Cinchona alkaloids reactions, asymmetric

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... 

The use of diazodicarboxylates has been recently explored in Cinchona alkaloid catalyzed asymmetric reactions. Jprgensen [50] reported the synthesis of non-biaryl atropisomers via dihydroquinine (DHQ) catalyzed asymmetric Friedel-Crafts ami-nation. Atropisomers are compounds where the chirality is attributed to restricted rotation along a chiral axis rather than stereogenic centers. They are useful key moieties in chiral ligands but syntheses of these substrates are tedious. 

As mentioned briefly in Chapter 2, very few publications describing cinchona alkaloid-based asymmetric reduction systems have appeared, despite the importance of this reaction, and they are restricted to the reduction of aromatic ketones. 

With regard to the catalytic asymmetric reaction , only a few successful examples, except those reactions using chiral transition metal complexes, have been reported. For example, the cinchona-alkaloid-catalyzed asymmetric 1,4-addition of thiols or 6-keto esters to Michael acceptors quinidine catalyzed the asymmetric addition of ketene to chloral and the highly enantioselective 1,4-addition of ) -keto esters in the presence of chiral crown ethers to Michael acceptors have been most earnestly studied. 

Shibata et al. [2,6] further extended this Cinchona alkaloid-mediated asymmetric transfer fluorination reaction to substrates with activated methylene groups, including acyclic (3-cyanoesters, cyclic (3-ketoesters, and oxindole substrates. Representative products, along with the optimal Cinchona alkaloids for these reactions, are shown in Scheme 13.3. Reaction conditions for the acyclic (3-cyanoesters and the cyclic (3-ketoesters used both (a) Selectfluor as the achiral electrophilic fluorine source in MeCN/CHaCla (3 4) at — 80 C and (b) dihydroquinidine acetate (DHQDA) in stoichiometric quantities. The oxindole substrates required the use of stoichiometric bis-Cinchona alkaloids, (DHQlaAQN or (DHQDlaPYR, to obtain useful yields and selectivities. Reactions of these substrates were run in MeCN at 0°C and also employed Selectfluor as the achiral electrophilic fluorine source. 

Iwabuchi Y, Furukawa M, Esumi T, Hatakeyama S (2001) An Enantio- and Stereocontrolled Synthesis of (-)-Mycestericin E via Cinchona Alkaloid-Catalyzed Asymmetric Baylis-Hillman Reaction. Chem Commun 2030... 

Moran, A. Hamilton, A. Bo, C. Melchiorre, P. A Mechanistic Rationale for the 9-Amino(9-Deoxy)Epi Cinchona Alkaloids Catalyzed Asymmetric Reactions via Iminium Ion activation of Enones.. Am. Chem. Soc. 2013,135, 9091-9098. 

Alternatively, Shibata and coworkers first realized the catalytic enantioselective synthesis of trifluoromethyl-substituted 2-isoxazolines 69 in 2010 by developing a cinchona-alkaloid-catalyzed asymmetric conjugate addition/cyclization/dehydration cascade reaction with hydroxylamines 67 and enones 68 (Scheme 2.19). A wide range of substrates could be employed in this reaction to give the desired cyclized products with excellent enantioselectivities [33]. 

Another important reaction associated with the name of Sharpless is the so-called Sharpless dihydroxylation i.e. the asymmetric dihydroxylation of alkenes upon treatment with osmium tetroxide in the presence of a cinchona alkaloid, such as dihydroquinine, dihydroquinidine or derivatives thereof, as the chiral ligand. This reaction is of wide applicability for the enantioselective dihydroxylation of alkenes, since it does not require additional functional groups in the substrate molecule ... 

Arai and co-workers have used chiral ammonium salts 89 and 90 (Scheme 1.25) derived from cinchona alkaloids as phase-transfer catalysts for asymmetric Dar-zens reactions (Table 1.12). They obtained moderate enantioselectivities for the addition of cyclic 92 (Entries 4—6) [43] and acyclic 91 (Entries 1-3) chloroketones [44] to a range of alkyl and aromatic aldehydes [45] and also obtained moderate selectivities on treatment of chlorosulfone 93 with aromatic aldehydes (Entries 7-9) [46, 47]. Treatment of chlorosulfone 93 with ketones resulted in low enantioselectivities. 

Table 1.12 Cinchona alkaloid-derived phase-transfer catalysts for asymmetric Darzens reactions.

Azirines (three-membered cyclic imines) are related to aziridines by a single redox step, and these reagents can therefore function as precursors to aziridines by way of addition reactions. The addition of carbon nucleophiles has been known for some time [52], but has recently undergone a renaissance, attracting the interest of several research groups. The cyclization of 2-(0-tosyl)oximino carbonyl compounds - the Neber reaction [53] - is the oldest known azirine synthesis, and asymmetric variants have been reported. Zwanenburg et ah, for example, prepared nonracemic chiral azirines from oximes of 3-ketoesters, using cinchona alkaloids as catalysts (Scheme 4.37) [54]. 

Azirines can be prepared in optically enriched form by the asymmetric Neber reaction mediated by Cinchona alkaloids. Thus, ketoxime tosylates 173, derived from 3-oxocarhoxylic esters, are converted to the azirine carboxylic esters 174 in the presence of a large excess of potassium carbonate and a catalytic amount of quinidine. The asymmetric bias is believed to be conferred on the substrate by strong hydrogen bonding via the catalyst hydroxyl group <96JA8491>. 

