芳基卤代物与苯乙烯的电化学还原偶联烷基化反应

doi:10.6023/cjoc202603011

有机化学

研究论文

芳基卤代物与苯乙烯的电化学还原偶联烷基化反应

刘小冬, 陈永乐, 蒙语薇, 王毛锐^*, 唐海涛^*

药用资源化学与药物分子工程教育部重点实验室,广西药用资源化学与药物分子工程重点实验室,特色药用资源化学广西高校工程研究中心,广西师范大学化学药学学院,桂林 541004

收稿日期:2026-03-09 修回日期:2026-04-06
基金资助:
广西自然科学基金(No. 2026GXNSFBA00640262), 广西科技计划项目资助, (No. GUIKE AD25069038), 国家资助博士后研究人员计划B档 (No. GZB20250265)和大学生创新创业训练计划 (No. X2025106020233) 资助项目.

Aryl Halides and Styrene Electrochemical Reduction Coupling Alkylation Reaction

Liu Xiaodong, Chen Yongle, Meng Yuwei, Wang Maorui^*, Tang Haitao^*

Key Laboratory for Chemistry and Molecular Engineering of Medicinal Resources (Ministry of Education of China), Guangxi Key Laboratory of Chemistry and Molecular Engineering of Medicinal Resources, University Engineering Research Center for Chemistry of Characteristic Medicinal Resources (Guangxi), School of Chemistry and Pharmaceutical Sciences, Guangxi Normal University, Guilin 541004, China

Received:2026-03-09 Revised:2026-04-06
Contact: *E-mail: mrwang@gxnu.edu.cn; httang@gxnu.edu.cn
Supported by:
Guangxi Natural Science Foundation of China (No. 2026GXNSFBA00640262), the Guangxi Science and Technology Program (GUIKE AD25069038), the Postdoctoral Fellowship Program of CPSF (No. GZB20250265) and the National Innovation and Entrepreneurship Training Program for Undergraduates (No. X2025106020233).

文章分享

1. cjoc202603011辅助材料.pdf(2461KB)

摘要/Abstract

联苄类化合物广泛存在于天然产物中,其衍生得到的二氢芪类衍生物具有优异抗肿瘤活性,是药物研发领域的重要先导结构。但现有合成方法多依赖贵金属催化剂与化学计量氧化还原剂,存在操作繁琐、应用受限等问题。本研究以有机电化学合成“以电子为绿色试剂”为核心理念,发展一种以萘为电子媒介,廉价易得的芳基卤化物与苯乙烯为原料,通过电化学还原偶联反应构建联苄类化合物的策略。该策略利用萘介导芳基卤代物在阴极还原脱卤生成苯基自由基,再以苯乙烯为自由基受体,开发出无需外源氧化还原剂及催化剂的电化学合成体系。此体系可在温和条件下高效制备联苄类化合物,底物适用性优异,能兼容碘代、溴代及氯代等多种芳基卤代物,为联苄类化合物的绿色高效合成提供了新路径,在药物合成领域具有良好应用潜力。

关键词: 卤苯, 有机电还原, C-C偶联, 无金属催化, 萘介导

Bibenzyl compounds are widely found in natural products, and their derived dihydrostilbene derivatives exhibit excellent anti-tumor activity, serving as important lead structures in the field of drug research and development. However, existing synthetic methods mostly rely on noble metal catalysts and stoichiometric oxidizing/reducing agents, suffering from drawbacks such as cumbersome operations and limited applications. Based on the core concept of organic electrochemical synthesis that "uses electrons as green reagents", this study develops a strategy for constructing bibenzyl compounds through electrochemical reductive coupling reaction, using naphthalene as the electron mediator and cheap and readily available aryl halides and styrenes as raw materials. This strategy utilizes naphthalene to mediate the reductive dehalogenation of aryl halides at the cathode to generate phenyl radicals, which then take styrenes as radical acceptors. An electrochemical synthesis system without exogenous oxidizing/reducing agents and catalysts is thus developed. This system can efficiently prepare bibenzyl compounds under mild conditions, with excellent substrate applicability, being compatible with various aryl halides such as iodo-, bromo-, and chloro-substituted ones. It provides a new green and efficient synthetic pathway for bibenzyl compounds, and has good application potential in the field of drug synthesis.

Key words: Halobenzene, Organic electroreduction, C-C coupling, Metal-free catalysis, Naphthalene mediated

引用此文

刘小冬, 陈永乐, 蒙语薇, 王毛锐, 唐海涛. 芳基卤代物与苯乙烯的电化学还原偶联烷基化反应[J]. 有机化学, doi: 10.6023/cjoc202603011.

