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Progress in Chemistry 2008, Vol. 20 Issue (06): 878-886 Previous Articles   Next Articles

• Review •

Organobismuth Chemistry in the Past Decade

Zhang Xiaowen1,2 Yin Shuangfeng1** Wu Shuisheng1 Dai Weili1 Li Wensheng1 Zhou Xiaoping1**   

  1. (1. College of Chemistry and Chemical Engineering, Hunan University, Changsha 410082, China;
    2. College of City Construction, Nanhua University, Hengyang 421001,China)
  • Received: Revised: Online: Published:
  • Contact: Yin Shuangfeng
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Organobismuth chemistry is becoming more attractive since Bi is relatively low in price, toxicity and radioactivity, and many organobismuth compounds have found applications on medicine, catalysis, cosmetic, electronic technology, and so on. Especially, it has undergone great changes in the past decade, and the research achievements are worthy of being summarized. We made this mini-review on organobismuth chemistry on the basis of the following 4 aspects: (1) the molecule structure characteristics and synthesis of new organobismuth compounds; (2) as reagents for cross-coupling, oxidation, arylation, and other reactions; (3) as catalysts for organic synthesis; (4) as medicines for the treatment of ulcers, anti-tumor and radio-therapy, etc. The present review is emphasized on making a systematic summary on the relationship between the structure and chemical and biochemical activity of new organobismuth compounds from a viewpoint of molecular level. Finally, the scarcities and the future developing perspectives on organobismuth chemistry are also presented.
Key words: organobismuth compound, cross-coupling, arylation, catalysts

