聚氯乙烯负载L-脯氨酸催化不对称Aldol反应的研究

以聚氯乙烯为载体,合成两种负载型催化剂水解聚氯乙烯四乙烯五胺负载L-脯氨酸催化剂(HPTP)和聚氯乙烯四乙烯五胺负载L-脯氨酸催化剂(PTP),催化剂中脯氨酸负载量分别为2.46 mmol/g和1.52 mmol/g。两种催化剂均可实现对不对称Aldol反应的催化,但HPTP的活性和选择性均较PTP的高。HPTP在水中可以催化多种苯甲醛与丙酮的不对称Aldol反应,取得中等的ee值。HPTP经过回收还可以重复利用,显示了较好的性能。在合适的反应条件下,HPTP催化对硝基苯甲醛和丙酮的反应,获得最高75%的产率和39%的ee值。     

助剂对L-脯氨酸催化直接不对称Aldol反应的影响

在L-脯氨酸催化的芳香醛与丙酮直接不对称aldol反应体系中添加二醇或二酚类助剂可有效提高反应活性.助剂的使用降低了该反应体系中L-脯氨酸的用量.特别是以邻苯二酚为助剂时,最佳反应条件下,仅用5mol％L-脯氨酸与1mol％助剂催化2-硝基苯甲醛与丙酮直接不对称aldol反应,aldol产物产率高达90％,对映选择性为80％.该反应产率比未加助剂条件下,L-脯氨酸用量为30mol％时的反应产率高.采用量子化学计算研究了助剂对该反应的促进作用.结果表明,助剂可与芳香醛的醛基形成氢键,从而活化醛基,提高反应效率.邻苯二酚结构中相邻的羟基能与底物芳香醛羰基的氧原子形成双氢键,大大活化了底物芳香醛的羰     

脯氨酸二肽催化的不对称直接Aldol反应

以(S)-脯氨酸和(R)-脯氨酸为原料合成了二肽H-(S)-Pro-(S)-Pro-OH(1)和H-(S)-Pro(-R)-Pro-OH(2),分别以两种二肽催化了不对称直接A ldol反应,获得了相同立体构型(S)的产物,与(S)-脯氨酸催化所得的产物构型(R)相反.该催化剂的立体选择性不高(ee<21%).理论计算的结果与实验结果吻合.     

壳聚糖负载L-脯氨酸对水中不对称Aldol反应的催化性能

以壳聚糖为载体制备了负载型L-脯氨酸不对称催化剂;将合成产物用于催化丙酮与取代苯甲醛在水中的直接不对称Aldol反应,考察了其催化性能.结果表明,与在有机溶剂中的L-脯氨酸催化剂相比,在水相中的壳聚糖负载L-脯氨酸催化剂表现出更好的催化活性;就间硝基苯甲醛与丙酮在水中的不对称Aldol反应而言,壳聚糖负载L-脯氨酸催化下的产率和ee值分别达95%和48%.此外,壳聚糖负载L-脯氨酸催化剂在水中具有很好的重复使用性能,重复使用10次后相应的产率和ee值分别为88%和68%.     

离子对负载L-脯氨酸阴离子催化下的不对称Aldol反应

在水相中,通过阴阳离子结合使L-脯氨酸阴离子负载在基于Merrifield树脂的季铵根阳离子上,制备出功能性高分子离子液体.将该体系作为一种高效、可回收的催化剂用于催化醛与酮的不对称Aldol反应.结果表明:该催化体系在微量水中有很好的催化活性和立体选择性,相应的Aldol反应产物获得了6∶94的dr值以及高达98%的ee值,且该催化体系有较好的重复使用性能.     

