₃ and led to the formation of environmentally harmful gaseous HCl. Moreover, this protocol involved i) the use of moisture-sensitive acyl chloride, ii) the use of a large volume of chlorinated solvent and iii) the generation of aluminium waste that needs to be disposed of. Additionally, formation of unidentified side products is very common in this reaction. Therefore, the use of this method especially in large scale preparation might present major drawbacks. To overcome these difficulties we, therefore, focused on the alternative methods available in the literature [25-30] that could be utilized for the straightforward preparation of acylated benzothiophene derivatives via C-C bond forming reactions as a key synthetic step. The use of mixed anhydrides of trifluoroacetic acid for aromatic acylation has been reported as a useful alternative to the Friedel-Crafts acylation process and a variety of aromatic and aliphatic carboxylic acids have been employed successfully. Encouraged by these results, we decided to adopt a similar strategy for the acylation of benzothiophene. We anticipated that a Lewis acid/transition metal free synthesis of acyl benzothiophenes could provide an easy access to a library of benzothiophene based analogues of potential biological interest. Notably, while the use of various arenes/heteroarenes has been explored in the previous study, [25-30] the use of benzothiophene has not been examined so far. Herein we describe an efficient and simple method for the preparation of acyl benzothiophenes (3 and 4) that involves the first use of benzothiophene in the aromatic acylation process mediated by the mixed anhydrides of trifluoroacetic acid (Scheme 1). The results of this study are summarized in Table 1.

Results and Discussion

Initially, we conducted the acylation reaction of benzothiophene with acetic acid in the presence of 85% phosphoric acid and excess trifluoroacetic anhydride (TFAA) at room temperature (25–30°C) for 30 min where no significant product formation was observed. Then the reaction was continued for a longer time and the progress of the reaction was monitored by TLC over time. This exercise resulted in isolation of acylated products and the best results were observed when the reaction was carried out for 4 h. However, a mixture of 2- and 3-acylated benzothiophene was always isolated in all these cases. An attempt to prepare a single regioisomer by varying all the reaction parameters failed perhaps due to the high reactivity of the benzothiophene ring under the conditions studied. A similar observation was noted during acetylation[16,23] of benzothiophene using i) acetic anhydride in the presence of BF₃.Et₂O or ii) acetyl chloride in the presence of AlCl₃. In a typical procedure, to a mixture of commercially available acid 1 (2 g, 15 mmol) in TFAA (8.5 mL, 60 mmol) was added acetic acid (0.9 g, 15 mmol) dropwise followed by 85% H₃PO₄ (1.46 g, 15 mmol) with vigorous stirring at 0°C. The mixture was then warmed to 25–30°C, stirred for 4 h and poured into ice-cold water (25 mL) with vigorous stirring. The solid separated was filtered, washed with petroleum ether (2 × 5 mL) and dried to give the mixture of product 3a and 4a in 70 % overall yield. Based on HPLC data, [see Additional File 1 for full experimental data] the isolated solid was found to be a 1:9 mixture of 3a and 4a. After separating these compounds using column chromatography, the structures of 3a and 4a was confirmed by spectral data [see Additional File 1 for full spectral data]. Having prepared 3a and 4a successfully we then tested the reactivity of other carboxylic acids under these reaction conditions and subsequently, a variety of acylated benzothiophenes were prepared [see Additional File 1 for full spectral data] (Table 1). All the reaction was carried out using 1 (1 equiv), acid 2 (1 equiv), 85% H₃PO₄ (1 equiv) and TFAA (4 equiv) at 25–30°C for 4–5 h and the % yields shown in Table 1 represents isolated overall yields of products. All the products were identified by ¹H NMR, IR and mass spectra. As shown in Table 1, both aliphatic and aromatic acids participated in the acylation reaction of benzothiophene (entries 1–5 and 6–9). Aryl acids bearing an electron donating group such as methoxy (entry 8, Table 1) or electron withdrawing group such as nitro (entry 9, Table 1) afforded the desired products in good yields. While a mixture of 2- and 3-acylated benzothiophene was isolated in all the cases (entries 1–9, Table 1), the 3-isomer was isolated as the major product irrespective of the nature of the carboxylic acid used. The ratio of regioisomers present in the crude product isolated from the reaction mixture was determined by analyzing the corresponding ¹H NMR data. The C-3 proton of compound 3 appeared in the region of 7.90–7.95 δ (when R = alkyl) and 7.97–8.0 δ (when R = aryl) whereas C-4 proton of compound 4 appeared in 8.27–8.29 δ (when R = alkyl) and 8.40–8.60 δ (when R = aryl).