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[ 1 ] 贾如宝(Jia R B) . 金属世界(Metal World) , 1993 , 5 : 22
[ 2 ] Tiekink E R T. Critical Reviews Oncology Hematology , 2002 , 42 :217 —224
[ 3 ] Sun H , Li H , Sadler P J . Chem. Ber. Recueil , 1997 , 130 :669 —681
[ 4 ] 蒋琪英(Jiang Q Y) , 沈娟(Shen J) , 钟国清(Zhong G Q) . 化学进展(Progress in Chemistry) , 2006 , 18(12) : 1634 —1645
[ 5 ] Finet J P. Chem. Rev. , 1989 , 89 : 1487 —1501
[ 6 ] Euiott G I , Konopelski J P. Tetrahedron , 2001 , 57 : 5683 —5705
[ 7 ] Suzuki H , Matano Y. Organobismuth Chemistry. Amsterdam:Elsevier , 2001
[ 8 ] Balázs L , St?ngáO , Breuning HJ , et al . Dalton Trans. , 2003 ,11 : 2237 —2243
[ 9 ] Soran A P , Silvestru C , Breunig H J , et al . Organometallics ,2007 , 6 : 1196 —1203
[10] Bachman R E , Whitmire K H. Inorg. Chem. , 1995 , 34 : 1542 —1551
[11] Minoura M, Kanamori Y, Miyake M, et al . Chem. Lett . , 1999 ,861 —862
[12] Shimada S , Yamazaki O , Tanaka T , et al . J . Organomet .Chem. , 2004 , 689 : 3012 —3023
[13] Kotani T , Nagai D , Asahi K, et al . Antimicrob. Agents Chemother. , 2005 , 49(7) : 2729 —2734
[14] Matano Y, Miyamatsu T , Suzuki H. Organometallics , 1996 , 15 :1951 —1953
[15] Matano Y, Begum S A , Miyamatsu T , et al . Organometallics ,1999 , 18 : 5668 —5681
[16] Breunig HJ , Ghesner I , Ghesner M E. Inorg. Chem. , 2003 , 5 :1751 —1757
[17] Finet J P , Fedorov A Y. Russ. Chem. Bull . Inter. Ed. , 2004 ,7 : 1488 —1495
[18] Fedorov A Y, Finet J P. J . Chem. Soc. Perkin Trans. 1 , 2000 ,3775 —3778
[19] Sharma P , Cabrera A , Rosas N , et al . Z. Anorg. Allg. Chem. ,2000 , 626 : 921 —924
[20] Uchiyama Y, Kano N , Kawashima T. Organometallics , 2001 ,20 : 2440 —2442
[21] Yu L , Ma Y Q , Liu R C , et al . Inorg. Chem. Commun. , 2004 ,7 : 410 —411
[22] Sharutin V V , Egorova I V , Sharutina O K. Russ. J . Coord.Chem. , 2005 , 1 : 2 —8
[23] Reglinski J , Spicer M D , Garner M, et al . J . Am. Chem. Soc. ,1999 , 121 : 2317 —2318
[24] Bailey P J , Lanfranchi M, Marchio L , et al . Inorg. Chem. ,2001 , 40 : 5030 —5032
[25] Bao M, Hayashi T , Shimada S. Dalton Trans. , 2004 , 2055 —2056
[26] Mustafizur A F M, Murafuji T , Kurotobi K, et al .Organometallics , 2004 , 23 : 6176 —6183
[27] Yin S F , Bao M, Shimada S , et al . The 86th Spring Conference of Japan Chemistry Association , 2005 , 2J3 —12 , 967
[28] Rao M L N , Shimada S , Tanaka M. Org. Lett . , 1999 , 8 :1271 —1273
[29] Rao M L N , Shimada S , Yamazaki O. J . Organomet . Chem. ,2002 , 659 : 117 —120
[30] Shimada S , Yamazaki O , Tanaka T , et al . Angew. Chem. Int .Ed. , 2003 , 42 : 1845 —1848
[31] Yamazaki O , Tanaka T , Shimada S , et al . Synlett , 2004 , 11 :1921 —1924
[32] Tíubrik O , Kisseljova K, M? eorg U. Synlett , 2006 , 15 : 2391 —2394
[33] Rasmussen L K, Begtrup M, Ruhland T. J . Org. Chem. , 2004 ,69 : 6890 —6893
[34] Rasmussen L K, Begtrup M, Ruhland T. J . Org. Chem. , 2006 ,71 : 1230 —1232
[35] Matano Y, Hisanaga T , Yamada H , et al . J . Org. Chem. ,2004 , 25 : 8676 —8679
[36] Matano Y, Nomura H , Suzuki H , et al . J . Am. Chem. Soc. ,2001 , 123 : 10954 —10965
[37] Matano Y, Nomura H. J . Am. Chem. Soc. , 2001 , 123 : 6443 —6444
[38] Matano Y, Nomura H , Hisanaga T , et al . Organometallics ,2004 , 23 : 5471 —5480
[39] Iwata T , Miyake Y, Nishibayashi Y. J . Chem. Soc. Perkin Trans. 1 , 2002 , 1548 —1554
[40] Miyake Y, Iwata T , Chung K G, et al . Chem. Commun. , 2001 ,10 : 2584 —2585
[41] Matano Y, Imahori H. J . Org. Chem. , 2004 , 16 : 5505 —5508
[42] Finet J P , Fedorov A Y. J . Organomet . Chem. , 2006 , 691 :2386 —2393
[43] Takashi O , Ryoji G, Keiji M. J . Am. Chem. Soc. , 2003 , 125 :10494 —10495
[44] Koech P K, Krische M J . J . Am. Chem. Soc. , 2004 , 17 :5350 —5350
[45] Sorenson R J . J . Org. Chem. , 2000 , 65 : 7747 —7749
[46] Arnauld T , Barton D H R. J . Org. Chem. , 1999 , 64 : 6915 —6917
[47] Coles SJ , Costello J F , Hursthouse MB. J . Organomet . Chem. ,2002 , 662 : 98 —104
[48] Tíubrik O , M? eorg U , Sillard R , et al . Tetrahedron , 2004 , 60 :8363 —8373
[49] Ikegai K, Mukaiyama T. Chem. Lett . , 2005 , 34 : 1496 —1497
[50] Fedorov A Y, Finet J P , Ganina O G, et al . Russ. Chem. Bull .Int . Ed. , 2005 , 11 : 2602 —2611
[51] Moiseev D V , Malysheva Y B , Shavyrin A S. J . Organomet .Chem. , 2005 , 690 : 3652 —3663
[52] Nishikata T , Yamamoto Y, Miyaura N. Chem. Commun. , 2004 ,1822 —1823
[53] Kirij N V , Pasenok S V , Yagupolskii Y L , et al . J . Fluorine Chem. , 2000 , 106 : 217 —221
[54] Campi E M, Deacon G B , Edwards G L , et al . J . Chem. Soc. ,1989 , 407 —408
[55] Dodonov V A , Zinovyeva T I. Metalloorg. Khim. , 1993 , 6 :375 —376
[56] Desmurs J R , Labrouillêre M, le Roux C , et al . Tetrahedron Lett . , 1997 , 38 : 8871 —8874
[57] Le Roux C , Mandrou S , Dubac J . J . Org. Chem. , 1996 , 61 :3885 —3887
[58] Labrouillère M, le Roux C , Gaspard H , et al . Tetrahedron Lett . ,1997 , 38 : 8871 —8874
[59] Anzalone P W, Baru A R , Danielson E M, et al . J . Org.Chem. , 2005 , 70(6) : 2091 —2096
[60] Ménard C , Doris E , Mioskowski C. Tetrahedron Lett . , 2003 ,44 : 6591 —6593
[61] Khosropour A R , Mohammadpoor-Baltorka I , Ghorbankhani H.Tetrahedron Lett . , 2006 , 47 : 3561 —3564
[62] 刘训恩(Liu X E) , 缪琳(Miu L) , 陈力(Chen L) 等. 北京理工大学学报(J . Beijing Institute T. ) , 1995 , 15 (6) : 7 —9
[63] 鲁国林(Lu G L) , 夏强(Xia Q) , 杜娟(Du J ) . 含能材料(Energetic Materials) , 1996 , 7 (2) : 60 —63
[64] Yin S F , Bao M, Shimada S , et al . The 32nd Symposium on Heteroatom Chemistry ( ed. Michael T H L) . Tsukuba : Asahi Publishing Company , 2005. 228 —229
[65] Sadler P J , Li H , Sun H. Coord. Chem. Rev. , 1999 , 185 :689 —709
[66] Murafuji T , Miyoshi Y, Ishibashi M, et al . J . Inorg. Biochem. ,2004 , 98 : 547 —552
[67] Murafuji T , Azuma T , Miyoshi Y. Bioorg. Med. Chem. Lett . ,2006 , 16 : 1510 —1513
[68] Kotani T , Nagai D , Asahi K, et al . Antimicrob. Agents Chemother. , 2005 , 7 : 2729 —2734
[69] Yu L , Ma Y Q , Wang G C , et al . J . Organomet . Chem. , 2003 ,679 : 173 —180
[70] Dittes U , Vogel E , Keppler B K. Coord. Chem. Rev. , 1997 ,163 : 345 —364
[71] Tytgat G N J . Dig. Dis. , 1998 , 16 : 192 —197
[72] Kêpf-Maier P , Klapêtke T. Inorg. Chim. Acta , 1988 , 152 : 49 —52
[73] Smith K A , Deacon G B , Jackson W R , et al . Metal-Based Drugs , 1998 , 5 : 295 —304
[74] Nikula T K, McDevitt M R , Finn R D , et al . J . Nucl . Med. ,1999 , 40 : 166 —176
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Abstract

Organobismuth Chemistry in the Past Decade