多官能团化的1,5-苯并二氮杂䓬类化合物的绿色合成

doi:10.6023/cjoc202106028

摘要/Abstract

1,5-苯并二氮杂䓬类化合物是一类具有重要生物或药理活性的七元氮杂环化合物, 酯基、羧基、酰基、芳基等均是其活性基团. 在室温(25 ℃)下以醛羰基化合物或二羰基化合物、3-丁炔-2-酮、取代的邻苯二胺为原料, 无水乙醇为溶剂, 磁性纳米铁酸钴(CoFe₂O₄)为催化剂/无催化剂条件下三组分串联反应一锅绿色合成34种COR、COOR或COOH取代的1,5-苯并二氮杂䓬类化合物, 产率最高可达90%, 并提出了催化串联合成反应机理. 该串联反应历经迈克尔加成反应、亲核加成反应、脱水反应、分子内的亚胺-烯胺环合反应、质子转移等反应过程, 一个反应体系内合成了多官能团化的1,5-苯并二氮杂䓬化合物, 实现了温和条件下, 一个反应体系中在苯并二氮杂䓬的七元环上同时引入活性的酰基、酯基或羧基等多个活性基团. 该方法的优势在于合成方法新颖、原子经济、目标化合物产率及选择性较高, 实现了反应过程的绿色化, 为绿色合成苯并氮杂䓬类化合物提供了新思路.

关键词: 三组分串联反应, 绿色合成, 1,5-苯并二氮杂䓬化合物

1,5-Benzodiazepine compounds are seven-membered nitrogen heterocyclic compounds with important biological and pharmacological activities. Ester group, carboxyl group, acyl group and aryl group are active groups of 1,5-benzodiazepine compounds. One-pot green synthesis of 34 kinds of 1,5-benzodiazepines with COR, COOR or COOH by three-component tandem reaction was performed at room temperature (25 ℃) with a yield of up to 90%. The mechanism of catalytic tandem reaction was proposed. These reactions were achieved by using aldehyde carbonyl compounds or dicarbonyl compounds, 3-butyn-2-one, substituted o-phenylenediamine as raw materials, absolute ethanol as solvent, magnetic nano cobalt ferrite (CoFe₂O₄) was realized under catalyst or without catalyst. The multifunctional 1,5-benzodiazepine compounds were formed via Michael addition reaction, nucleophilic addition-dehydration reaction, intramolecular imine-enamine cyclization and proton transfer processes, which realized that multiple active groups such as active acyl, ester or carboxyl groups were simultaneously introduced into the seven-membered ring of the benzodiazepine in a reaction system under mild conditions. This synthesis method has the advantages of novel synthesis method, atom economy, high yield and selectivity of the target compounds, which realize the green reaction process, and provide a new idea for green synthesis of benzozazepines.

Key words: three-component tandem reaction, green synthesis, 1,5-benzodiazepine compounds

引用此文

王明亮, 尹刘燕, 温甜甜, 张晓, 高杰, 王兰芝. 多官能团化的1,5-苯并二氮杂䓬类化合物的绿色合成[J]. 有机化学, 2022, 42(1): 160-171.

Mingliang Wang, Liuyan Yin, Tiantian Wen, Xiao Zhang, Jie Gao, Lanzhi Wang. Green Synthesis of 1,5-Benzodiazepines with Multifunctional Groups[J]. Chinese Journal of Organic Chemistry, 2022, 42(1): 160-171.

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图/表 10

图式1. 三组分串联反应一锅合成取代的3-乙酰基-1,5-苯并二氮杂?化合物

Scheme 1. Three-component tandem reaction to synthesize substituted 3-acetyl-1,5-benzodiazepines in one-pot

图式2. 一锅法的探究

Scheme 2. Exploring the one-pot method

图式3. 分步合成方法探究

Scheme 3. Research on stepwise synthesis method

图式 4. 串联合成方法的探究

Scheme 4. Research on tandem synthesis method

Entry	Solvent	Temp./℃	Catalyst^b	Time/h	Yield^e/%
1	EtOH	0	Free	12.0	—
2	EtOH	Reflux^c	Free	8.0	20
3	EtOH	r.t.^d	Free	10.0	40
4	MeOH	r.t.	Free	10.0	35
5	MeCN	r.t.	Free	13.0	30
6	PhMe	r.t.	Free	13.0	25
7	DMF	r.t.	Free	13.0	32
8	THF	r.t.	Free	13.0	30
9	EtOH	r.t.	AcOH	3.0	50
10	EtOH	r.t.	PTSA	3.0	50
11	EtOH	r.t.	PMA	4.0	53
12	EtOH	r.t.	PWA	4.0	55
13	EtOH	r.t.	CoCl₂	5.5	65
14	EtOH	r.t.	CeCl₃	5.5	65
15	EtOH	r.t.	CoFe₂O₄	5.5	78

表1. 三组分串联反应最优条件的筛选a

Table 1. Selection of optimal conditions for three-component series reaction

Entry	Solvent	Temp./℃	Catalyst^b	Time/h	Yield^c/%
1	EtOH	r.t.^d	Free	5.5	80
2	EtOH	r.t.	AcOH	3.5	50
3	EtOH	r.t.	PTSA	3.5	50
4	EtOH	r.t.	PMA	5.0	50
5	EtOH	r.t.	PWA	5.0	55
6	EtOH	r.t.	CoCl₂	6.0	65
7	EtOH	r.t.	CeCl₃	6.0	65
8	EtOH	r.t.	CoFe₂O₄	6.0	70

表2. 合成目标化合物5的最优条件筛选a

Table 2. Screening of optimal conditions for the synthesis of target compound 5

图式5. 苯并二氮杂?类化合物的合成

Scheme 5. Synthesis of benzodiazepine compounds

表3. 苯并二氮杂?类化合物的底物范围a

Table 3. Substrate range of benzodiazepine compounds

图1. 化合物4db的晶体结构图

Figure 1. Crystal structure of 4db

图式5. 目标化合物4ab的反应机理

Scheme 5. Reaction mechanism of target compound 4ab

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