Amine cinchona alkaloids

Not so long ago, the general opinion was that high enantioselectivity can only be achieved with natural, structurally unique, complex modifiers as the cinchona alkaloids. Our results obtained with simple chiral aminoalcohols and amines demonstrate the contrary. With enantiomeric excesses exceeding 80%, commercially available naphthylethylamine is the most effective chiral modifier for low-pressure hydrogenation of ethyl pyruvate reported to... 

Pt/Al2C>3-cinchona alkaloid catalyst system is widely used for enantioselective hydrogenation of different prochiral substrates, such as a-ketoesters [1-2], a,p-diketones, etc. [3-5], It has been shown that in the enantioselective hydrogenation of ethyl pyruvate (Etpy) under certain reaction conditions (low cinchonidine concentration, using toluene as a solvent) achiral tertiary amines (ATAs triethylamine, quinuclidine (Q) and DABCO) as additives increase not only the reaction rate, but the enantioselectivity [6], This observation has been explained by a virtual increase of chiral modifier concentration as a result of the shift in cinchonidine monomer - dimer equilibrium by ATAs [7],... 

The most successful modifier is cinchonidine and its enantiomer cinchonine, but some work in expanding the repertoire of substrate/modifier/catalyst combinations has been reported (S)-(-)-l-(l-naphthyl)ethylamine or (//)-1 -(I -naphth T)eth Tamine for Pt/alumina [108,231], derivatives of cinchona alkaloid such as 10,11-dihydrocinchonidine [36,71], 2-phenyl-9-deoxy-10, 11-dihydrocinchonidine [55], and O-methyl-cinchonidine for Pt/alumina [133], ephedrine for Pd/alumina [107], (-)-dihydroapovincaminic acid ethyl ester (-)-DHVIN for Pd/TiOz [122], (-)-dihydrovinpocetine for Pt/alumina [42], chiral amines such as 1 -(1 -naphtln I)-2-(I -pyrro 1 idiny 1) ethanol, l-(9-anthracenyl)-2-(l-pyrrolidinyl)ethanol, l-(9-triptycenyl)-2-(l-pyrrol idi nyl)cthanol, (Z )-2-(l-pyrrolidinyl)-l-(l-naphthyl)ethanol for Pt/alumina [37,116], D- and L-histidine and methyl esters of d- and L-tryptophan for Pt/alumina [35], morphine alkaloids [113],... 

Preliminary mechanistic studies show no polymerization of the unsaturated aldehydes under Cinchona alkaloid catalysis, thereby indicating that the chiral tertiary amine catalyst does not act as a nucleophilic promoter, similar to Baylis-Hilhnan type reactions (Scheme 1). Rather, the quinuclidine nitrogen acts in a Brpnsted basic deprotonation-activation of various cychc and acyclic 1,3-dicarbonyl donors. The conjugate addition of the 1,3-dicarbonyl donors to a,(3-unsaturated aldehydes generated substrates with aU-carbon quaternary centers in excellent yields and stereoselectivities (Scheme 2) Utility of these aU-carbon quaternary adducts was demonstrated in the seven-step synthesis of (H-)-tanikolide 14, an antifungal metabolite. 

The majority of the Michael-type conjugate additions are promoted by amine-based catalysts and proceed via an enamine or iminium intermediate species. Subsequently, Jprgensen et al. [43] explored the aza-Michael addition of hydra-zones to cyclic enones catalyzed by Cinchona alkaloids. Although the reaction proceeds under pyrrolidine catalysis via iminium activation of the enone, and also with NEtj via hydrazone activation, both methods do not confer enantioselectivity to the reaction. Under a Cinchona alkaloid screen, quinine 3 was identified as an effective aza-Michael catalyst to give 92% yield and 1 3.5 er (Scheme 4). 

Highly enantioselective organocatalytic Mannich reactions of aldehydes and ketones have been extensively stndied with chiral secondary amine catalysts. These secondary amines employ chiral prolines, pyrrolidines, and imidazoles to generate a highly active enamine or imininm intermediate species [44], Cinchona alkaloids were previonsly shown to be active catalysts in malonate additions. The conjngate addition of malonates and other 1,3-dicarbonyls to imines, however, is relatively nnexplored. Snbseqnently, Schans et al. [45] employed the nse of Cinchona alkaloids in the conjngate addition of P-ketoesters to iV-acyl aldimines. Highly enantioselective mnltifnnctional secondary amine prodncts were obtained with 10 mol% cinchonine (Scheme 5). 