L-脯氨酸催化的不对称Aldol缩合反应实验设计

介绍了L-脯氨酸催化的对硝基苯甲醛与丙酮的不对称Aldol反应的实验设计。室温反应2 h后,柱层析得到（R）-4-（4-硝基苯基）-4-羟基-2-丁酮,利用手性高效液相色谱测试得到产物的ee值。学生实验结果显示,收率范围为53%~74%,对映选择性范围为62%~69%。本实验方案将Aldol反应的研究成果设计成综合性实验,不仅强化训练了学生基本的实验技能和操作,同时拓宽了知识面,培养了学生分析问题、解决问题等方面的综合能力。     

氯甲基化聚苯乙烯负载修饰L-脯氨酸催化不对称Aldol反应研究

以氯甲基化聚苯乙烯为载体,分别以氨基胍、三聚氰胺和4,4′-二氨基苯磺酰苯胺(DASA)为连接臂,合成了三种负载修饰L-脯氨酸催化剂,并且将其用于催化不对称Aldol反应,探索了溶剂和底物对其催化性能的影响,并考察了其重复使用性能.结果表明,DASA负载修饰L-脯氨酸催化剂具有较好的催化活性和选择性,相应的最高产率达83%,e.e.值达86%.     

脯氨酸催化的不对称Aldol反应的研究进展

不对称合成是手性药物制备的核心环节,A ldol反应是重要的形成C—C键的反应之一,在全合成中有广泛应用.脯氨酸的两个异构体均价廉易得,作为一个非金属不对称催化试剂,它催化的不对称A ldol反应立体选择性高,有很好的应用前景.本文就近二十年来脯氨酸催化A ldol反应的机理,溶剂效应,最新进展三方面进行了介绍.     

壳聚糖负载辛可宁催化剂的制备及其在水中催化不对称Aldol反应

以丁二酸酐为连接臂,经两步反应制备了壳聚糖负载辛可宁有机催化剂(CTS-SA-CN),并研究了CTS-SA-CN在水体系中对酮与多种芳香醛的直接不对称aldol反应的催化性能。结果表明,在CTS-SA-CN催化下,酮与多种芳香醛发生直接不对称aldol反应,可得到99%的产率和96%的ee值。另外, CTS-SA-CN可通过简单过滤实现回收,重复使用5次活性并没有明显下降。     

壳聚糖负载辛可宁催化剂的制备及其在水中催化不对称Aldol反应

以丁二酸酐为连接臂,经两步反应制备了壳聚糖负载辛可宁有机催化剂(CTS-SA-CN),并研究了CTS-SA-CN在水体系中对酮与多种芳香醛的直接不对称aldol反应的催化性能。结果表明,在CTS-SA-CN催化下,酮与多种芳香醛发生直接不对称aldol反应,可得到99%的产率和96%的ee值。另外, CTS-SA-CN可通过简单过滤实现回收,重复使用5次活性并没有明显下降。     

Recent progress on direct catalytic asymmetric vinylogous reactions

Direct catalytic asymmetric vinylogous reaction serves as a powerful tool to introduce stereocenter(s) at the γ- or/and even more remote position(s) of the vinylogous products in an atom-economical and efficient way. A variety of direct catalytic asymmetric vinylogous reactions with broad substrate scope and mild reaction conditions has been developed. Both metal catalysis and organocatalysis contributed in this field and led to the vinylogous products in high stereoselectivity. These vinylogous reactions provided efficient pathways for the synthesis of highly functionalized optically pure compounds, especially these with potential biological activity and pharmacological activity. This digest paper mainly focuses on the most recent developments in this field, including both nucleophilic addition and nucleophilic substitution.     

Organocatalytic direct asymmetric aldol reactions in water

We have developed direct asymmetric cross-aldol reactions that can be performed in water without addition of organic solvents. A bifunctional catalyst with a long hydrophobic alkyl chain efficiently catalyzed the reactions and afforded the desired aldol products in excellent yield with high enantiomeric excess, even when only an equal molar ratio of the donor and acceptor was used. These results reveal an effective design strategy for the development of aqueous organocatalytic systems.     

Dipeptide-catalyzed direct asymmetric aldol reactions in the presence of water

The l-proline-based dipeptide has been discovered and developed as an efficient catalyst for the direct asymmetric aldol reactions of unmodified ketones with various aldehydes including aromatic, aliphatic, heteroaromatic, and unsaturated aldehydes in the presence of water at 0 °C. The resulted methodology and optimal conditions led to the corresponding aldol products with high yields (up to 94%) and good enantioselectivities (up to 97% ee).     

