Cinchona alkaloid-derived enantioselective

Cinchona Alkaloid-Derived Enantioselective Separation Materials.. 

M. Lammerhofer and W. Lindner. Liquid chromatographic enantiomer separation and chiral recognition by Cinchona alkaloid-derived enantioselective separation materials. In Advances in Chromatography, Vol. 46, ed. E. Grushka and N, Grinberg. Boca Raton, FL CRC Press, Taylor Francis Group, 2008. 

One of the most significant developmental advances in the Jacobsen-Katsuki epoxidation reaction was the discovery that certain additives can have a profound and often beneficial effect on the reaction. Katsuki first discovered that iV-oxides were particularly beneficial additives. Since then it has become clear that the addition of iV-oxides such as 4-phenylpyridine-iV-oxide (4-PPNO) often increases catalyst turnovers, improves enantioselectivity, diastereoselectivity, and epoxides yields. Other additives that have been found to be especially beneficial under certain conditions are imidazole and cinchona alkaloid derived salts vide infra). 

Epoxidations and Darzens Condensations The asymmetric catalytic epoxida-tion of a,p-unsaturated ketones using cinchona alkaloid-derived catalysts was introduced in the 19708. However, high levels of enantioselectivity were achieved only 20 years later, when Lygo, Arai, 2-t94 others P ... 

Darzens condensation using crown ethers and cinchona alkaloids-derived catalysts, respectively, obtaining epoxides with moderate enantioselectivity. 

A new cinchona alkaloid-derived catalyst has been developed for the enantioselective Strecker reaction of aryl aldimines via hydrogen-bonding activation. For reference, see Huang, J. Corey, E. J. Org. Lett. 2004, 6, 5027-5029. 

New catalyst design further highlights the utility of the scaffold and functional moieties of the Cinchona alkaloids. his-Cinchona alkaloid derivative 43 was developed by Corey [49] for enantioselective dihydroxylation of olefins with OsO. The catalyst was later employed in the Strecker hydrocyanation of iV-allyl aldimines. The mechanistic logic behind the catalyst for the Strecker reaction presents a chiral ammonium salt of the catalyst 43 (in the presence of a conjugate acid) that would stabilize the aldimine already activated via hydrogen-bonding to the protonated quinuclidine moiety. Nucleophilic attack by cyanide ion to the imine would give an a-amino nitrile product (Scheme 10). 

Nitroaldol (Henry) reactions of nitroalkanes and a carbonyl were investigated by Hiemstra [76], Based on their earlier studies with Cinchona alkaloid derived catalysts, they were able to achieve moderate enantioselectivities between aromatic aldehydes and nitromethane. Until then, organocatalyzed nitroaldol reactions displayed poor selectivities. Based on prior reports by Sods [77], an activated thionrea tethered to a Cinchona alkaloid at the quinoline position seemed like a good catalyst candidate. Hiemstra incorporated that same moiety to their catalyst. Snbsequently, catalyst 121 was used in the nitroaldol reaction of aromatic aldehydes to generate P-amino alcohols in high yield and high enantioselectivities (Scheme 27). 

A polymeric cinchona alkaloid-derived ligand 44 was prepared and used to catalyze the asymmetric dihydroxylation of olefins (see the diagram below).66 Both aliphatic and aromatic olefins afforded diols with good enantioselectivities. 

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). 

Recently, chiral phase-transfer-catalyzed asymmetric Michael addition has received much attention, and excellent enantioselectivity (up to 99% ee) has been reported using cinchona alkaloid-derived chiral phase-transfer catalysts [40]. Among noncinchona alkaloid-derived chiral phase-transfer catalysts Shibasaki s tartrate derived C2-symmetrical two-center catalyst provided a Michael adduct with up to 82% ee [41]. 

Asymmetric epoxidation catalyzed by chiral phase-transfer catalysts is another reaction which has been extensively studied following an initial report by Wynberg [2,44]. Shioiri et al. further improved the enantioselective epoxidation of naphthoquinones under cinchona alkaloid-derived chiral phase-transfer catalysis [45],... 

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). 

The chiral phase-transfer catalyst 3 afforded product 61 in 49% ee. The same group studied this reaction further by employing monodeazacinchona derivatives 14a-c [17]. The newly prepared non-natural analogues of cinchona alkaloids effectively promoted the hydroxylation reaction, although the enantioselectivity was lower than with natural cinchona alkaloid-derived chiral phase-transfer catalysts (Scheme 7.15). 

