Cinchona 3+2 -cycloaddition

Okamura and Nakatani [65] revealed that the cycloaddition of 3-hydroxy-2-py-rone 107 with electron deficient dienophiles such as simple a,p-unsaturated aldehydes form the endo adduct under base catalysis. The reaction proceeds under NEtj, but demonstrates superior selectivity with Cinchona alkaloids. More recently, Deng et al. [66], through use of modified Cinchona alkaloids, expanded the dienophile pool in the Diels-Alder reaction of 3-hydroxy-2-pyrone 107 with a,p-unsaturated ketones. The mechanistic insight reveals that the bifunctional Cinchona alkaloid catalyst, via multiple hydrogen bonding, raises the HOMO of the 2-pyrone while lowering the LUMO of the dienophile with simultaneous stereocontrol over the substrates (Scheme 22). 

An interesting expansion to the scope of dienes that could be adopted as partners within the Diels-Alder cycloaddition was reported by Deng (Scheme 57) [193]. Reaction of 3-hydroxypyrones 145 with a broad range of a,p-unsaturated ketones in the presence of the primary cinchona alkaloid 144 (5 mol%) provided the Diels-Alder adducts with exceptional levels of asymmetric induction (up to 99% ee). Within this report it was also shown that the related alkaloid 146 provided access to the enantiomeric adducts with similar levels of asymmetric induction. 

To improve the position selectivity in the AD of oligoprenyl compounds bis-cinchona alkaloid ligand 8 was introduced by Corey 15,6]. Its design was based on the [3+2]-cycloaddition model for the AD mechanism, which will be discussed in Section 6E. 1.2. The two 4-heptyl ether substituents of the quinolines are supposed to assist fixation of the substrate in the binding cleft. Additionally, the jV-methylquinuclidinium unit and the linking naphthopyridazine were introduced to rigidify the osmium tetroxide complex of 8 [6],... 

CYCLOADDITIONS Alkylaluminum halides. Cinchona alkaloids. Trifluoromethanesulfonic anhydride. 

Cinchona alkaloid derivatives catalysed the enantioselective 4 + 2-cycloaddition of o-quinones with ketene enolates to produce chiral o-quinone cycloadducts in high ee... 

Polymer-supported organocatalysts have been used for cycloaddition of ketene, 127, to chloral, 128 [141]. Use of homo-acrylate polymers of cinchona alkaloids led to formation of the desired /Mactone (S)-130 with enantioselectivity up to... 

A series of (1-lactams (64) have been synthesized through the use of an immobilized cinchona alkaloid catalyst. This is postulated to proceed via the cycloaddition of an imine, and a ketene formed in situ through deprotonation of an acid chloride (Scheme 4.81). Different system configurations were described in the paper however, a column filled with a 5 1 mixture of solid K2C03 and immobilized-quinine derivative 65 cooled to —45 °C was found to be the most practical. The solution of the acid chloride and imine was dripped through the column and then directed... 

Cinchona alkaloids possess a nucleophilic quinuclidine structure and can perform as versatile Lewis bases to react with ketenes generated in situ from acyl halides in the presence of an acid scavenger. The resulting ketene enolates can react with electrophilic C=0 or C=N bonds to deliver chiral [i-lactones [5] or [i-lactams [6], respectively, in a [2 + 2] cycloaddition manner, which is discussed in Chapter 5 in detail. Gaunt et al. also developed practical one pot cydopropanation processes mediated by the modified cinchona alkaloids via ammonium ylide intermediates [7]. Although the catalytic strategy has been well established, the utilization of ammonium enolate based [4 + 2] cycloaddition is rare probably because of the relative unreactivity of the... 

Later, Lectka et al. reported a detailed synthetic and mechanistic study of unusual [4 + 2] cycloaddition of ketene enolates and o-quinones by the bifunctional catalysis of cinchona alkaloids BQD la (or BQN lb) and Lewis adds. The undertaken investigations based on the integration of experimental and calculated data itself demonstrated a surprising cooperative LA/LB interaction on a ketene enolate. It showed that the reaction of o-quinone undergoes a mechanistic switch in which the mode of activation changes from Lewis acid (LA) complexation of the quinone to metal complexation of the chiral ketene enolate. 

