Quaternary cinchona alkaloids

The asymmetric alkylation of glycine derivatives is one of the most simple methods by which to obtain optically active a-amino acids [31]. The enantioselective alkylation of glycine Schiff base 52 under phase-transfer catalysis (PTC) conditions and catalyzed by a quaternary cinchona alkaloid, as pioneered by O Donnell [32], allowed impressive degrees of enantioselection to be achieved using only a very simple procedure. Some examples of polymer-supported cinchona alkaloids are shown in Scheme 3.14. Polymer-supported chiral quaternary ammonium salts 48 have been easily prepared from crosslinked chloromethylated polystyrene (Merrifield resin) with an excess of cinchona alkaloid in refluxing toluene [33]. The use of these polymer-supported quaternary ammonium salts allowed high enantioselectivities (up to 90% ee) to be obtained. 

The principal action of the quaternary cinchona alkaloids has been shown to be peripheral (50, 87, 88). The central nervous system is not markedly effected by paralyzing doses, but a transient fall in blood pressure is produced (50, 87, 88, 104). A -Methylquininium chloride has been used on a limited scale in clinical medicine to relieve muscle spasm in certain spastic states (5a, 9, 31). As in the case of curare and the Erythrina alkaloids, synergistic effects are noted between iV-methyl- and iV-ethylquininium chlorides and certain anesthetics and hypnotics (45). 

None of the quaternary salts of the cinchona alkaloids have given promising results as pneumococcicidal agents, but quinine methochloride and ethochloride have received some attention recently as curarising drugs. ... 

Cinchona alkaloids now occupy the central position in designing the chiral non-racemic phase transfer catalysts because they have various functional groups easily derivatized and are commercially available with cheap price. The quaternary ammonium salts derived from cinchona alkaloids as well as some other phase transfer catalysts are... 

O Donnell (1989), Corey/Lygo (1997) cinchona alkaloid-derived quaternary ammonium salts Lewis Base Cataiysis... 

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. 

Preliminary mechanistic studies show no polymerization of the unsaturated aldehydes under Cinchona alkaloid catalysis, thereby indicating that the chiral tertiary amine catalyst does not act as a nucleophilic promoter, similar to Baylis-Hilhnan type reactions (Scheme 1). Rather, the quinuclidine nitrogen acts in a Brpnsted basic deprotonation-activation of various cychc and acyclic 1,3-dicarbonyl donors. The conjugate addition of the 1,3-dicarbonyl donors to a,(3-unsaturated aldehydes generated substrates with aU-carbon quaternary centers in excellent yields and stereoselectivities (Scheme 2) Utility of these aU-carbon quaternary adducts was demonstrated in the seven-step synthesis of (H-)-tanikolide 14, an antifungal metabolite. 

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). 

Alkylation of Schiff bases, derived from amino acid and non-optically active aromatic aldehydes by phase-transfer catalysis in the presence of cinchona alkaloid derived quaternary ammonium salts, gave ce values of up to 50% l42. 

Very successful results have been obtained with functionalized quaternary ammonium salts derived from cinchona alkaloids. An example... 

In 1989, O Donnell and coworkers successfully utilized cinchona alkaloid-derived chiral quaternary ammonium salts for the asymmetric synthesis of a-amino acids using tert-butyl glycinate benzophenone Schiff base 1 as a key substrate [5]. The asymmetric alkylation of 1 proceeded smoothly under mild phase-transfer... 

The asymmetric cyclopropanation of a-bromocyclohexenone with cyanoacetate 31 has been achieved under phase-transfer conditions by the use of cinchona alkaloid-derived catalyst, which constructs chiral quaternary carbons on the cyclopropane... 

As reviewed in this chapter, cinchona alkaloids have played a crucial role in the development of asymmetric phase-transfer catalysis since its advent, and today constitute a privileged structural motif that may be widely utilized for the design of new chiral quaternary ammonium salts. These benefits are due not only to the... 