Currently, this area is not as well developed as the use of cinchona alkaloid derivatives or spiro-ammonium salts as asymmetric phase-transfer catalysts, and the key requirements for an effective catalyst are only just becoming apparent. As a result, the enantioselectivities observed using these catalysts rarely compete with those obtainable by ammonium ion-derived phase-transfer catalysts. Nevertheless, the ease with which large numbers of analogues - of Taddol, Nobin, and salen in particular- can be prepared, and the almost infinite variety for the preparation of new, chiral metal(ligand) complexes, bodes well for the future development of more enantioselective versions of these catalysts. 

Some bifunctional 6 -OH Cinchona alkaloid derivatives catalyse the enantioselective hydroxyalkylation of indoles by aldehydes and a-keto esters.44 Indole, for example, can react with ethyl glyoxylate to give mainly (39) in 93% ee. The enan- tioselective reaction of indoles with iV-sulfonyl aldimines [e.g. (40)] is catalysed by the Cu(OTf)2 complex of (S)-benzylbisoxazoline (37b) to form 3-indolylmethanamine derivatives, in up to 96% ee [e.g. (41a)] 45 Some 9-thiourea Cinchona alkaloids have been found to catalyse the formation of 3-indolylmethanamines [e.g. (41b)] from indoles and /V-PhS02-phenyli mines in 90% ee.46 Aryl- and alkyl-imines also give enantioselective reactions. 

The Cinchona alkaloid-derived thiourea (112), has been developed as an organocat-alyst for conjugate addition of a wide range of nucleophilic enol species to enones. The reaction is characterized by high enantioselectivities and mild reaction condition.160... 

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

The highest enantioselectivity (up to >99%) yet achieved in the addition of S-nucleophiles to enones was reported in 2002 by Deng et al. [59]. By systematic screening of monomeric and dimeric cinchona alkaloid derivatives they identified the dihydroquinidine-pyrimidine conjugate (DHQD PYR (72, Scheme 4.35) as the most effective catalyst. This material is frequently used in the Sharpless asymmetric dihydroxylation and is commercially available. Screening of several aromatic thiols resulted in the identification of 2-thionaphthol as the nucleophile giving best yields and enantioselectivity. Examples for the (DHQD PYR-catalyzed addition of 2-thionaphthol to enones are summarized in Scheme 4.35. 

Michael addition of nitromethane to chalcones can be catalysed by cinchona alkaloid-derived chiral bifunctional thiourea (142) (0.5-10 mol%) to give the corresponding products at 25-100 °C in high chemical yields and high enantioselectivity ... 

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]. 

The use of bifunctional thiourea-substituted cinchona alkaloid derivatives has continued to gamer interest, with the Deng laboratory reporting the use of a 6 -thiourea-substituted cinchona derivative for both the Mannich reactions of malo-nates with imines [136] and the Friedel-Crafts reactions of imines with indoles [137]. In both reports, a catalyst loading of 10-20 mol% provided the desired products in almost uniformly high yields and high enantioselectivities. Thiourea-substituted cinchona derivatives have also been used for the enantioselective aza-Henry reactions of aldimines [138] and the enantioselective Henry reactions of nitromethane with aromatic aldehydes [139]. 

Petri, A., Pini, D. and Salvadori, P. Heterogeneous enantioselective dihydroxylation of aliphatic olefins - A comparison between different polymeric cinchona alkaloid derivatives, Tetrahedron Lett., 1995, 36, 1549-1552. 

Another important asymmetric epoxidation of a conjugated systems is the reaction of alkenes with polyleucine, DBU and urea H2O2, giving an epoxy-carbonyl compound with good enantioselectivity. The hydroperoxide anion epoxidation of conjugated carbonyl compounds with a polyamino acid, such as poly-L-alanine or poly-L-leucine is known as the Julia—Colonna epoxidation Epoxidation of conjugated ketones to give nonracemic epoxy-ketones was done with aq. NaOCl and a Cinchona alkaloid derivative as catalyst. A triphasic phase-transfer catalysis protocol has also been developed. p-Peptides have been used as catalysts in this reaction. ... 

---