Development of a recyclable fluorous chiral phase-transfer catalyst: application to the catalytic asymmetric synthesis of alpha-amino acids

[structure: see text] A recyclable fluorous chiral phase-transfer catalyst was synthesized and successfully applied for the catalytic asymmetric synthesis of both natural and unnatural alpha-amino acids. The reaction involves alkylation of a glycine derivative followed by extractive recovery of the chiral phase-transfer catalyst using fluorous solvent.     

An Asymmetric Synthesis of Isoindolinones

Recently, the results from this laboratory showed that the reductive alkylation of protected (S)-malimide could be achieved in a high regio- and diastereoselective manner. The substituted 2-pyrrolidinones thus formed are versatile chiral building blocks which can be used in the asymmetric synthesis of pyrrolidines^[1,2],2-pyrrolidinones^[3,4] and β-hydroxy-γ-amino acids^[5,6]. As an extension of this work, and in combination with the current interest in the synthesis of isoindolin-1-ones, a study on the asymmetric reductive alkylation of phthalimide derived from (R)-phenylglycinol was undertaken.     

Enantioselective Hydroarylation of Olefins Using Palladium/Chiral Quinoline Oxazolines

Palladium-catalyzed arylation and alkenylation of olefins, known as the Heck reaction, is one of the most efficient catalytic methods for carbon-carbon bond formation in organic synthesis^[1]. During the last decade, asymmetric Heck reactions have attracted great attention, and a number of highly enantioselective chiral ligands have been developed to enhance chiral discrimination in these reactions^[2]. However, asymmetric Heck-type hydroarylations of olefins, addition of aryl halides or triflates to carbon-carbon double bonds, have not been well studied. In 1991, Brunner reported an asymmetric hydroarylation of norbornene and norbornadiene with aryl iodides using chiral bisphosphine ligands, and around 40% ee was achieved^[3]. Later on, Achiwa reached around 70% ee in the asymmetric hydroarylation of norbornene with phenyl triflate by using chiral P-N ligands^[4,5]. Herein, we wish to describe our investigations on chiral quinolinyl-oxazoline ligands that provide the first examples of efficient bisnitrogen ligands in Heck-type hydroarylation and the application of this reaction in the asymmetric synthesis of Epibatidine.     

Catalytic asymmetric synthesis of 1,1-disubstituted tetrahydro-β-carbolines by phase-transfer catalyzed alkylations

Efficient catalytic asymmetric synthesis of 1,1-disubstituted tetrahydro-β-carbolines has been achieved via asymmetric alkylation of 1-cyanotetrahydro-β-carbolines using a binaphthyl-modified N-spiro-type chiral phase-transfer catalyst. This is a valuable example of hitherto difficult highly enantioselective alkylations at α-carbon of the cyano group under phase-transfer conditions.     

A New Approach in Enantioselective Catalytic with Bis(oxazoline) Ligand-Metal Complexes

In recent years, the research of enantioselective-catalyzed reaction and the catalyst has got great development. Of the various chiral catalysts, great attention was given to the C₂-symmetry chiral bis(oxazoline)ligand-metal complexes for they could be easily synthesized and have shown good enantioselection in various catalytic processes, including cyclopropanation from dihalogenmethane^[1] and diazoacetate^[2].But no report has been found of enantioselective-catalyzed cyclopropanation from sulfonyl-carbanions and alkenes. The test of chiral cyclopropanation from sulfonylcarbanions with nickel bis(oxazolinyl)pyridine catalyst has been made in our lab, and alkylation of aldehydes with diethyl zinc in the presence of nickel or iron bis(oxazolinyl)pyridine was also tested (scheme 1). Some asymmetric effects were observed in these reactions.     

Planar Chiral Ligands:Design and Applications in Asymmetric Synthesis

Chiral ligands play an important role in asymmetric synthesis. Among them the ligands having planar chirality attract more interesting of organic chemists because of their unique structure. Recently, some new types of planar chiral ligands, including 1,1'-disubstituted ferrocene 1, bis(ferrocene carboxylic)diaminocyclohexane 2, and benzylic substituted cyclophane 3, are synthesized (Scheme 1)^[1]. These chiral ligands have been successfully used in asymmetric allylic alkylation, Heck reaction, etc. The role of planar chirality in asymmetric induction by using NMR and X-ray are also studied.     

Orthopalladated complexes as phase-transfer catalysts for asymmetric alkylation of achiral Schiff base esters

The asymmetric C-alkylation of benzophenone Schiff base glycine esters has been achieved using a palladium(II) chiral complex as a phase-transfer catalyst. The aromatic moiety around the metal center and various physicochemical parameters were investigated to study their effect on the asymmetric alkylation reaction under phase-transfer conditions. Moderate enantioselectivity(30–40%) was achieved under room temperature conditions, which is a significant improvement compared to no enantioselectivity with a chiral palladium-salen complex reported earlier. Computer simulation studies indicate that coordination of the metal center with Z-enolate forming a square planar complex provides a favorable steric environment where the α-carbon atom of the enolate is available for enantioselective alkylation.     