We have developed a very simple and single-step process for the synthesis of acyl benzothiophenes. All the starting materials are commercially available and can be used directly. The process does not require the use of additional organic solvent but involves use of excess TFAA. While the excess of TFAA and TFA (trifluoroacetic acid produced during the reaction) was removed by treating the reaction mixture with water, their removal by distillation is more appropriate for large scale preparations.[31] This also allows the recovery of spent TFAA, as TFA can be converted back to TFAA via dehydration[32] thereby eliminating the acid waste. It is known that TFAA is produced commercially via dehydration of TFA by using SO₃ as a dehydrating agent. However, P₂O₅ is more convenient in small scale preparation of TFAA.

A probable mechanism for the acylation of benzothiophene is shown in Scheme 2.[25] Accordingly, phosphoric acid plays a role of covalent catalyst which leads to the generation of acyl bis(trifluoroacetyl)phosphate from the acylation precursor acyl trifluoroacetate generated in situ.[33] The acyl bis(trifluoroacetyl)phosphate then acetylates the benzothiophene ring in the presence of phosphoric acid to afford the products 3 and 4. Phosphoric acid as a source of proton helps in activation. The isolation of compound 4 as the major product can be explained by the higher reactivity of C-3 over C-2 of the benzothiophene ring.

Conclusion

In conclusion, we have described a general synthesis of a variety of acylated benzothiophenes via acylation of benzothiophene rings with in situ generated arylacetyl trifluoroacetates. The reaction proceeds at room temperature and does not involve the use of any expensive reagents or catalysts. Other advantages of the present protocol include i) ready availability of the starting materials and mild reaction conditions, ii) environmentally safe as the protocol is free from the use of inorganic Lewis acids as well as chlorinated hydrocarbons as solvent, iii) simple operational procedure. However, formation of a mixture of regioisomers is the major drawback of this protocol. Nevertheless, the present process is certainly superior to the classical Friedel-Crafts acylation technique and other multi step synthesis. Further studies on establishing the regeioselectivity and application of this methodology in organic synthesis are under investigation.

Acknowledgements

The authors thank Mr. M. N. Raju, the chairman of M.N.R. Educational Trust for his constant encouragement.

References

1. Jordan VC:

   Nat ReV Drug Discoery. 2003, 2:205-213. Publisher Full Text

2. Rossouw JE, Anderson GL, Prentice RL, LaCroix AZ, Kooperberg C, Stefanick ML, Jackson RD, Beresford SA, Howard BV, Johnson KC, Kotchen JM, Ockene J:

   JAMA, J Am Med Assoc. 2002, 288:321-333. Publisher Full Text

3. Sall DJ, Bastian JA, Briggs SL, Buben JA, Chirgadze NY, Clawson DK, Denney ML, Giera DD, Gifford-Moore DS, Harper RW, Hauser KL, Klimkowski VJ, Kohn TJ, Lin H-S, McCowan JR, Palkowitz AD, Smith GF, Takeuchi K, Thrasher KJ, Tinsley JM, Utterback BG, Yan S-CB, Zhang M:

   J Med Chem. 1997, 40:3489-3493. PubMed Abstract | Publisher Full Text

4. Challenger F, Miller SA:

   J Chem Soc. 1939, 1005-1007. Publisher Full Text

5. Buu-Hoi NP:

   Recl Trav Chim Pays-Bas. 1948, 67:795-812.