In particular, it is not only the cinchona alkaloids that are suitable chiral sources for asymmetric organocatalysis [6], but also the corresponding ammonium salts. Indeed, the latter are particularly useful for chiral PTCs because (1) both pseudo enantiomers of the starting amines are inexpensive and available commercially (2) various quaternary ammonium salts can be easily prepared by the use of alkyl halides in a single step and (3) the olefin and hydroxyl functions are beneficial for further modification of the catalyst. In this chapter, the details of recent progress on asymmetric phase-transfer catalysis are described, with special focus on cinchona-derived ammonium salts, except for asymmetric alkylation in a-amino acid synthesis. 

A wide variety of catalytic asymmetric transformations have been achieved in the above investigations, which clearly indicates that quaternary ammonium salts derived from cinchona alkaloids are still powerful reagents, despite their limited structural diversity. Moreover, as PTC chemistry has been recognized as a highly practical approach, further progress should be expected in this area of research. 

Cinchona alkaloids, of course, have occupied the central position in the design of chiral PTCs. By employing a simple chemical transformation of the tertiary amine ofthe natural cinchona alkaloids to the corresponding quaternary ammonium salts, using active halides (e.g., aryl-methyl halides), a basic series of PTCs can be readily prepared. Cinchona alkaloid-derived PTCs have proved their real value in many types of catalytic asymmetric synthesis, including a-alkylation of modified a-amino acids for the synthesis of higher-ordered a-amino acids [2], a-alkylation of... 

It is generally considered that a quaternary ammonium salt derived from cinchona alkaloids has an imaginary tetrahedron composed of four carbon atoms adjacent to the bridgehead nitrogen. As shown in Figure 4.2, in order to serve as an efficient... 

Currently, the chiral phase-transfer catalyst category remains dominated by cinchona alkaloid-derived quaternary ammonium salts that provide impressive enantioselec-tivity for a range of asymmetric reactions (see Chapter 1 to 4). In addition, Maruoka s binaphthyl-derived spiro ammonium salt provides the best results for a variety of asymmetric reactions (see Chapters 5 and 6). Recently, some other quaternary ammonium salts, including Shibasaki s two-center catalyst, have demonstrated promising results in asymmetric syntheses (see Chapter 6), while chiral crown ethers and other organocatalysts, including TADDOL or NOBIN, have also found important places within the chiral phase-transfer catalyst list (see Chapter 8). 

Non-cinchona alkaloid-derived quaternary ammonium salts 1 [10] and 2 [11] were each shown to promote asymmetric alkylation reactions, with enantioselectivity of up to 48% and 94% ee, respectively (Scheme 7.1). 

In continuation with their studies on the synthesis of new analogues of cinchona alkaloids, Dehmlow et al. prepared quaternary ammonium salt 14, which is a... 

Dehmlow and coworkers [17] compared the efficiency of monodeazadnchona alkaloid derivatives 14a-c in the enantioselective epoxidation of naphthoquinone 50 with that of cinchona alkaloid-derived chiral phase-transfer catalysts 15a-c (Table 7.7) (for comparison of the alkylation reaction, see Table 7.1). Interestingly, the non-natural cinchona alkaloid analogues 14a-c afforded better results than natural cinchona alkaloids 15a-c. The deazacinchonine derivatives 14a,b produced epoxidation product 51 in higher enantioselectivity than the related cinchona alkaloids 15a,b. Of note, catalyst 14c, which possessed a bulky 9-anthracenylmethyl substituent on the quaternary nitrogen, afforded the highest enantioselectivity (84% ee). 

Direct Mannich reactions of cyclic 1,3-dicarbonyls with acyl imines, R1-CH=N-CO2R2, gives o -quaternary-carbon-bearing products (9 X = CH2, O Y = Me, OMe, OEt) with yieldIdelee up to 98/90/99%, using cinchona alkaloid catalysts 25 ... 