Liu Xiaodong, Chen Yongle, Meng Yuwei, Wang Maorui, Tang Haitao. Aryl Halides and Styrene Electrochemical Reduction Coupling Alkylation Reaction[J]. Chinese Journal of Organic Chemistry, doi: 10.6023/cjoc202603011.

导出引用 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

分享此文

参考文献

[1] (a) Liu Y.; Li X.; Sui S.; Tang J.; Chen D.; Kang Y.; Xie K.; Liu J.; Lan J.; Wu L.; Chen R.; Peng Y.; Dai J. ACTA. PHARM. SIN. B.2023, 13, 1771~1785.
(b) Krawczyk H. Bioorg. Chem.2019, 90, 103073.
[2] Nandy S.; Dey A. DARU J. Pharm. Sci.2020, 28, 701~734.
[3] He L.; Su Q.; Bai L.; Li M.; Liu J.; Liu X.; Zhang C.; Jiang Z.; He J.; Shi J.; Huang S.; Guo L. Eur. J. Med. Chem.2020, 204, 112530.
[4] Vitalini S.; Cicek S. S.; Granica S.; Zidorn C. Curr. Med. Chem.2018, 25, 1194~1240.
[5] Liu Y.; Zhang J.; Zhan R.; Chen Y. Chem. Biodiversity. 2022, 19, e202200259.
[6] Kongkatitham V.; Dehlinger A.; Chaotham C.; Likhitwitayawuid K.; Böttcher C.; Sritularak B. PLoS. ONE. 2024, 19, e0292366.
[7] Chen X.; Wang M.; Jiang H.; Dixneuf P. H.; Zhang M. J. Am. Chem. Soc.2025, 147, 43153~43161.
[8] Xie J.; Liang R.; Jia Y. Chin. J. Chem.2021, 39, 710~728.
[9] Yadav M. R.; Nagaoka M.; Kashihara M.; Zhong R. L.; Miyazaki T.; Sakaki S.; Nakao Y. J. Am. Chem. Soc.2017, 139, 9423~9426.
[10] Haas D.; Hammann J.M.; Greiner R.; Knochel P. ACS Catal. 2016, 6, 1540~1552.
[11] (a) Yang X. W.; Li D. H.; Song A. X.; Liu F. S.J. Org. Chem. 2020, 85, 11750~11765.
(b) Kantam M. L.; Chakravarti R.; Chintareddy V. R.; Sreedhar B.; Bhargava S. Adv. Synth. Catal.2008, 350, 2544~2550.
[12] Du W.; Zhao F.; Yang R.; Xia Z.Org. Lett. 2024, 26, 3145-3150.
[13] Reischauer S.; Pieber B. iScience2021, 24, 102209.
[14] Yang Q.; Li X.; Chen L.; Han X.; Wang F. R.; Tang J. Angew. Chem. Int. Ed.2023, 62, e202307907.
[15] (a) Badsara S. S.; Ucheniya K.; Chouhan A.; Gurjar A. Chem. Rec. 2025, 25, e202500092.
(b) Wang M.; Zhang C.; Ci C.; Jiang H.; Dixneuf P. H.; Zhang M.J. Am. Chem. Soc. 2023, 145, 10967~10973.
(c) Wang M.; Zhang C.; Zhao He.; Jiang H.; Dixneuf P. H.; Zhang M.CCS Chem. 2024, 6, 342~352.
[16] Yu W.; Wang S.; He M.; Jiang Z.; Yu Y.; Lan J.; Luo J.; Wang P.; Qi X.; Wang T.; Lei A. Angew. Chem. Int. Ed.2023, 62, e202219166.
[17] (a) Xie F.; Han F.; Su Q.; Peng Y.; Jing L.; Han P.Org. Lett. 2024, 26, 4427~4432.
(b) Hu P.; Peters B. K.; Malapit C. A.; Vantourout J. C.; Wang P.; Li J.; Mele L.; Echeverria P. G.; Minteer S. D.; Baran P. S. J. Am. Chem. Soc.2020, 142, 20979~20986.
[18] Folgueiras‐Amador A. A.; Teuten A. E.; Salam‐Perez M.; Pearce J. E.; Denuault G.; Pletcher D.; Parsons P. J.; Harrowven D. C.; Brown, R. C. D. Angew. Chem. Int. Ed.2022, 61, e202203694.
[19] Wang Y.; Zhao Z.; Pan D.; Wang S.; Jia K.; Ma D.; Yang G.; Xue X.; Qiu Y. Angew. Chem. Int. Ed.2022, 61, e202210201.
[20] Li X.; Zhou J.; Deng W.; Wang Z.; Wen Y.; Li Z.; Qiu Y.; Huang Y. Chem. Sci. 2024, 15, 11418~11427.
[21] Lai Y.; Milner P. J. Angew. Chem. Int. Ed.2024, 63, e20240883.
[22] Liu M.; Feng T.; Wang Y.; Kou G.; Wang Q.; Wang Q.; Qiu Y.Nat. Commun. 2023, 14, 6467.
[23] Hong H.; Zou Z.; Liang G.; Pu S.; Hu J.; Chen L.; Zhu Z.; Li Y.; Huang, Yu. Org. Biomol. Chem.2020, 18, 5832~5837.