Interestingly, certain chiral tertiary bases, viz., the Cinchona alkaloids, result in an asymmetric 1,3-elimination to give enantiomerically enriched azirine esters 29 (Scheme 15). The best results were obtained with quinidine in toluene as the solvent at a rather high dilution (2 mg mL ) at 0 °C. In an alcoholic solvent no asymmetric conversion was observed. It is of importance to note that the pseudoenantiomers of the alkaloid bases gave opposite antipodes of the azirine ester, whereby quinidine leads to the predominant formation of the (k)-enan-tiomer (ee = -80%). To explain this asymmetric Neber reaction, it is suggested... 

Introduction Since we had already developed the novel asymmetric addition of lithium acetylide to ketimine 5, we did not spend any time on investigating any chiral resolution methods for Efavirenz . Our previous method was applied to 41. In the presence of the lithium alkoxide of cinchona alkaloids, the reaction proceeded to afford the desired alcohol 45, as expected, but the enantiomeric excess of 45 was only in the range 50-60%. After screening various readily accessible chiral amino alcohols, it was found that a derivative of ephedrine, (1J ,2S) l-phenyl-2-(l-pyrrolidinyl)propan-l-ol (46), provided the best enantiomeric excess of 45 (as high as 98%) with an excellent yield (vide infra). Prior to the development of asymmetric addition in detail, we had to prepare two additional reagents, the chiral modifier 46 and cyclopropylacetylene (37). 

Another microwave-mediated intramolecular SN2 reaction forms one of the key steps in a recent catalytic asymmetric synthesis of the cinchona alkaloid quinine by Jacobsen and coworkers [209]. The strategy to construct the crucial quinudidine core of the natural product relies on an intramolecular SN2 reaction/epoxide ringopening (Scheme 6.103). After removal of the benzyl carbamate (Cbz) protecting group with diethylaluminum chloride/thioanisole, microwave heating of the acetonitrile solution at 200 °C for 2 min provided a 68% isolated yield of the natural product as the final transformation in a 16-step total synthesis. 

The enantioselective hydrogenation of prochiral substances bearing an activated group, such as an ester, an acid or an amide, is often an important step in the industrial synthesis of fine and pharmaceutical products. In addition to the hydrogenation of /5-ketoesters into optically pure products with Raney nickel modified by tartaric acid [117], the asymmetric reduction of a-ketoesters on heterogeneous platinum catalysts modified by cinchona alkaloids (cinchonidine and cinchonine) was reported for the first time by Orito and coworkers [118-121]. Asymmetric catalysis on solid surfaces remains a very important research area for a better mechanistic understanding of the interaction between the substrate, the modifier and the catalyst [122-125], although excellent results in terms of enantiomeric excesses (up to 97%) have been obtained in the reduction of ethyl pyruvate under optimum reaction conditions with these Pt/cinchona systems [126-128],... 

Since Sharpless discovery of asymmetric dihydroxylation reactions of al-kenes mediated by osmium tetroxide-cinchona alkaloid complexes, continuous efforts have been made to improve the reaction. It has been accepted that the tighter binding of the ligand with osmium tetroxide will result in better stability for the complex and improved ee in the products, and a number of chiral auxiliaries have been examined in this effort. Table 4 11 (below) lists the chiral auxiliaries thus far used in asymmetric dihydroxylation of alkenes. In most cases, diamine auxiliaries provide moderate to good results (up to 90% ee). 

Scheme 19. Asymmetric Michael reaction by use of cinchona alkaloid derivatives.

In the second chapter, Hans Wynberg describes one facet—namely asymmetric catalysis—of the currently very active field of asymmetric synthesis. Wynberg and his co-workers have devised efficient asymmetric syntheses catalyzed by cinchona alkaloids. Several of these reactions are reviewed and rationalized by means of mechanistic models. 

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. 

In this chapter, we discuss recent (reported mainly during 2000-2005) asymmetric reactions catalyzed by chiral bases. Because practicality is an important factor in the present asymmetric catalysis, we restricted our discussion mainly to the reactions giving over 90% ee unless the conversion is novel. We notice, however, that there are many potentially useful and scientifically interesting reactions, in which enantioselectivity does not exceed the practical range at this moment. Chiral organic base (proline and cinchona alkaloids)-catalyzed reactions were discussed in Chapter 11 by Lelais and MacMillan. 

The focus of this review is to discuss the role of Cinchona alkaloids as Brpnsted bases in organocatalytic asymmetric reactions. Cinchona alkaloids are Lewis basic when the quinuclidine nitrogen initiates a nucleophilic attack to the substrate in asymmetric reactions such as the Baylis-Hillman (Fig. 3), P-lactone synthesis, asymmetric a-halogenation, alkylations, carbocyanation of ketones, and Diels-Alder reactions 30-39] (Fig. 4). 

Novel asymmetric conjugate-type reactions have been accomplished with Cinchona alkaloid-derived chiral thioureas, including less traditional reactions such as asymmetric decarboxylation [71]. In the following discussion, asymmetric reactions involving nitro-olefms, aldehydes and enones, and imines will be highlighted (Fig. 5). 

The asymmetric conjugate additions with thiol nucleophiles was further expanded to 2-mercaptobenzaldehydes [98]. Wang had previously developed a domino Michael-aldol reaction promoted by Cinchona alkaloids, and now illustrated the utihty of cyclohexane-diamine bifunctionalized catalysts for the domino... 

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