Design of N-spiro C2-symmetric chiral quaternary ammonium bromides as novel chiral phase-transfer catalysts: synthesis and application to practical asymmetric synthesis of alpha-amino acids

A series of C(2)-symmetric chiral quaternary ammonium bromides 10 and 11 have been designed as a new, purely synthetic chiral phase-transfer catalyst, and readily prepared from commercially available optically pure 1,1'-bi-2-naphthol as a basic chiral unit. The details of the synthetic procedures of each requisite chiral binaphthyl subunit have been disclosed, and the structures of the assembled N-spiro chiral quaternary ammonium bromides 11a and 11f were unequivocally determined by single-crystal X-ray diffraction analysis. The reactivity and selectivity of these chiral ammonium bromides as chiral phase-transfer catalysts have been evaluated in the asymmetric alkylation of the benzophenone Schiff base of glycine ester 7 under mild liquid-liquid phase-transfer conditions, and the optimization of the reaction variables (solvent, base, and temperature) has also been conducted. Further, the scope and limitations of this asymmetric alkylation have been thoroughly investigated with a variety of alkyl halides, in which the advantage of the unique N-spiro structure of 11 and dramatic effect of the steric as well as the electronic properties of the aromatic substituents on the 3,3'-position of one binaphthyl moiety have been particularly emphasized. Finally, the potential synthetic utility of the present method for the practical asymmetric synthesis of structurally diverse natural and unnatural alpha-amino acids has been demonstrated by its successful application to the facile asymmetric syntheses of (S)-N-acetylindoline-2-carboxylate, a key intermediate in the synthesis of the ACE inhibitor, and l-Dopa (l-3,4-dihydroxyphenylalanine) ester and its analogue.     

Chiral Resolution of l,l'-Binaphthalene-2, 2'-Diol and its (-)-Menthyl Chloroformate derivatives by HPLC with Urea Derivative as Chiral Stationary Phase

Optically pure l,1'-binaphthalene-2,2'-diols are very useful compounds for various application^[1] such as catalyst ligands for asymmetric synthesis, the starting materials for other chiral binaphthyl catalysts and resolving agents for racemic compounds. Consequently, the preparation of optically pure l,l'-binaphthalene-2,2'-diols are of current interest Recently, new methods of resolution of racemic l,1'-binaphthalene-2,2'-diols utilizing (-)-(lR)-menthyl chloroformate as the derivatization agent have been developed^[2,3]. To determine the optical purity of these 1,1'-binaphthalenes, it is necessary to develop a convenient and reliable method for the detection of each stereoisomers.     

New chiral phase-transfer catalysts possessing a 6,6′-bridged ring on the biphenyl unit: application to the synthesis of α,α-dialkyl-α-amino acids

A new chiral phase-transfer catalyst possessing a 6,6′-bridged ring on the biphenyl unit has been developed for the practical synthesis of α,α-dialkyl-α-amino acids. This catalyst shows very high activity for the asymmetric alkylation of an alanine derivative to give α,α-dialkyl-α-amino acid derivatives with high enantioselectivities.     

Chiral phosphine-free Pd-mediated asymmetric allylation of prochiral enolate with a chiral phase-transfer catalyst

[reaction: see text]. A chiral phase-transfer catalyst has been applied to the asymmetric allylation of the tert-butyl glycinate-benzophenone Schiff base with various allylic acetates for the first time to give the allylated products in good yields and with comparable to higher enantioselectivity than for asymmetric alkylation at the same temperature (91-96% ee) without any chiral ligands for coordinating to the palladium.     

Synthesis of Chiral 1,3-Bis(oxazolinyl)benzene

In recent years, C₂-symmetric chiral bis (oxazoline) ligand-metal complexes have received a great of attention through their use in various catalytic processes^[1-2]. Since the early 1990s, many impressive enantioselective carbon-carbon bond forming reactions, aziridination reactions, hydrosilylations, oxidations and reductions have been recorded using bis (oxazoline)-metal complexes with wide structural diversity^[3-4]. The latest review is intended to focus on the recent developments of bis(oxazoline) ligand-metal catalyzed asymmetric reactions and their applications in organic synthesis. Herein we intend to report the synthesis of a new type of chiral bis(oxazoline), 1,3-bis(oxazolinyl)benzene. Application of their asymmetric catalysis is under working.     