6. Yokoyama Y, Nakata H, Sugama K, Yokoyama Y:

   Mol Cryst Liq Cryst Sci Technol Sect A. 2000, 344:253-258. Publisher Full Text

7. Horiguchi Y, Ogawa K, Saitoh T, Sano T:

   Chem Pharm Bull. 2004, 52:214-220. PubMed Abstract | Publisher Full Text

8. Katritzky AR, Bobrov S, Khashab N, Kirichenko KJ:

   Org Chem. 2004, 69:4269-4271. Publisher Full Text

9. Hosomi A, Miyashiro Y, Yoshida R, Tominaga Y, Yanagi T, Hojo M:

   J Org Chem. 1990, 55:5308-5310. Publisher Full Text

10. Tominaga Y, Pratap R, Castle RN, Lee ML:

    J Heterocycl Chem. 1982, 19:871-877.

11. Brooks CDW, Stewart AO, Basha A, Bhatia P, Ratajczyk JD, Martin JG, Craig RA, Kolasa T, Bouska JB, Lanni C, Harris RR, Malo PE, Carter GW, Bell RL:

    J Med Chem. 1995, 38:4768-4775. PubMed Abstract | Publisher Full Text

12. Martinez-Esparza J, Oficialdegui A-M, Perez-Silanes S, Heras B, Orus L, Palop J-A, Lasheas B, Roca J, Mourelle M, Bosch A, Castillo J-CD, Tordera R, Del Rio J, Monge A:

    J Med Chem. 2001, 44:418-428. PubMed Abstract | Publisher Full Text

13. Ishiyama T, Kizaki H, Miyaura N, Suzuki A:

    Tetrahedron Lett. 1993, 34:7595-7598. Publisher Full Text

14. Hsiao C-N, Bhagavatula L, Pariza RJ:

    Synth Commun. 1990, 20:1687-1695. Publisher Full Text

15. Oda K, Machida M:

    Chem Pharm Bull. 1993, 41:1299-1301.

16. Farrar MW, Levine R:

    J Am Chem Soc. 1950, 72:4433-4435. Publisher Full Text

17. Basha A, Brooks DW:

    J Org Chem. 1993, 58:1293-1294. Publisher Full Text

18. Leardini R, Pedulli GF, Tundo A, Zanardi G:

    J Chem Soc Chem Commun. 1985, 20:1390-1391. Publisher Full Text

19. Huff BE, Leffelman CL, LeTourneau ME, Sullivan KA, Ward JA, Stille JR:

    Heterocycles. 1997, 45:1363-1384.

20. Gallagher T, Pardoe DA, Porter RA:

    Tetrahedron Lett. 2000, 41:5415-5418. Publisher Full Text

21. Gaertner R:

    J Am Chem Soc. 1952, 74:2185-2187. Publisher Full Text

22. Buu-Hoi NP, Cagniant P:

    Recl Trav Chim Pays-Bas. 1948, 67:64-70.

23. Doepp D, Hassan AA, Henkel G:

    Liebigs Ann Org Bioorg Chem. 1996, 5:697-700.

24. Mitsumori S, Tsuri T, Honma T, Hiramatsu Y, Okada T, Hashizume H, Kida S, Inagaki M, Arimura A, Yasui K, Asanuma F, Kishino J, Ohtani M:

    J Med Chem. 2003, 46:2446-2455. PubMed Abstract | Publisher Full Text

25. Veeramaneni VR, Pal M, Yeleswarapu KR:

    Tetrahedron. 2003, 59:3283-3290. Publisher Full Text

26. Galli C:

    Synthesis. 1979, 303-304. Publisher Full Text

27. Matsushita Y-I, Sugamoto K, Matsui T:

    Tetrahedron Lett. 2004, 45:4723-4727. Publisher Full Text

28. Firouzabadi H, Iranpoor N, Nowrouzi N:

    Tetrahedron Lett. 2003, 44:5343-5345. Publisher Full Text

29. Ranu BC, Ghosh G, Jana U:

    J Org Chem. 1996, 61:9546-9547. Publisher Full Text

30. Wilkinson MC, Saez F, Hon WL, (E):

    Synlett. 2006, 1063-1066. Publisher Full Text

31. Smyth TP, Corby BW:

    Org Process Res Dev. 1997, 1:264-267. Publisher Full Text

32. Swarts F:

    Bull Cl Sci Acad R Belg. 1922, 343.

33. Smyth TP, Corby BW:

    J Org Chem. 1998, 63:8946-8951. Publisher Full Text

< previousfull textnext >