Asymmetric cinchona-based phase-transfer

In the presence of cinchona derivatives as catalysts, peroxides or hypochlorites as Michael donors react with electron-deficient olefins to give epoxides via conjugate addition-intramolecular cyclization sequence reactions. Two complementary methodologies have been developed for the asymmetric epoxidation of electron-poor olefins, in which either cinchona-based phase-transfer catalysts or 9-amino-9(deoxy)-epi-dnchona alkaloids are used as organocatalysts. Mechanistically, in these two... 

Asymmetric Cycloaddition Catalyzed by Cinchona-Based Phase-Transfer Catalysts... 

Esters 16b,c are used in reactions catalyzed by cinchona alkaloid-based phase-transfer catalysts, since the size of the ester is important for efficient asymmetric induction in these reactions [35], However, the syntheses of esters 16b,c adds considerable cost to any attempt to exploit this chemistry on a commercial basis. Fortunately, it was possible to develop reaction conditions which allowed the readily available and inexpensive substrate 16a to be alkylated with high enantios-electivity using catalyst 33 and sodium hydroxide, as shown in Scheme 8.18 [36]. The key feature of this modified process is the introduction of a re-esterification step following alkylation of the enolate of compound 16a. It appears that under... 

In 1989, O Donnell and coworkers successfully utilized cinchona alkaloid-derived chiral quaternary ammonium salts for the asymmetric synthesis of a-amino acids using tert-butyl glycinate benzophenone Schiff base 1 as a key substrate [5]. The asymmetric alkylation of 1 proceeded smoothly under mild phase-transfer... 

Consequently, Dehmlow and coworkers modified the cinchona alkaloid structure to elucidate the role of each ofthe structural motifs of cinchona alkaloid-derived chiral phase-transfer catalysts in asymmetric reactions. Thus, the quinoline nucleus of cinchona alkaloid was replaced with various simple or sterically bulky substituents, and the resulting catalysts were screened in asymmetric reactions (Scheme 7.2). The initial results using catalysts 8-11 in the asymmetric borohydride reduction of pivalophenone, the hydroxylation of 2-ethyl-l-tetralone and the alkylation of SchifF s base each exhibited lower enantiomeric excesses than the corresponding cinchona alkaloid-derived chiral phase-transfer catalysts [14]. 

Aldol reactions using a quaternary chinchona alkaloid-based ammonium salt as orga-nocatalyst Several quaternary ammonium salts derived from cinchona alkaloids have proven to be excellent organocatalysts for asymmetric nucleophilic substitutions, Michael reactions and other syntheses. As described in more detail in, e.g., Chapters 3 and 4, those salts act as chiral phase-transfer catalysts. It is, therefore, not surprising that catalysts of type 31 have been also applied in the asymmetric aldol reaction [65, 66], The aldol reactions were performed with the aromatic enolate 30a and benzaldehyde in the presence of ammonium fluoride salts derived from cinchonidine and cinchonine, respectively, as a phase-transfer catalyst (10 mol%). For example, in the presence of the cinchonine-derived catalyst 31 the desired product (S)-32a was formed in 65% yield (Scheme 6.16). The enantioselectivity, however, was low (39% ee) [65],... 

Alkylations. Highly enantioselective alkylation of t-butyl 4,4-bis (p-dimethyl-aminophenyl)-3-butenoate and t-butyl A -diphenylmethyleneglycine in the presence of a quatemized cinchona alkaloid results. The salt plays a dual role in asymmetric induction and as a phase-transfer catalyst. The products from the former reaction can be cleaved at the double bond to furnish chiral malonaldehydic esters which have many obvious synthetic applications. A combination of PTC, LiCl, and an organic base (e.g., DBU) favors the enantioselective alkylation of a chiral A-acylimidazolidinone in which the acyl side chain is derived from glycine. ... 

It has been suggested that cinchona bases, although most valuable chiral auxiliaries (e.g., the AD reaction [5] and asymmetric phase-transfer reactions [6]), are very unlikely to find application as (chiral) building blocks [7]. The recent developments outlined herein will change this view. 

The asymmetric alkylation of glycine derivatives is one of the most simple methods by which to obtain optically active a-amino acids [31]. The enantioselective alkylation of glycine Schiff base 52 under phase-transfer catalysis (PTC) conditions and catalyzed by a quaternary cinchona alkaloid, as pioneered by O Donnell [32], allowed impressive degrees of enantioselection to be achieved using only a very simple procedure. Some examples of polymer-supported cinchona alkaloids are shown in Scheme 3.14. Polymer-supported chiral quaternary ammonium salts 48 have been easily prepared from crosslinked chloromethylated polystyrene (Merrifield resin) with an excess of cinchona alkaloid in refluxing toluene [33]. The use of these polymer-supported quaternary ammonium salts allowed high enantioselectivities (up to 90% ee) to be obtained. 

The asymmetric Darzens reaction of a-chlorocycloalkanones using quatemized cinchona alkaloids as phase-transfer catalyst and LiOH as base in BU2O at room temperature is usually high yielding. However, the moderate ee is disappointing. 

Some other very important events in the historic development of asymmetric organocatalysis appeared between 1980 and the late 1990s, such as the development of the enantioselective alkylation of enolates using cinchona-alkaloid-based quaternary ammonium salts under phase-transfer conditions or the use of chiral Bronsted acids by Inoue or Jacobsen for the asymmetric hydro-cyanation of aldehydes and imines respectively. These initial reports acted as the launching point for a very rich chemistry that was extensively developed in the following years, such as the enantioselective catalysis by H-bonding activation or the asymmetric phase-transfer catalysis. The same would apply to the development of enantioselective versions of the Morita-Baylis-Hillman reaction,to the use of polyamino acids for the epoxidation of enones, also known as the Julia epoxidation or to the chemistry by Denmark in the phosphor-amide-catalyzed aldol reaction. ... 

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