手性高分子金属络合物在不对称催化中的应用

综述了手性高分子金属络合物（人工合成）在不对称催化中的应用及最新进展,参考文献５３篇。     

Asymmetric Phase-Transfer Catalysis

Both in the laboratory and industrially , phase-transfer catalysis offers the potential to induce asymmetry into reactions with anionic intermediates. Equation (a) provides an example (conditions: a) 10 mol % phase-transfer catalyst, BnBr, CsOH⋅H₂O, PhMe, 15–24 h, −78°C).     

Catalytic Asymmetric Allenylation: Regulation of the Equilibrium between Propargyl- and Allenylstannanes during the Catalytic Process

Achiral substrates 1 and 2 can be regioselectively converted into chiral allenyl alcohols 3 through the title reaction [Eq. (1)] with the synergetic reagent iPrSBEt₂ and a chiral Ti^IV catalyst. The dramatic regioselectivity originates from the regulation of the equilibrium between propargyl- and allenylstannanes during the catalytic process.     

C3 Symmetry in Asymmetric Catalysis and Chiral Recognition

Rotational symmetry can be an important factor in the design of highly selective receptors for chiral recognition. This is well known for C₂-symmetric compounds, but the concept can be extended to chiral compounds of higher symmetry such as 1 .     

微通道反应器在不对称催化中的应用

不对称催化是合成手性化合物的重要手段,针对该领域已开展了大量的研究工作并获得了引人瞩目的研究成果。相比于传统的釜式反应器,微通道反应器具有传质/传热效率高、反应时间短、易于自动化和提高安全性等优势。因此,将微通道反应器应用于不对称催化领域已成为当前的研究热点,并且在耦合在线分析、多相催化和光催化等领域已展现出良好的应用前景。本文对近年来微通道反应器在不对称催化领域中的最新研究进展进行总结和综述,并对未来的发展方向进行展望。     

Asymmetric Catalysis with Heterobimetallic Compounds

This review focuses on a new concept in catalytic asymmetric reactions that was first realized for the use of heterobimetallic complexes. As these heterobimetallic complexes function as both a Brønsted base and as a Lewis acid, just like an enzyme, they make possible a variety of efficient catalytic asymmetric reactions. This heterobimetallic concept should prove to be applicable to a variety of new asymmetric catalyses. The first part of this review describes the development of rare-earth–alkali metal complexes such as LnM₃tris(binaphthoxide) complexes (LnMB, Ln = rare-earth metal, M = alkali metal), which are readily prepared from the corresponding rare-earth trichlorides or rare-earth isopropoxides, and their application to catalytic asymmetric synthesis. By using a catalytic amount of LnMB complexes several asymmetric reactions proceed efficiently to give the corresponding desired products in up to 98% ee: LnLB-catalyzed asymmetric nitroaldol reactions (L = Li), LnSB-catalyzed asymmetric Michael reactions (S ? Na), and LnPB-catalyzed asymmetric hydrophosphonylations of either imines or aldehydes (P ? K). Applications of these heterobimetallic catalysts to the syntheses of several biologically and medicinally important compounds are also described. Spectral analyses and computational simulations of the asymmetric reactions catalyzed by the heterobimetallic complexes reveal that the two different metals play different roles to enhance the reactivity of both reaction partners and to position them. From mechanistic considerations, a useful activation of the heterobimetallic catalyses was realized by addition of alkali metal reagents. The second part describes the development of another type of heterobimetallic catalysts featuring Group 13 elements such as Al and Ga as the central metal. Among them, the AlLibis(binaphthoxide) complex (ALB) is an effective catalyst for asymmetric Michael reactions, tandem Michael–aldol reactions, and hydrophosphonylation of aldehydes.     

Asymmetric Electrochemical Catalysis

Asymmetric electrochemical catalysis, an emerging frontline in asymmetric catalysis and electro-organic synthesis, is summarized. Representative works are classified, with respect to the external chiral resources, including chiral media, chiral mediator, chiral catalyst, and chiral electrode. This concept article is expected to provide readers with the general concepts and perspectives of each chiral electrochemical catalysis mode, and to indicate the potential and future development of asymmetric electrochemical catalysis.     

