Cinchonine catalysts

A soln. of startg. ketone in toluene, triethyl phosphite (for in situ reduction of labile hydroperoxide intermediates), and 5 mol% of the chiral cinchonine catalyst added successively to 50% aq. NaOH, and the mixture stirred vigorously at room temp, with 02-bubbling for 5 h - (S)-product. Y 95% (e.e. 79%). F.e. and cyclic p,y-ethylene-a-hydroxyketones from a,P-ethyleneketones s. M. Masui et al., Tetrahedron Letters 29, 2835-8 (1988). 

In another context, a chiral phase-transfer A-9-anthracenylmethyl O-ada-mantoyl derivatised cinchonine catalyst was shown to promote the asymmetric ring-opening of A7-tosyl protected aziridines with cyclic p-keto esters in the presence of an aqueous base, leading to the formation of chiral aminoethyl... 

The hydrogenation of the esters methyl tiglate, methyl trifluorotiglate, and methyl angelate occurred slowly over 1% Pd/SiOa at room temperature and 10 bar pressure. Modification of the catalyst by cinchonidine or cinchonine induced no enantioselectivity under any conditions Typical results are given in Table 2. 

Hydrogenation of the free acids over unmodified catalyst occurred slowly, proceeded to completion in 20 h and gave racemic product as expected Enantioselective hydrogenation occurred at a slower rate over alkaloid-modified catalyst, cinchonidine modification providing an excess of S-product and cinchonine an excess ofR-product... 

The hydrogenation of methyl pyruvate proceeded over 4% Pd/Fe20 at 293 K and 10 bar when the catalyst was prepared by reduction at room temperature Racemic product was obtained over utunodified catalyst, modification of the catalyst with a cinchona alkaloid reduced reaction rate and rendered the reaction enantioselective. S-lactate was formed in excess when the modifier was cinchonidine, and R-lactate when the modifier was cinchonine... 

Table 3), Enantioselective reaction was of order 0 7 in hydrogen by the initial rate method (over the range 2 to 50 bar, 293 K, cinchonine modifier) and 0 2 in pyruvate (0 1 to 3.0 M, 293 K, 10 bar pressure, cinchonine modifier) Enantiomeric excess was independent of reactant concentrations within these ranges Reactions exhibited self-poisoning so that complete conversion was not achieved within 20 h reaction time. As the quantity of cinchonine modifier added to the catalyst was increased from zero to 1 gram per gram so the... 

Catalytic enantioselective nucleophilic addition of nitroalkanes to electron-deficient alke-nes is a challenging area in organic synthesis. The use of cinchona alkaloids as chiral catalysts has been studied for many years. Asymmetric induction in the Michael addition of nitroalkanes to enones has been carried out with various chiral bases. Wynberg and coworkers have used various alkaloids and their derivatives, but the enantiomeric excess (ee) is generally low (up to 20%).199 The Michael addition of methyl vinyl ketone to 2-nitrocycloalkanes catalyzed by the cinchona alkaloid cinchonine affords adducts in high yields in up to 60% ee (Eq. 4.137).200... 

The enantioselective hydrogenation of prochiral substances bearing an activated group, such as an ester, an acid or an amide, is often an important step in the industrial synthesis of fine and pharmaceutical products. In addition to the hydrogenation of /5-ketoesters into optically pure products with Raney nickel modified by tartaric acid [117], the asymmetric reduction of a-ketoesters on heterogeneous platinum catalysts modified by cinchona alkaloids (cinchonidine and cinchonine) was reported for the first time by Orito and coworkers [118-121]. Asymmetric catalysis on solid surfaces remains a very important research area for a better mechanistic understanding of the interaction between the substrate, the modifier and the catalyst [122-125], although excellent results in terms of enantiomeric excesses (up to 97%) have been obtained in the reduction of ethyl pyruvate under optimum reaction conditions with these Pt/cinchona systems [126-128],... 

The first practical and efficient asymmetric alkylation by use of chiral phase-transfer catalysts was the alkylation of the phenylindanone 15 (R1=Ph), reported by the Merck research group in 1984.114-161 By use of the quaternary ammonium salt 7 (R=4-CF3i X=Br) derived from cinchonine, the alkylated products 16 were obtained in excellent yield with high enantiomeric excess, as shown in... 