Stereocontrolled synthesis of 3-(trans-2-aminocyclopropyl)alanine,a key component of belactosin A

Herein we report a concise synthesis of 3-(trans-2-aminocyclopropyl)alanine, a component of belactosin A, using asymmetric alkylation of a glycine enolate in the presence of chiral phase-transfer catalysts to control the configuration at C2. Reaction of protected glycidol with triethyl phosphonoacetate (Wadsworth-Emmons cyclopropanation) is used for enantiospecific preparation of an intermediate cyclopropanecarboxylate that is converted to a cyclopropylamine via Curtius rearrangement. [reaction: see text]     

Enantioselective Hydrogenation of Acetophenone over Cinchonidine-Stabilized and Supported Rhodium Clusters

Because of the importance of the chirality in chemicals in everyday, the synthesis of enantiomerically pure chiral compounds has become an important academic and commercial advantage. In asymmetric synthesis field, enantioselective catalysis has been the most challenging subject over the past decades. Among the numerous enantioselective heterogeneous catalysts, the rhodium is always an unsuccessful example under favorable reaction conditions with only 20%-30% enantiomeric excess (e.e.)^[1].And almost all of papers about heterogeneous enantioselective catalysis have reported that rhodium is not suitable for heterogeneous enantioselective hydrogenation^[1-3].     

Asymmetric Borohydride Reduction of Acetophenone Catalyzed by Chiral Salen-Co(Ⅱ) Complex Using Sodium Borohydride

Development of efficient catalytic asymmetric reactions is the most challenging task in current synthetic chemistry; much effort has been devoted to create the chiral metal complexes of asymmetric catalysis. In the last two decades' many brand-new ligands had been synthesized and their combination with various metal ions has been applied in asymmetric catalysis. However, most ligands have only narrow applications and their use is limited to some reactions. Exceptionally, a few ligands and their metal complexes such as binaphthol, semicollin,and binap show wide applicability. Chiral salen ligand is one of such ligands and their metal complexes are now used as the catalysts for a variety of asymmetric reactions such as epoxidation^[1], aziridination^[2], cyclopropanation^[3], Diels-Alder reaction^[4], asymmetric transfer hydrogenation of aromatic ketones^[5] and kinetic resolution of racemic epoxides^[6] and so on.     

Organocatalytic asymmetric synthesis of sulfoxides from sulfenic acid anions mediated by a Cinchona-derived phase-transfer reagent

Preliminary results concerning a conceptually novel route to chiral sulfoxides based on the asymmetric alkylation of sulfenate salts with alkyl halides mediated by a chiral phase-transfer catalyst are described. As a representative example, o-anisyl methyl sulfoxide was produced in 96% yield and with an enantiomeric excess of 58% using commercial cinchonidinium derivative 2a.     

Asymmetric synthesis of functionalized aza-cyclic amino acids with quaternary stereocenters by a phase-transfer-catalyzed alkylation strategy

[Reaction: see text] Practical asymmetric synthesis of functionalized aza-cyclic alpha-amino acid derivatives possessing quaternary stereocenters has been achieved by the phase-transfer-catalyzed alkylation of 2 or 3 using chiral quaternary ammonium bromide 1 as catalyst. Subsequent reduction and alkylation of the 3-keto carbonyl moiety of 4 proceeded with complete diastereochemical control to afford the corresponding beta-hydroxy aza-cyclic alpha-amino acid derivatives having stereochemically defined consecutive quaternary carbon centers.     

Improved Alkylation Technology with Solid Acid Material as Catalyst

Alkylation of isobutane with C3-C5 olefins has been practiced commercially since the 1940s. Indeed, alkylation which is mainly formed by multibranched paraffins,has a rather low vapor pressure, high octane numbers (RON and MON) and a low sensitive factor. In the past twelve years, about 20 alkylation plants using either HF or H₂SO₄ catalysts have been built in China^[1]. Concerns have been raised about the safety and environmental impact of the handing of the very large quantities of these liquid acids used in alkylation today and a great deal of time and money has been spent in the past 20 years in attempts to develop alkylation catalyst and process that are more environmentally friend than current industrial technology^[2]. To date,no process has been announced that seems to be of commercial interest, but two possible exceptions (Topöse process and UOP Alkylene process) are discussed in this paper. Many difficult technical challenges must be surmount in the next few years for a new solid catalyst alkylation process to be commercialized successfully.     

Identification of a highly effective asymmetric phase-transfer catalyst derived from α-methylnaphthylamine

A library of quaternary ammonium salts has been generated via reaction of simple chiral amines with a series of conformationally dynamic biphenyl units. Screening of this library against the alkylation of a glycine imine has led to the identification of a highly effective asymmetric phase-transfer catalyst derived from α-methylnaphthylamine.     

钯催化烯基苯并噁嗪酮基于内球型机理的线性和不对称烯丙基烷基化反应

烯基苯并噁嗪酮作为底物参与反应受到有机合成工作者的广泛关注.在过渡金属催化作用下,烯基苯并噁嗪酮脱除一分子二氧化碳,生成的两性离子中间体既可以被亲核试剂进攻,得到结构丰富的芳香胺,也可以作为1,4-偶极子与硫叶立德,缺电子烯烃或α,β-不饱和醛参与成环,分别生成相应的五元、六元或七元含氮杂环.后者广泛存在于农药、医药和...