手性原子簇合物与不对称催化反应

以骨架手性原子簇合物为催化剂的不对称催化反应一直认为是极富挑战性的课题，一旦实现，将是一种理想和概念上的突破，回顾原子簇合物的不对性及不对称催化反应的进展，阐述了我们的目标和一些相关的问题。     

高分子支载的金鸡纳生物碱催化剂在不对称催化反应中的应用进展

综述了近年来高分子支载的金鸡纳生物碱催化剂在不对称双羟基化反应、不对称Michael加成反应、活性亚胺的不对称烷基化反应以及潜手性酮的不对称还原反应中的应用及最新进展。     

Nonlinear Effects in Asymmetric Synthesis and Stereoselective Reactions: Ten Years of Investigation

Who would have thought before 1986 that an enantiomerically impure catalyst could give a product in an asymmetric synthesis with an enantiomeric excess higher than that of the catalyst? Until then it was assumed that the ee value of the product (ee_prod) from an asymmetric synthesis was linearly correlated to the ee value of the chiral auxiliary (ee_aux)—in fact a large deviation is possible (see diagram). These nonlinear effects are not only of academic interest since they have a variety of practical uses, which are highlighted in this review.     

Asymmetric Catalysis with Chiral Frustrated Lewis Pairs

The chemistry of frustrated Lewis pairs (FLPs) provides the most important approach for the metal‐free hydrogenation and hydrosilylations. Great progress has been achieved in this area for the past decade. Some promising results have also been obtained. This perspective article mainly focuses on the recent advances for the synthesis of chiral Lewis acidic boranes in category of three protocols, 1) hydroboration of chiral internal alkenes with Piers’ borane HB(C₆F₅)₂; 2) in situ hydroboration of chiral alkenes or alkynes without any purification; 3) and substitution reaction of (C₆F₅)_nBCl_3–n with chiral organometallic reagents, as well as their applications in the metal‐free asymmetric hydrogenations and hydrosilylations.

     

Sharpless Asymmetric Aminohydroxylation: Scope,Limitations, and Use in Synthesis

As a valuable methodology for organic synthesis , asymmetric aminohydroxylation (AA)—the catalytic and asymmetric conversion of alkenes into enantiomerically enriched N‐protected amino alcohols—has become established in a remarkably short period of time. Examples of the types of products that can be synthesized easily on a reasonably large scale and in enantiomerically pure form are shown in the picture.     

Triphase Catalysis [New synthetic methods (27)]

Triphase catalysis (TC) has recently been introduced as a unique form of heterogeneous catalysis in which the catalyst and each of a pair of reactants are located in separate phases. Based on this concept, new synthetic methods have been developed for aqueous phase–organic phase reactions using a solid phase catalyst. Although it is only at an early stage of development, TC shows considerable potential for practical use. Our mechanistic understanding of these highly complex catalytic systems is at present very limited and detailed examination will be required before their relationship to phase-transfer, micellar, and interfacial catalysis becomes clear.     

The Directed Synthesis of Biaryl Compounds: Modern Concepts and Strategies

The preparation and utilization of specific biaryl systems, particularly those which suffer hindered rotation, is a demanding goal not only in the synthesis of natural products and Pharmaceuticals, but also for example in the discovery of new reagents for asymmetric synthesis. This article will attempt to provide a topical review of modern, efficient processes for the specific preparation of biaryls. This appears to be of particular urgency, since, under the pressure of continually increasing demand, a wealth of new or modified synthetic approaches to the ever more important biaryl systems has been realized in recent years. The high standard which has been reached in this field is impressively demonstrated by regio- and stereoselective syntheses of important biaryl natural products such as steganone, ancistrocladine, ancistrocladisine, and dioncophylline A. Besides the utilization of asymmetric induction in the actual coupling step, the thermodynamically or kinetically controlled torsion of biaryl axes belongs to the most important concepts discussed.     