The first promising asymmetric aldol reactions through phase transfer mode will be the coupling of silyl enol ethers with aldehydes utilizing chiral non-racemic quaternary ammonium fluorides,1371 a chiral version of tetra-n-butylammonium fluoride (TBAF). Various ammonium and phosphonium catalysts were tried138391 in the reaction of the silyl enol ether 41 of 2-methyl-l-tetralone with benzaldehyde, and the best result was obtained by use of the ammonium fluoride 7 (R=H, X=F) derived from cinchonine,1371 as shown in Scheme 14. 

The catalytic asymmetric Horner-Wadsworth-Emmons reaction was realized by use of the quaternary ammonium salts 7 derived from cinchonine as a phase transfer catalyst.1631 Thus, tert-butylcyclo-hexanone 85 reacted with triethyl phosphonoacet-ate 86 together with RbOH-H20 in the presence of the ammonium salts 7, and then the product 87 was isolated after reesterification by treatment with acidic ethanol, as shown in Scheme 27 Among the... 

Asymmetric oxygenation of ketones.1 Oxygenation of the achiral ketone 1 in the presence of this chiral phase-transfer catalyst derived from cinchonine results... 

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],... 

The structures of quinine, cinchonidine, quinidine, and cinchonine are shown in Figure 3. Other workers (16,17) have discussed these alkaloids and their use as catalysts in some detail. An excellent discussion of cinchona-alkaloid-catalyzed reactions prior to 1968 was given by Pracejus (18). In this section we discuss only four aspects of these reactions. 

Quinine and quinidine, as well as cinchonidine and cinchonine, are diastereo-meric pairs. However, at the critical sites—the P-hydroxyamine portions of the molecules—they are enantiomeric. Thus if quinine is used as the chiral catalyst in an asymmetric transformation (i.e., with one enantiomer being formed in excess), the other enantiomer is formed in excess when quinidine is used. Table 2 gives a representative example, the thiol addition reaction (19). 

These reactions, performed many times, show, in addition to the reversal of the absolute configuration of the product with the change in the configuration at C-8 and C-9 of the alkaloids, a small but reproducible difference in the e.e. of the product. It is evident that the diastereomeric nature of quinine vs. quinidine and cinchonidine vs. cinchonine expresses itself via small but important energy differences in the best fits of the transition states. Noteworthy in this respect is the fine work of Kobayashi (20), who observed larger differences (in the e.e. s of products) when the diastereomeric cinchona alkaloids were used as catalysts after having been copolymerized with acrylonitrile (presumably via the vinyl side chain of the alkaloids). 

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). 

Chen and co-workers presented, in 2007, a Michael-type Friedel-Crafts reaction of 2-naphthols and trans-P-nitroalkenes utilizing the bifunctional activating mode of cinchonine-derived catalyst 117 [277]. The nitroalkene was activated and steri-cally orientated by double hydrogen bonding, while the tertiary amino group interacts with the naphthol hydroxy group to activate the naphthol for the nucleophilic P-attack at the Michael acceptor nitroalkene (Scheme 6.117). 

A cursory examination of the Cinchona catalysts used in O Donnell-type alkylation [90] of methyl (diphenylimino)glycinate (Appendix 7.A) reveals that only minor modifications to the Cinchona scaffold are required for the synthesis of a catalyst the 8-substituent on the quinuclidine core may either be a vinyl group (as in the parent alkaloids, quinine and quinidine) or can be an ethyl substituent, introduced by hydrogenation. The quinoline system at the 2-position ofthe quinuclidine ring can be unsubstituted if the catalyst is derived from quinine or quinidine, but can contain a 6-methoxy group ifit is derived from cinchonine or cinchonidine. The 3-position ofthe quinuclidine ring may contain either a hydroxy group or else a vinyloxy or benzyloxy... 

For the Pt/cinchona catalysts only preliminary adsorption studies have been reported [30]. From the fact that in situ modification is possible and that under preparative conditions a constant optical yield is observed we conclude that in this case there is a dynamic equilibrium between cinchona molecules in solution and adsorbed modifier. This is supported by an interesting experiment by Margitfalvi [63] When cinchonine is added to the reaction solution of ethyl pyruvate and a catalyst pre-modified with cinchonidine, the enantiomeric excess changes within a few minutes from (R)- to (S)-methyl lactate, suggesting that the cinchonidine has been replaced on the platinum surface by the excess cinchonine. 

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