Based on prior results where Ricci used Cinchona alkaloids as phase-transfer-catalysts, the group proceeded to look at hydrophosphonylation of imines [48], Employing the chiral tertiary amine as a Brpnsted base, a-amino phosphonates products were synthesized in high yields and good selectivities. 

Another type of Cinchona alkaloid catalyzed reactions that employs azodicarbo-xylates includes enantioselective allylic amination. Jprgensen [51-53] investigated the enantioselective electrophilic addition to aUyhc C-H bonds activated by a chiral Brpnsted base. Using Cinchona alkaloids, the first enantioselective, metal-free aUyhc amination was reported using alkylidene cyanoacetates with dialkyl azodi-carboxylates (Scheme 12). The product was further functionalized and used in subsequent tandem reactions to generate useful chiral building blocks (52, 53). Subsequent work was applied to other types of allylic nitriles in the addition to a,P-unsaturated aldehydes and P-substituted nitro-olefins (Scheme 13). 

Wang and co-workers reported a novel class of organocatalysts for the asymmetric Michael addition of 2,4-pentandiones to nitro-olefms [131]. A screen of catalyst types showed that the binaphthol-derived amine thiourea promoted the enantiose-lective addition in high yield and selectivity, unlike the cyclohexane-diamine catalysts and Cinchona alkaloids (Scheme 77, Table 5). 

Although, from a historical standpoint the cinchona alkaloids also occupy a central position in the field owing to their use as catalysts for the alcoholative ASD of meso anhydrides (a Type II process, see Schane 2), the past few years have witnessed an explosion of interest in the development of other classes of iert-amine-based catalysts primarily for Type I processes. 

Certain tertiary amines such as pyridine or a-quinuclidine accelerate the stoichiometric reaction between osmium tetroxide and olefins (86). An asymmetric olefin osmylation using stoichiometric amounts of cinchona alkaloids as the chiral ligands was described in 1980 (87a). Optical yields of up to 90% were attained with frans-stilbene as substrate. 

Cinchona alkaloids, naturally ubiquitous /3-hydroxy tertiary-amines, are characterized by a basic quinuclidine nitrogen surrounded by a highly asymmetric environment (12). Wynberg discovered that such alkaloids effect highly enantioselective hetero-[2 -I- 2] addition of ketene and chloral to produce /3-lactones, as shown in Scheme 4 (13). The reaction occurs catalytically in quantitative yield in toluene at — 50°C. Quinidine and quinine afford the antipodal products by leading, after hydrolysis, to (S)- and (/ )-malic acid, respectively. The presence of a /3-hydroxyl group in the catalyst amines is not crucial. The reaction appears to occur... 

In particular, it is not only the cinchona alkaloids that are suitable chiral sources for asymmetric organocatalysis [6], but also the corresponding ammonium salts. Indeed, the latter are particularly useful for chiral PTCs because (1) both pseudo enantiomers of the starting amines are inexpensive and available commercially (2) various quaternary ammonium salts can be easily prepared by the use of alkyl halides in a single step and (3) the olefin and hydroxyl functions are beneficial for further modification of the catalyst. In this chapter, the details of recent progress on asymmetric phase-transfer catalysis are described, with special focus on cinchona-derived ammonium salts, except for asymmetric alkylation in a-amino acid synthesis. 

Cinchona alkaloids, of course, have occupied the central position in the design of chiral PTCs. By employing a simple chemical transformation of the tertiary amine ofthe natural cinchona alkaloids to the corresponding quaternary ammonium salts, using active halides (e.g., aryl-methyl halides), a basic series of PTCs can be readily prepared. Cinchona alkaloid-derived PTCs have proved their real value in many types of catalytic asymmetric synthesis, including a-alkylation of modified a-amino acids for the synthesis of higher-ordered a-amino acids [2], a-alkylation of... 

The role of some chiral bifunctional amines and optically active cinchona alkaloid derivatives (Figure 3) as catalysts has been explored in catalytic asymmetric Staudinger reactions. Bicarbonate salts have been used as viable alternatives to... 

Further developments by Deng et al. on the a-amination of a-cyanoacetates 12 (Eq. 4) showed that G -OH-modified cinchona alkaloids, which are accessible from either quinine or quinidine, were also effective catalysts for the reaction leading to optically active products in 71-99% yield and up to 99% ee [11]. 

Catalyst 3 is proposed to function in a manner similar to the cinchona alkaloid catalysts (1 and 2), with the tertiary amine providing activation for the nucleophilic thiol, which is held in close proximity to the thiourea-bound carbonyl substrate. 

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