Pseudoenantiomeric quinidine

Later, the scope of this methodology was successfully extended to the intramolecular version by List and coworkers [14]. By employing 9-amino-9-deoxyepiquinine 24 as a catalyst (20 mol%) and an acid cocatalyst (AcOH, 60 mol%), 5-substituted-3-methyl-2-cydohexene-l-ones (26) were obtained with high enantioselectivity (up to 94% ee) from the diketones 25 via the intramolecular aldol reaction (Scheme 8.8). The chiral enones 26 are valuable synthetic building blocks for the synthesis of many biologically important compounds (e.g., HIV-1 protease-inhibitive didemnaketals). The pseudoenantiomeric quinidine analogue 23 of 24 also provided the opposite... 

Moreover, as is usually found in most of the asymmetric reactions catalyzed by cinchona alkaloid derivatives, the opposite enantiomer of each diaster-eomeric Michael adduct could also be obtained by simply changing the catalyst to the corresponding pseudoenantiomeric quinidine-based compounds of type 83 or 71. Once again, a model was proposed to account for the observed results, involving a conformationally rigid intermediate in which both the pronucleophile and the electrophile were attached to the catalyst by the formation of multiple H-bonds, explaining the reversal of the diastereoselection by the epimeric nature of C-9 in catalyst 71b with respect to 84c. The stereochemical... 

An important contribution elucidating the potential of primary amines derived from Cinchona alkaloids has been the aldol cyclodehydration of achiral 4-substituted-2,6-heptanediones to enantiomerically enriched 5-substituted-3-methyl-2-cyclohexene-l-ones, presented by List and coworkers in 2008 (Scheme 14.26). Both 9-deo>y-9-amino-epr-quinine (QNA) and its pseudoenantiomeric, quinidine-derived amine QDA, in combination with acetic acid as cocatalyst, proved to be efficient and highly enantio-selective catalysts for this transformation, giving both enantiomers of 5-substituted-3-methyl-2-cyclohexene-l-ones with very good results. The authors observed that proline and the catalytic antibody 38C2 delivered poor enantioselectivity in this reaction. Furthermore, the synthetic utility of the reaction was exemplified by the first asymmetric synthesis of both... 

The pseudoenantiomeric nature of quinine and quinidine (opposite configurations at Cg and Cq) as well as of the corresponding carbamates has already been outlined. 

FIGURE 1.19 X-ray crystal structures of selector-selectand complexes (ion-pairs) (a) O-9-(P-chloro-fert-butylcarbamoyl)quinine with iV-(3,5-dinitrobenzoyl)-(5)-leucine, (b) tbe pseudoenantiomeric complex of 0-9-( 3-cbloro-tert-butylcarbamoyl)quinidine with N-(3,5-dinitrobenzoyl)-(i )-leucine, (c) 0-9-( 3-cbloro-terf-butylcarbamoyl)quinine with N-(3,5-dinitrobenzoyl)-(5)-alanyl-(5)-alanine, and (d) comparison of tbe complexes of (a) and (c). Most hydrogens have been omitted for the purpose of clarity. (Reprinted from C. Czerwenka et al., Anal. Chem., 74 5658 (2002). With permission.)... 

Another issue is validated by the presented X-ray structures This is related to the pseudoenantiomeric character of the tert-butylcarbamates of quinine and quinidine (Figure 1.19a,b). Except for the vinyl on the backside of the quinuclidine ring, both the complexes that are actually diastereomeric to each other actually look like mirror images with regard to conformations and intermolecular interactions as well so that the pseudoenantiomeric experimental chromatographic behavior for DNB-Leu can be rationalized also on the basis of their X-ray crystal structures. 

The pseudoenantiomeric catalysts derived from the alkaloid pairs cinchonine/cinchonidine and quinidine/quinine (1/4 or 2/5, respectively) are related as diastereomers but are enantiomeric with respect to the front working-face defined by carbons 8 and 9. 

The essential components of the catalyst for the asymmetric dihydroxylation process are osmium tetroxide (OSO4) and an ester of one or the other of the pseudoenantiomeric cinchona alkaloids dihydro-quinidine (DH( D) and dihydroquinine (DHQ). An amine oxide, generally A(-methylmoiphoIine N-oxide, serves as the oxidant for foe reaction. When an alkenic substrate is added very slowly to a... 

As mentioned in the previous section, nowadays, readily available and inexpensive cinchona alkaloids with pseudoenantiomeric forms, such as quinine and quinidine or cinchonine and cinchonidine, are among the most privileged chirality inducers in the area of asymmetric catalysis. The key feature responsible for their successful utility in catalysis is that they possess diverse chiral skeletons and are easily tunable for diverse types of reactions (Figure 1.2). The presence of the 1,2-aminoalcohol subunit containing the highly basic and bulky quinuclidine, which complements the proximal Lewis acidic hydroxyl function, is primarily responsible for their catalytic activity. 

Very recently, an intramolecular cycloaldolization was employed successfully early in the synthesis of quinine (2) and quinidine (3) (97). Hatakeyama etal. used a (S)-12 catalyzed aldol reaction followed by in situ reduction of the aldol product with NaBBLj to obtain the diastereomers 99 and 100 in good yield and enantios-electivity (dr = 1 2). Followed by protection of the primary alcohol and oxidation of the secondary one, intermediate 101 with the desired configuration could easily be obtained. The intermediate 101 was then transformed into either 2 or the pseudoenantiomeric 3 by known methods (Scheme 23) (97). 

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