Cinchona alkaloid primary amine catalyst

Analogously, Melchiorre et al. developed an iminium-enamine tandem sequence, which relies on the chiral primary amine catalyst 101, directly derived from natural cinchona alkaloids (Scheme 2.29) [59]. 

An interesting example of aminocatalysis where a chiral primary amine activates a-substituted a,p-unsaturated aldehydes in a cascade sequence for the addition of indoles and azocarboxylate was reported by Melchiorre and coworkers (Scheme 6.16) [43]. Primary amine 128 directly derived from natural cinchona alkaloid was the catalyst of choice, which promoted this cascade reaction providing final adducts 129, as valuable precursors for a-amino acids having two adjacent stereogenic centers, one of which is quaternary, with very high enantioselectivities (83-99%). The yields are moderate to good (31-80%), and different substituents on the indole core (Cl, OMe, Me) are well tolerated. 

In 2010, Jorgensen et al. developed an enantioselective tandem reaction of propargylated malononitriles with cyclic enones sequentially catalysed by a cinchona alkaloid-derived primary amine catalyst in the presence of (J )-mandelic acid as an additive for the first Michael step, and a gold catalyst for the second tandem exo-dig cyclisation-isomerisation reaction. " As shown in Scheme 7.62, the corresponding chiral bicyclic enones were achieved in good yields and high enantioselectivities of up to 96% ee, albeit low to moderate diastereoselectivities (34-66% de). 

Although considerable improvements have been made for endo-selective cycloadditions of azomethine imines, methods for exo and enantioselective cycloaddition of azomethine imines were relatively scarce. By employing novel, multifunctional primary amine catalysts 145 derived from cinchona alkaloids in the presence of triisopropylbenzene sulfonic acid (TIPBA) 146 as cocatalyst, Chen and coworkers developed the first organocatalytic, highly exo-selective, and enantioselective 1,3-DC reaction of cyclic enones 142 and azomethine imines 143 in 2007 [53]. The additional and synergistic hydrogen-bonding interaction of catalyst and 1,3-dipole is essential for enantiocontrol, and excellent stereoselectivities were achieved for a broad scope of substrates (dr > 99 1, up to 95% ee) (Scheme 2.37). 

S)-proline-catalyzed reaction is not sufficient therefore, a large number of (S)-proline-derived secondary amine catalysts have been developed. Primary amine catalysts derived from natural amino acids and cinchona alkaloids have also emerged as highly versatile and powerful catalysts [25]. For example, in the intramolecular 6-endo aldol reaction of diketone 43, quinine-derived primary amine 44 in acetic acid affords the cyclic ketone (S)-46 in 94% yield with 90% ee (Scheme 28.3) (S)-prohne gives the cycUzation product in low yield with moderate ee. In addition, the pseudo-enantiomeric quinidine-derived primary amine 45 deUvers the opposite product, the (R)-enantiomer 46, with similar yield and enantioselectivity [26]. 

Primary amine catalysts have been used almost exdusively for the activation of enones or a-substituted enals due to the low reactivity of the secondary amine catalysts described below with these substrates. The stereochemical course of the reaction is highly dependent on the nature of the primary amine and in most cases is difficult to rationalize. The most common primary amines used as catalysts are cinchona alkaloid derivatives, chiral diamines, or BINAM derivatives (Figure 33.6). 

In 2010, Xie reported a vinylogous Michael addition of 3-cyano-4-methylcou-marins to a,P-unsaturated ketones using primary amine catalysts derived from cinchona alkaloids to promote the reaction. The final compounds were afforded in good yields and good enantioselectivities [88]. 

A stereoselective [3+2] dipolar cycloaddition of azomethine imines 141 with ot,P-unsaturated aldehydes catalyzed by ot,a-diarylprolinol salts was also reported by Chen et al. [88]. More important, they extended the strategy to cyclic enones by employing a Cinchona alkaloid-derived bifunctional primary amine catalyst 142 (Scheme 1.52) [89]. The synergistic hydrogen-bonding interaction of the catalyst and 1,3-dipoles 141 plays a critical role in high enantiocontrol (dr >99 1, up to 95% ee). 