Another catalytic application of chiral ketene enolates to [4 + 2]-type cydizations was the discovery of their use in the diastereoselective and enantioselective syntheses of disubstituted thiazinone. Nelson and coworkers described the cyclocondensations of acid chlorides and a-amido sulfones as effective surrogates for asymmetric Mannich addition reactions in the presence of catalytic system composed of O-TM S quinine lc or O-TMS quinidine Id (20mol%), LiC104, and DIPEA. These reactions provided chiral Mannich adducts masked as cis-4,5 -disubstituted thiazinone heterocycles S. It was noteworthy that the in situ formation of enolizable N-thioacyl imine electrophiles, which could be trapped by the nucleophilic ketene enolates, was crucial to the success of this reaction. As summarized in Table 10.2, the cinchona-catalyzed ketene-N-thioacyl-imine cycloadditions were generally effective for a variety of alkyl-substituted ketenes and aliphatic imine electrophiles (>95%ee, >95%cis trans) [12]. 

Asymmetric Cycloadditions Catalyzed by QumucM me Tertiary Amim 303 Table 10.2 Cinchona alkaloid catalyzed ketene-N-thioacyl imine [4 + 2] cycloadditions ... 

Apart from acting as effective Lewis base catalysts, the quinuclidine structure of cinchona alkaloids can also participate in the other cycloaddition reaction by a different catalytic mechanism. Calter et al. described an interesting asymmetric interrupted Feist-Benary reaction between ethyl bromopyruvates and cyclohexadione. They proposed that the protonated cinchona alkaloid would perform as a Bronsted acid to form hydrogen-bonding interaction with a-ketoester moiety, rendering it more electrophilic toward attack by either the enol or enolate of cydohexandione. Then intramolecular alkylation would afford the formal [3 + 2] cycloadduct (Scheme 10.12) [16]. 

Azomethine ylides are very important 1,3-dipoles, and they are usually used to react with alkenes leading to the formation of the highly substituted pyrrolidine derivatives [17]. A novel and practical process for the 1,3-dipolar cycloaddition of azomethine ylides with alkenes had been reported by j0rgensen and coworkers [18]. They proposed that a dipol-chiral base ion pair would be generated between a-imino ester-metal complex and a cinchona alkaloid, and subsequent cycloaddition with dipolarophile would take place in a stereoselective manner (Scheme 10.13). 

Asymmetric Cycloadditions Catalyzed by Bifiinctional Cinchona Alkaloids... 

Asymmetric Cycloadditions Catalyzed by Bifunctional Cinchona Alkaloids 309... 

Zhang et al. investigated the asymmetric 1,3-dipolar cycloaddition of tert-butyl 2-(diphenylmethyleneamino)acetate and nitroalkenes promoted by bifunctional thiourea compounds derived from cinchona alkaloids, affording chiral pyrrolidine derivatives 13 with multisubstitutions. Catalyst lm delivered the best results in terms of catalytic activity, diastereoselectivity and enantioselectivity. Nevertheless, only moderate ee values could be obtained while the diastereoselectivities were generally good (Scheme 10.18) [22]. 

Asymmetric Cycloaddition Reactions Catalyzed by Cinchona-Based Primary Amines 313... 

Asymmetric Cycloaddition Catalyzed by Cinchona-Based Phase-Transfer Catalysts... 

Drawing from their success with catalytic [4 + 2] cycloaddition, Lectka group developed another highly enantioselective cycloaddition of o-quinone methide (o-QM) with silyl ketene acetals, using a chiral cinchona alkaloid derived ammonium, N-(3-nitrobenzyl)quinidinium fluoride Is, as a precatalyst. The free hydroxyl group of the cinchona alkaloid moiety was crucial to high optical induction. A variety of silyl ketene acetals had been screened to afford the cycloadducts 22 with good ee (72-90%) and excellent yield (84—91%) (Scheme 10.26) [35]. 

As discussed above, the vast synthetic potential of cinchona alkaloids and their derivatives in the asymmetric cycloadditions has been well demonstrated over the past few years. Cinchona-based organocatalysts possess diverse chiral skeletons and are multifunctional. There is no doubt that the further development of cinchona-based organocatalysts and their catalyzed cycloaddition reactions will continue to provide exciting results in the near future. 

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