Cinchona alkaloid-based catalysts amine

With respect to the catalysts of choice, the MacMillan imidazolidinones 77 emerged as the most commonly used ones in iminium catalysis, but also cinchona alkaloid-based amines like 115 as well as the Hayashi-Jprgensen catalysts 85 have been highly successful in this field [31,47]. 

The same year, jOTgensen and coworkers reported an enantioselective aza-Michael addition to enones using hydrazones as nucleophiles and cinchona alkaloids as catalyst [104]. This base-catalyzed reaction renders the final aminated products in good yields but only moderate enantioselectivities (up to 77% ee). 

While asymmetric counteranion-directed catalysis (ACDC) has been estab-hshed as a powerful strategy in iminium catalysis, enamine-based asymmetric counteranion-directed catalysis has not yet been developed. Recently, Lu et al. [32] demonstrated that the combination of a cinchona alkaloid-derived primary amine and chiral camphorsuhnnic acid (CSA) results in an effective ion-pair catalyst for the directed asymmetric amination of a-branched aldehydes through enamine activation (Scheme 43.21). 

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). 

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. 

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. 

Prostereogenic ketenes and chiral alcohols in the presence of achiral amines yield esters with high diastereoselectivity (see Section 2.1.5.). Extensive studies with achiral alcohols and acylat-ed cinchona alkaloids as base catalysts reveal that high enantioselectivities can also be achieved for example with 1 137,138. 

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... 

In the previons section, secondary chiral amines were employed that give rise to enamine formation npon reaction with ketones or aldehydes. Chiral tertiary amines, unable to form enamines, are nevertheless capable of inducing enantioselectivity in case substrates are used that contain sufficiently acidic protons such as aldehydes, ketones or active methylene compounds [33]. The cinchona alkaloids, by far the most versatile source of Brpnsted base catalysts, have played a prominent role in various types of asymmetric organocatalytic reactions [34], which is also true for the Mannich reaction. 

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. 

Cinchona alkaloid derivatives can also serve as useful Lewis basic catalysts, as very well exemplified by their successful employment in the Morita-Baylis-Hillman (MBH) reaction and its aza variant (aza-MBH), which provide a convenient access to functionalised allylie aleohols and amines. As early as 1999 Hatakeyama and coworkers reported the use of p-isocupreidine (P-ICPD) as a catalyst for the reaction of aliphatic and aromatic aldehydes with 1,1,1,3,3,3-hexafluoroisopropyl acrylate, affording the desired adducts with very high enantioselectivities (Scheme 14.19). The concomitant formation of the dioxanone derivatives lowered the yield in the MBH adducts and caused difficulties in the experimental proeedure. Interestingly, the dioxanone derivatives had the opposite eonfiguration at the alcoholic stereocentre compared to the MBH produet, highlighting an intriguing mechanistic feature of this Lewis-base catalysed reaction. ... 

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