芳基卤代物与苯乙烯的电化学还原偶联烷基化反应

Aryl Halides and Styrene Electrochemical Reduction Coupling Alkylation Reaction

PDF

补充材料

可视化

摘要/Abstract

引用此文

分享此文

参考文献

相关文章 15

编辑推荐

相关统计

本文评价

[1]	郭艳辉, 屈红恩, 梁佩. 手性有机硒化合物的合成研究进展[J]. 有机化学, 2026, 46(3): 786-805.
[2]	张连吉, 王炳福, 潘大龙, 王翠苹, 赵玉辉, 迟海军, 董岩, 魏万国, 张志强. 乙酸介导的咪唑并吡啶与乙二醛水合物的无金属氧化C—H交叉偶联反应[J]. 有机化学, 2025, 45(8): 2923-2931.
[3]	纪健, 刘进华, 管丛, 陈绪文, 赵芸, 刘顺英. 原位生成的磺酸催化N-磺酰基-1,2,3-三氮唑与醇偶联高区域选择性合成N²-取代1,2,3-三氮唑[J]. 有机化学, 2023, 43(3): 1168-1176.
[4]	马彪, 章淼淼, 李占宇, 彭进松, 陈春霞. 无过渡金属催化的Suzuki-Type交叉偶联反应研究进展[J]. 有机化学, 2023, 43(2): 455-470.
[5]	张智鑫, 翟彤仪, 朱伯汉, 钱鹏程, 叶龙武. 无金属催化炔酰胺分子内[4+2]环化反应合成四氢吲哚衍生物[J]. 有机化学, 2022, 42(5): 1501-1508.
[6]	陈任宏, 吴桂贞, 杨凯, 叶斌, 陈庆凤, 汪朝阳. 一锅法合成N-呋喃酮基磺酰腙类化合物[J]. 有机化学, 2021, 41(7): 2750-2759.
[7]	杨凯, 刘美娟, 张毓娜, 占佳琦, 邓璐璇, 郑雪洁, 周永军, 汪朝阳. 基于2-卤苯甲酰胺合成苯并杂环化合物的研究进展[J]. 有机化学, 2021, 41(6): 2175-2187.
[8]	谢坤宸, 江铭轩, 陈晓岚, 吕琪妍, 於兵. α-酮酸在无金属有机光合成中的应用[J]. 有机化学, 2021, 41(12): 4575-4587.
[9]	刘天宝, 彭艳芬, 桂美芳, 章敏. 无金属催化快速合成2-芳酰氨基萘并[1, 2-d]噻唑[J]. 有机化学, 2019, 39(11): 3199-3206.
[10]	吴玉芹, 于凉云, 张奇, 李立冬. 钯催化[2+2+2]环化反应制备5,6-二氢苯并菲啶衍生物[J]. 有机化学, 2017, 37(9): 2336-2342.
[11]	蔺松波, 何兴瑞, 孟金鹏, 顾海宁, 张培志, 吴军. 无过渡金属存在下由邻卤苯酚合成邻卤二芳胺[J]. 有机化学, 2017, 37(7): 1864-1869.
[12]	汤玲娟, 陆新谋, 纪顺俊. 碱促进下碳二亚胺参与构建二氢喹唑啉及其衍生物[J]. 有机化学, 2017, 37(3): 746-752.
[13]	郝文燕, 王昱赟, 刘云云. 无金属催化的8-氨基喹啉C5位上的卤化反应[J]. 有机化学, 2017, 37(12): 3198-3203.
[14]	肖立伟, 张光霞, 景学敏, 周秋香, 冯茹. 功能化多取代噁唑类化合物的合成研究新进展[J]. 有机化学, 2016, 36(5): 1000-1013.
[15]	胡飞, 高文超, 常宏宏, 李兴, 魏文珑. 碘促进的砜基化反应研究进展[J]. 有机化学, 2015, 35(9): 1848-1860.