Hydroxide Ion Initiated Reactions Under Phase Transfer Catalysis Conditions: Mechanism and Implications. New Synthetic Methods (62)

The development of Phase Transfer Catalysis (PTC) represents a major step forward in the employment of many organic reactions and renders them very convenient and useful processes. These reactions involve the application of nucleophiles in general, anions and bases in particular, in reactions carried out in a water-organic solvent system. They can be performed both in the laboratory and on an industrial scale. The ease of application of PTC processes is the main reason for their increasing utilization in industry. An outstanding achievement of this technique is the employment of aqueous bases in reactions which traditionally would otherwise require a strong base in a nonaqueous medium. The classical procedures that require severe anhydrous conditions, expensive solvents and dangerous bases such as metal hydrides and organometallic reagents are now replaced by aqueous solutions of, e.g., sodium or potassium hydroxides (PTC/OH processes). In contrast to the extensive synthetic applications of PTC/OH systems, the detailed mechanisms of these processes have been the subject of a great deal of controversy and various mechanisms have been suggested. However, it would seem that our knowledge concerning the mechanistic aspects of such reactions has now reached the stage where it can be used to advantage in synthesis planning. A better understanding of the various factors which influence the reaction would undoubtedly help to optimize PTC/OH processes such as to enable higher yields in shorter reaction times at lower temperatures. The importance of, inter alia, the catalyst will be pointed out and it is highly recommended that such catalysts be always available in the laboratory, for the range of organic reactions that they can efficiently, conveniently and safely catalyze is vast indeed.     

Axially Chiral Aryl‐Alkene‐Indole Framework: A Nascent Member of the Atropisomeric Family and Its Catalytic Asymmetric Construction

A new class of axially chiral aryl‐alkene‐indole frameworks have been designed, and the first catalytic asymmetric construction of such scaffolds has been established by the strategy of organocatalytic (Z/E)‐selective and enantioselective (4+3) cyclization of 3‐alkynyl‐2‐indolylmethanols with 2‐naphthols or phenols (all >95 : 5 E/Z, up to 98% yield, 97% ee). This reaction also represents the first catalytic asymmetric construction of axially chiral alkene‐heteroaryl scaffolds, which will add a new member to the atropisomeric family. This approach has not only confronted the great challenges in constructing axially chiral alkene‐heteroaryl scaffolds but also provided a powerful strategy for the enantioselective construction of axially chiral aryl‐alkene‐indole frameworks.     

负载化的手性双(口,恶)唑啉配体在不对称催化中应用

负载化的手性双唑啉配体广泛应用于不对称催化领域,具有小分子配体所不具备的可回收再利用的特点。本文主要介绍了不同类型的负载化手性双唑啉配体以及它们在不对称催化领域中的应用。     

Advances in Phase-Transfer Catalysis [New synthetic methods (20)]

Phase-transfer catalysis (PTC) has grown into a versatile preparative method in the last few years. The most notable new developments include the use of crown ethers as phase-transfer catalysts and the introduction of solid-liquid PTC. Some representative examples have been selected from the large number of new PTC reactions and some of them are summarized in tables.     

The Concept of Docking/Protecting Groups in Biohydroxylation

A general principle for biohydroxylation , in which time-consuming screening and enrichment techniques are avoided, is demonstrated by the introduction of a docking/protecting group into the substrate. This facilitates acceptance by the microorganism and allows the use of a narrow range of microorganisms, for example Beauveria bassiana ATTC 7159 (B. b.), for the hydroxylation of compounds with diverse structures. After the biohydroxylation, the docking/protecting group is removed (see scheme).     

Amine Additives Greatly Expand the Scope of Asymmetric Hydrosilylation of Imines

Slow addition of a primary amine to the reaction mixture greatly increases the scope of the titanium-catalyzed asymmetric reduction of imines 1 . An important added feature of this method is that chiral secondary amines 2 can be obtained in much higher optical purity (up to 99 % ee) than would be predicted from the E:Z ratios of the starting imines 1 .