Cinchona alkaloid-based catalysts addition

The efficiency with which modified Cinchona alkaloids catalyze conjugate additions of a-substituted a-cyanoacetates highlights the nitrile group s stereoselective role with the catalyst. Deng et al. [60] utilized this observation to develop a one-step construction of chiral acyclic adducts that have non-adjacent, 1,3-tertiary-quatemary stereocenters. Based on their mechanistic studies and proposed transition state model, the bifimctional nature of the quinoline C(6 )-OH Cinchona alkaloids could induce a tandem conjugate addition-protonation reaction to create the tertiary and quaternary stereocenters in an enantioselective and diastereoselective manner (Scheme 18). 

The Jorgensen group also applied the parent cinchona alkaloids as catalysts to the aza-Michael addition of hydrazones 8 to cyclic enones 9 [4] and the asymmetric deconjugative Michael reaction of alkylidene cyanoacetates 10 with acrolein (11) [5], However, only a moderate level of enantioselectivity was obtained in both reactions (Scheme 9.4). Of note, for the deconjugative Michael reaction, the delocalized allylic anion 12 could be generated via the deprotonation of 10 by the cinchona base and might attack the electrophilic enal at either the a- or the y-position. However, in this study, only the a-adducts were produced. 

In the same year, Connon and coworkers [63] reported that the chiral bifunctional cinchona alkaloid-based thiouea 81a is also able to catalyze the addition of dimethyl chloromalonate 196 to nitroolefins 124, leading to the Michael adduct that cyclizes to form the cyclopropane 197 in the presence of DBU. Almost single diastereomeric nitrocyclopropanes (>98% de) were obtained in good yields. However, the enantios-electivity obtained with this type of catalyst was poor (<47% ee) (Scheme 9.69). 

Asymmetric Michael addition of optically active perhydro-l,4-oxazepin-5,7-diones, and of thioglycollic acid in the presence of a cinchona alkaloid as catalyst, to a-nitro-olefins yields y-nitrocarboxylic acids and 2-nitrothio ethers, respectively, with reasonable enantiomeric excess. Allylsilanes add to a-nitro-olefins in the presence of aluminium chloride to give unsaturated nitronic acids, which are further transformed in a Nef-type reaction to give y,5-enones (Scheme 36).Nitro-compounds are also converted into the corresponding carbonyl compounds upon treatment with base and MoOs pyHMPA, a new modified Nef reaction. 

In 2003, Rawal reported the use of TADDOLs 177 as chiral H-bonding catalysts to facilitate highly enantioselec-tive hetero-Diels-Alder reactions between dienes 181 and different aldehydes 86 (Scheme 6.29A) [82], and also BINOL-based catalysts 178 were found to facilitate this reaction with excellent selectivities [83]. TADDOLs were also successfully used as organocatalysts for other asymmetric transformations like Mukaiyama aldol reactions, nitroso aldol reactions, or Strecker reactions to mention a few examples only [84]. In addition, also BINOL derivatives have been employed as efficient chiral H-bonding activators as exemplified in the Morita-Baylis-Hilhnan reaction of enone 184 with different carbaldehydes 86 [85]. The use of chiral squaramides for asymmetric reactions dates back to 2005 when Xie et al. first used camphor-derived squaric amino alcohols as ligands in borane reductions [86]. The first truly organocatalytic application was described by Rawal et al. in 2008 who found that minute amounts of the bifunctional cinchona alkaloid-based squaramide 180 are... 

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). 

Addition of CH2(CN)2 to -substituted 2-enoylpyridines RCH=CHCO(2-Py), catalysed by the cinchona alkaloid-based bifunctional ureas, such as (345) (10mol%), has been reported to proceed with <97% ee in m-xylene at room temperature. Squaramide (346) proved to be even more efficient for the addition of the same nucleophile to enones R CH=CHCOR, which required only 0.5 mol% catalyst loading to attain <96% ee (in CHCI3 at room temperature), ... 

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... 

While this manuscript was under preparation, a considerable number of examples of sohd-phase-attached catalysts appeared in the literature which is a clear indication for the dynamic character of this field. These include catalysts based on palladium [131, 132], nickel [133] and rhodium [134] as well applications in hydrogenations including transfer hydrogenations [135, 136] and oxidations [137]. In addition various articles have appeared that are dedicated to immobilized chiral h-gands for asymmetric synthesis such as chiral binol [138], salen [139], and bisoxa-zoline [140] cinchona alkaloid derived [141] complexes. 

In addition to metal catalysts, organocatalysts could also be used in asymmetric cyanation reactions. Chiral Lewis bases, modified cinchona alkaloids, catalyzed asymmetric cyanation of ketones by using ethyl cyanoformate as the cyanide source (Scheme 5.34)." Similar to metal-catalyzed reactions, ethyl cyanoformate was first activated by chiral Lewis bases to form active nucleophiles. Various acyclic and cyclic dialkyl ketones were transformed into the desired products. Because of using... 

Aldol and Related Condensations As an elegant extension of the PTC-alkylation reaction, quaternary ammonium catalysts have been efficiently utilized in asymmetric aldol (Scheme 11.17a)" and nitroaldol reactions (Scheme ll.lTb) for the constmction of optically active p-hydroxy-a-amino acids. In most cases, Mukaiyama-aldol-type reactions were performed, in which the coupling of sUyl enol ethers with aldehydes was catalyzed by chiral ammonium fluoride salts, thus avoiding the need of additional bases, and allowing the reaction to be performed under homogeneous conditions. " It is important to note that salts derived from cinchona alkaloids provided preferentially iyw-diastereomers, while Maruoka s catalysts afforded awh-diastereomers. 

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). 

In the initial screening of various Cinchona alkaloids, the addition of diethyl phosphate 41 to IV-Boc imine 40 in toluene revealed the key role of the free hydroxyl group of the catalyst. Replacing the C(9)-OH group with esters or amides only results in poor selectivity. Quinine (Q) was identified as an ideal catalyst. A mechanistic proposal for the role of quinine is presented. Hydrogen-bonding by the free C(9)-hydroxyl group and quinuclidine base activation of the phosphonate into a nucleophilic phosphite species are key to the reactivity of this transformation (Scheme 9). 

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