Cinchona first generation

Figure 13.10 First generation of cinchona-based CSPs (25-27) and resolved racemates 28-32 (in parentheses are enantioseparation factors a).

The a-keto ester was hydrogenated to the corresponding a-hydroxy derivative with a Pt/Al203 catalyst, a cinchona alkaloid (chiral modifier) and H2 (60 bar) in toluene or AcOH. This first generation production process was run... 

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). 

TABLE 10.2. Reactions with First- and Second-Generation Cinchona-Derived Catalysts... 

Lectka and coworkers first demonstrated that the ammonium enolates 18 generated from acid chlorides in the presence of a cinchona alkaloid catalyst (BQn, 19) and... 

In this chapter, we review the enantioselective proto nation of enols/enolates where the asymmetry is brought by cinchona alkaloids, either the natural products or some analogues. The cinchona alkaloids may act as a direct protonating agent of enolates or as an acid-base bifunctional catalyst by first deprotonating the substrate to generate the enolate and then, as an acid, by reprotonating the carbanion. 

The power of column-like reactors for continuous flow processes lies in the possibility to sequentially link them up in order to carry out multistep syntheses in solution in one run (see also Schemes 1 and 2). Lectka and coworkers utilized conventional fritted and jacketed columns for this purpose. These columns were filled with conventional functionalized polymeric beads [47]. The continuous flow was forced by gravity. En route to / -lactams polymer beads functionalized with the Schwesinger base 17, a cinchona alkaloid derivative 18 as a chiral catalyst, and a primary amine 19 were sequentially employed. They first guaranteed the generation of phenyl ketene from phenyl... 

The first organocatalytic asymmetric aziridination reactions of electron-deficient olefins made use of either (i) a chiral tertiary amine combined with a 0-phosphinyl or sulfonyl hydroxylamine for the in situ generation of aminimides as aziridination reagents [133, 134], or (ii) a quaternary salt of cinchona alkaloids in phase-transfer catalysis in combination with ethyl nosyloxycarbamate [135], A-acyl A-aryl... 

The asymmetric a-sulfenylation of ketones is a particularly challenging reaction, as demonstrated by the poor success reported in the stereoselective variants via classical enolate/azaenolate reaction with an electrophilic sulfur reagent [71]. An umpolung approach has been devised by Coltart and co-workers [72] to effect the first asymmetric a-sulfenylation of ketones with arene thiols. Nitroso alkene derivatives, in i/tM-generated under basic conditions from a-chloro oximes, reacted with arene thiols in the presence of cinchona thiourea 27, which promoted the conjugate addition of thiophenol (Scheme 14.25). The chiral nonracemic a-sulfenylated oximes were directly hydrolyzed by IBX to ketones in high yield and good enantioselectivity. 

The first catalytic asymmetric Staudinger reaction to be described used chiral tertiary amines 14 and 15 derived from the Cinchona alkaloids as the nucleophile to activate the ketene via zwitterion formation. The ketene was conveniently generated in situ from the acid chloride. Because the HCl generated in the elimination would consume the chiral tertiary amine catalyst, a nonnucleophilic strong base (e.g.. Proton Sponge) was included to remove the HCl formed. Yields of -lactams were on the order of 60% in 99% ee. 

In the same context, Loh et al. have developed the first organocatalytic and enantioselective direct vinylogous Michael addition of a,a-dicyanoolefins to maleimides performed in the presence of the cinchona alkaloid depicted in Scheme 1.26. This novel procedure generated the corresponding Michael anti-products in good yields with excellent diastereo- and enantioselectivities of up to 99% ee, as shown in Scheme 1.26. In this study, the authors have demonstrated that the free hydroxyl group of the catalyst played a key role in the substrate activation. 

Cinchona alkaloid-derived ammonium phenoxides as Lewis base catalysts have been appUed to asymmetric vinylogous Mukaiyama-type aldol reactions (Scheme 14.8) [30]. In the first step of this reaction, silyl compound 14 reacts with ammonium phenoxide to produce ammonium dienolate 15 with generation of trimethyl(phenoxy) silane. The latter part of this reachon mechanism is basically simQar to the reaction mechanism of ammonium fluoride-catalyzed reactions with silyl nucleophiles as shown in Scheme 14.7. This reaction system was also appUed to other asymmetric transformations [6a, 31]. 

Mannich Reaction Carbamate-protected alkyl imines are important building blocks in the synthesis of chiral alkyl amines. However, they are usually unstable, and most of them cannot be prepared in pure form. As the optimal substitutes, a-amido sulfones 142 were first used in the PTC-catalyzed enantioselective aza-Henry reaction in 2005 [57]. Subsequently, Song et al. reported a chiral Cinchona alkaloid thiourea (130b)-catalyzed Mannich reaction with in situ generation of... 

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