Both experimental and theoretical studies have been reported of fluoro-denitration and fluoro-dechlorination reactions using anhydrous tetrabutylammonium fluoride in DMSO. The absences of ion pairing and strong solvation are critical in contributing to the reactivity of the fluorinating agent24 Quaternary ammonium salts derived from cinchona alkaloids have been shown to be effective catalysts in an improved asymmetric substitution reaction of /1-dicarbonyl compounds with activated fluoroarenes. The products may be functionalized to yield spiro-oxindoles.25... 

Aldol reactions using a quaternary chinchona alkaloid-based ammonium salt as orga-nocatalyst Several quaternary ammonium salts derived from cinchona alkaloids have proven to be excellent organocatalysts for asymmetric nucleophilic substitutions, Michael reactions and other syntheses. As described in more detail in, e.g., Chapters 3 and 4, those salts act as chiral phase-transfer catalysts. It is, therefore, not surprising that catalysts of type 31 have been also applied in the asymmetric aldol reaction [65, 66], The aldol reactions were performed with the aromatic enolate 30a and benzaldehyde in the presence of ammonium fluoride salts derived from cinchonidine and cinchonine, respectively, as a phase-transfer catalyst (10 mol%). For example, in the presence of the cinchonine-derived catalyst 31 the desired product (S)-32a was formed in 65% yield (Scheme 6.16). The enantioselectivity, however, was low (39% ee) [65],... 

Phase-transfer catalysis has been widely been used for asymmetric epoxidation of enones [100]. This catalytic reaction was pioneered by Wynberg et al., who used mainly the chiral and pseudo-enantiomeric quaternary ammonium salts 66 and 67, derived from the cinchona alkaloids quinine and quinidine, respectively [101-105],... 

In the mid-1980s Merck chemists developed a method for asymmetric alkylation of a cyclic ketone in the presence of a simple cinchona alkaloid (see also Section 3.1) [50-52], The resulting product 23, bearing a quaternary stereogenic center, is an intermediate in the synthesis of indacrinone 20 (Scheme 14.9). It should be noted that this impressive contribution from Merck chemists was not only the first exam-... 

Chiral phase transfer catalysts have been exploited in a wide range of reactions which involve anionic intermediates. Remarkably, quaternary ammonium salts of 1 and 2 have been shown to induce asymmetry in many different synthetic reactions, and the cinchona alkaloids appear to be a charmed template for the design of effective phase transfer catalysts [14],... 

A first attempt to realize catalytic asymmetric fluorination under phase transfer conditions goes back to attempts by Cahard et al. [20] Quaternary ammonium salts of cinchona alkaloids were used as catalysts in the presence of TosNFtBu as F-source and 23 was employed as substrate. Unfortunately, enantioselectivities remained rather low. Very recently, Kim and Park have described a closely related system (Scheme 4) [21]. 

The direct enantioselective organocatalytic a-fluorination can also be performed with cinchona alkaloid derivatives as catalyst under phase-transfer reaction conditions [25]. The fluorination reaction by NFSI of / -ketoesters 21, readily enolizable substrates, generated a stereogenic quaternary C-F bond in high yields and with enantioselectivities up to 69% ee for the optically active products 26 (Eq. 6). 

Recently, Mukaiyama and co-workers prepared cinchona alkaloid-derived chiral quaternary ammonium phenoxide-phenol complex 23 and used it as an efficient organocatalyst for the tandem Michael addition and lactonization between oc,f-unsaturated ketones and a ketene silyl acetal 24 derived from phenyl isobutyrate. This approach permits the highly enantioselective synthesis of a series of 3,4-dihydropyran-2-ones (25), as shown in Scheme 4.11 [17]. 

Further reports on asymmetric synthesis in the presence of Cinchona alkaloids have been made.142 " For example, hydrogenation of methyl pyruvate with a platinum-alumina catalyst containing quinine gives (+)-(/ )-methyl lactate in 87% optical yield.1426 Asymmetric induction with optical yields up to 36 and 26% has been observed in the Michael addition of thiols and nitro-alkanes to ct/ -unsaturated ketones in the presence of quaternary salts derived from the Cinchona alkaloids.142"... 

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