Metal/linked-BINOL complexes: Applications in direct catalytic asymmetric Mannich-type reactions

Development of metal/linked-BINOL complexes and their applications in direct catalytic asymmetric Mannich-type reactions of hydroxyketones are reviewed. A Et₂Zn/linked-BINOL complex was effective for diastereo- and enantioselective synthesis of β-amino alcohols. By choosing the proper protective groups on the imine nitrogen, either anti- or syn-β-amino alcohol was obtained in excellent enantioselectivity (up to >99.5% ee) using the same zinc catalysis. Y{N(SiMe₃)₂}₃/linked-BINOL complex was effective for various hydroxyketones, affording syn-β-amino alcohols with high enantioselectivity (up to 98% ee). To broaden the nucleophile scope to carboxylic acid derivatives, N-acylpyrrole was utilized as an ester equivalent donor. In(O-iPr)₃/linked-BINOL complex was effective for generating an In-enolate from N-acylpyrrole in situ, giving Mannich adducts with high enantioselectivity (up to 98% ee).     

Organocatalytic asymmetric syn-selective direct aldol reactions in water

A practical and convenient organocatalytic strategy is developed to provide a direct route to syn-selective aldol products in the presence of water. The siloxy serine organocatalyst mediates the direct aldol reaction of TBSO-protected hydroxyacetone with a variety of aldehydes to provide the aldol products in good yields and enantioselectivities up to 92%.     

Amino acid catalyzed direct asymmetric aldol reactions: a bioorganic approach to catalytic asymmetric carbon-carbon bond-forming reactions.

Direct asymmetric catalytic aldol reactions have been successfully performed using aldehydes and unmodified ketones together with commercially available chiral cyclic secondary amines as catalysts. Structure-based catalyst screening identified L-proline and 5,5-dimethyl thiazolidinium-4-carboxylate (DMTC) as the most powerful amino acid catalysts for the reaction of both acyclic and cyclic ketones as aldol donors with aromatic and aliphatic aldehydes to afford the corresponding aldol products with high regio-, diastereo-, and enantioselectivities. Reactions employing hydroxyacetone as an aldol donor provide anti-1,2-diols as the major product with ee values up to >99%. The reactions are assumed to proceed via a metal-free Zimmerman-Traxler-type transition state and involve an enamine intermediate. The observed stereochemistry of the products is in accordance with the proposed transition state. Further supporting evidence is provided by the lack of nonlinear effects. The reactions tolerate a small amount of water (<4 vol %), do not require inert reaction conditions and preformed enolate equivalents, and can be conveniently performed at room temperature in various solvents. In addition, reaction conditions that facilitate catalyst recovery as well as immobilization are described. Finally, mechanistically related addition reactions such as ketone additions to imines (Mannich-type reactions) and to nitro-olefins and alpha,beta-unsaturated diesters (Michael-type reactions) have also been developed.     

3-Pyrrolidinecarboxylic acid for direct catalytic asymmetric anti-Mannich-type reactions of unmodified ketones

We report the development of direct catalytic, enantioselective, anti-selective Mannich-type reactions between unmodified ketones and alpha-imino esters under mild conditions. The reactions were performed using 5-10 mol % of (R)-3-pyrrolidinecarboxylic or (R)-beta-proline as catalyst in an environmentally benign solvent, 2-PrOH, at room temperature. The anti-Mannich products were obtained in good yields with high diastereo- and enantioselectivities (up to anti/syn >99:1, 99% ee). While (3R,5R)-5-methyl-3-pyrrolidinecarboxylic acid is an excellent catalyst for the anti-Mannich-type reactions of aldehydes, it did not efficiently catalyze the corresponding Mannich-type reactions of ketones; (R)-3-pyrrolidinecarboxylic acid did efficiently catalyze the Mannich-type reactions of ketones. (S)-Proline or (S)-2-pyrrolidinecarboxylic acid has been reported to catalyze the Mannich-type reactions of ketones to afford the syn-products. Thus, the position of the carboxylic acid group on the pyrrolidine ring directs the stereoselection of the catalyzed reaction, providing either syn- or anti-Mannich products.