Chen group developed first asymmetric amination of aryl ketones by employing primary amine catalyst derived from cinchona alkaloid [43]. In the catalysis of 77, an array of aryl ketones react with diethyl azodicarboxylate to afford a-amino products with up to 99% ee (Scheme 5.22). 

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... 

Scheme 2.10 Enantioselective Michael addition of ketones to nitroalkenes catalyzed by primary amine-sulfonamide catalysts 27a-b and by 9-epi amino cinchona alkaloid 28a.

The conceptually different activation of carbonyl substrates through the formation of a nucleophilic enamine or an electrophilic iminium ion is achieved by use of 9-deo>q -ep/-9-amino Cinchona catalysts. In contrast to typical secondary amine-based catalysts i.e. derived from proline), the primary amine of these modified Cinchona alkaloids can combine also with sterically biased substrates, such as ketones and hindered aldehydes. This class of catalyst has thus allowed the scope of aminocatalysis to be extended beyond unhindered aldehydes/enals, and has proved to be remarkably powerful and general. 

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 efficiency of secondary amine catalysts is often eroded when moving from aldehydes to ketones as the donor carbonyl substrates, a trend that can be explained in terms of either the greater difficulty in the generation of the intermediate enamine species or their attenuated reactivity. To alleviate this situation, primary amines have emerged as a complementary family of amine catalysts. For instance, proline and related chiral secondary amines are not useful catalysts for the a-amination of aromatic enolizable ketones. As in other similar situations involving ketones as substrates, primary amines proved to be superior catalysts, although in these cases the presence of an acid co-catalyst seems to be crucial for reactivity. For instance (Scheme 11.4), primary amines derived from cinchona alkaloids can efficiently... 

An enamine-catalyzed asymmetric a-fluorination of ketones, which are notoriously challenging substrates for this reaction, was reported by MacMillan and coworkers in 2011 [27]. After exhaustive automated screening of over 250 organo-catalysts, a Cinchona alkaloid-derived primary amine organocatalyst was identified as the optimal catalyst for this transformation (Scheme 13.11). Only cyclic ketones provided fluorinated products in high yields and enantiomeric excesses. 

More recently, it has been reported that primary amines derived from cinchona alkaloids [75] as well as proline derivatives [76], combined with achiral Brpnsted or Lewis acids, may also efficiently catalyze the enantioselective Biginelli reaction. Alternatively, a carbohydrate-based bifnnctional primary amine-thiourea catalyst was developed for this transformation, with similar enantiocontrol [77]. 

The first highly enantio-selective a-fluorination of ketones using organocatalysis has been accomplished. " The optimal catalytic system, a primary amine-functionalized cinchona alkaloid (24), allows the direct and asymmetric a-fluorination of a variety of carbo- and hetero-cyclic substrates. Furthermore, this protocol also provides diastereo-, regio-, and chemo-selective catalyst control in fluorinations involving complex carbonyl systems (up to 98 2 dr, 99% ee, and >99 1 regiocontrol). 

On the other hand, several cinchona alkaloid-derived primary amines have been successfully investigated as organocatalysts for asymmetric Michael additions of ketones to Michael acceptors. As an example, Lu et al. have described the first Michael addition of cyclic ketones to vinyl sulfone catalysed by a catalyst of this type, providing an easy access to chiral a-alkylated carbonyl compounds with high yields and enantioselectivities of up to 96% ee, albeit with moderate diastereoselectivities (<72% de), as shown in Scheme 1.21. This novel methodology was apphed to the synthesis of sodium cyclamate, an important compound in the artificial sweeteners industry. 

Enantioselective a-fluorination of cyclic ketones can be achieved with excellent enantioselectivity by the use of NFSi in the presence of a primary amine functionalized cinchona alkaloid catalyst (eq 29). ... 

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