Chiral bifunctional catalysts

Chen and co-workers utilized the chiral bifunctional catalysts to directly access vinylogous carbon-carbon bonds via the asymmetric Michael addition of a,a-dicy-ano-olefms to nitro-olefms [102]. The scope of the reaction was explored with a variety of substituted a,a-dicyano-olefins and P-substituted nitro-olefms (Scheme 50). The authors propose the catalysf s tertiary amine functionality depro-tonates the cyano-olefm, activating the nucleophile to add to the -face of the pre-coordinated nitro-olefm. 

Scheme 8.19 Supported thiourea derivative as chiral bifunctional catalyst.

In this section, examples of transformations mediated by chiral bifunctional catalysts are presented, focusing on cinchona alkaloids, cinchona-alkaloid-derived thioureas, and cyclohexane-diamine catalysts (Figure 11). 

Shibasaki and coworkers reported highly general Strecker-type reaction of N-fluorenyl aldimines with TMSCN catalyzed by chiral bifunctional catalyst (64a) (Scheme 6.49) [63]. In this case, the use of small amount of PhOH as a proton source resulted in both rate acceleration and high enantioselectivity. Interestingly, it was... 

In 1981, Wynberg and Hiemstra already identified the unmodified cinchona alkaloids as chiral bifunctional catalysts for enantioselective conjugate additions to cycloalkenones [3]. They proposed that the OH group of cinchonine would act as a hydrogen bond donor site and stabilize the enolate-Uke transition state of the conjugate addition reaction (Scheme 6.1). 

The design and development of bifunctional organocatalysts is of ongoing interest in organic synthetic chemistry [31]. The strategy by simultaneously activating both a nucleophile and an electrophile with a chiral bifunctional catalyst allows the... 

Additions to quinoline derivatives also continued to be reported last year. Chiral dihydroquinoline-2-nitriles 55 were prepared in up to 91% ee via a catalytic, asymmetric Reissert-type reaction promoted by a Lewis acid-Lewis base bifunctional catalyst. The dihydroquinoline-2-nitrile derivatives can be converted to tetrahydroquinoline-2-carboxylates without any loss of enantiomeric purity <00JA6327>. In addition the cyanomethyl group was introduced selectively at the C2-position of quinoline derivatives by reaction of trimethylsilylacetonitrile with quinolinium methiodides in the presence of CsF <00JOC907>. The reaction of quinolylmethyl and l-(quinolyl)ethylacetates with dimethylmalonate anion in the presence of Pd(0) was reported. Products of nucleophilic substitution and elimination and reduction products were obtained . Pyridoquinolines were prepared in one step from quinolines and 6-substituted quinolines under Friedel-Crafts conditions <00JCS(P1)2898>. 

Shibasaki et al. developed a polymer-supported bifunctional catalyst (33) in which aluminum was complexed to a chiral binaphtyl derivative containing also two Lewis basic phosphine oxide-functionahties. The binaphtyl unit was attached via a non-coordinating alkenyl Hnker to the Janda Jel-polymer, a polystyrene resin containing flexible tetrahydrofuran-derived cross-Hnkers and showing better swelling properties than Merifield resins (Scheme 4.19) [105]. Catalyst (33) was employed in the enantioselective Strecker-type synthesis of imines with TMSCN. 

Dicarbonyl compounds are widely used in organic synthesis as activated nucleophiles. Because of the relatively high acidity of the methylenic C—H of 1,3-dicarbonyl compounds, most reactions involving 1,3-dicarbonyl compounds are considered to be nucleophilic additions or substitutions of enolates. However, some experimental evidence showed that 1,3-dicarbonyl compounds could react via C—H activations. Although this concept is still controversial, it opens a novel idea to consider the reactions of activated C H bonds. The chiral bifunctional Ru catalysts were used in enantioselective C C bonds formation by Michael addition of 1,3-dicarbonyl compounds with high yields and enantiomeric excesses. ... 

Finally in Chapters 11-13, some of the more recent discoveries that have led to a renaissance in the field of organocatalysis are described. Included in this section are the development of chiral Brdnsted acids and Lewis acidic metals bearing the conjugate base of the Bronsted acids as the ligands and the chiral bifunctional acid-base catalysts. 

Keywords Asymmetric organocatalysis Bifunctional catalyst Brpnsted base Chiral scaffold Cinchona akaloid Cyclohexane-diamine Guanidine... 

Following work on Michael addition of triazoles to nitro-olefins (discussed in Sect. 2.5), bifunctional chiral thiourea catalysts were used in the addition of triazoles to chalcones [83]. The catalytic system was applicable to enones bearing aromatic groups of varying electronic natures to provide good yields and moderate selectivity. a-Cyanoacetates [84] were also applied in Michael addition to chalcones under similar catalytic conditions (Scheme 33). 

Bifunctional catalysts have proven to be very powerful in asymmetric organic transformations [3], It is proposed that these chiral catalysts possess both Brpnsted base and acid character allowing for activation of both electrophile and nucleophile for enantioselective carbon-carbon bond formation [89], Pioneers Jacobsen, Takemoto, Johnston, Li, Wang and Tsogoeva have illustrated the synthetic utility of the bifunctional catalysts in various organic transformations with a class of cyclohexane-diamine derived catalysts (Fig. 6). In general, these catalysts contain a Brpnsted basic tertiary nitrogen, which activates the substrate for asymmetric catalysis, in conjunction with a Brpnsted acid moiety, such as urea or pyridinium proton. 

Axially chiral phosphoric acid 3 was chosen as a potential catalyst due to its unique characteristics (Fig. 2). (1) The phosphorus atom and its optically active ligand form a seven-membered ring which prevents free rotation around the P-0 bond and therefore fixes the conformation of Brpnsted acid 3. This structural feature cannot be found in analogous carboxylic or sulfonic acids. (2) Phosphate 3 with the appropriate acid ity should activate potential substrates via protonation and hence increase their electrophilicity. Subsequent attack of a nucleophile and related processes could result in the formation of enantioenriched products via steren-chemical communication between the cationic protonated substrate and the chiral phosphate anion. (3) Since the phosphoryl oxygen atom of Brpnsted acid 3 provides an additional Lewis basic site, chiral BINOL phosphate 3 might act as bifunctional catalyst. 

Shortly thereafter, Terada demonstrated that the Mannich reaction between several N-Boc aryl imines and acetoacetone was effectively catalyzed by only 2 mol% of le (Scheme 5.2) [4]. In view of AMyama s work, this study is particularly significant because it suggested that le may act as a bifunctional catalyst [9] not only to form a chiral ion pair with the electrophile but also to activate the nucelo-phile through hydrogen bonding of the a-proton with Lewis basic phosphoryl oxygen. 

In 2007, Wang and co-workers published a protocol for an enantio- and diastereoselective domino Michael-aldol reaction using electron-rich and electron-deficient 2-mercaptobenzaldehydes and maleimides as substrates [223]. The conversion was described to proceed smoothly in the presence of bifunctional catalyst 12 (lmol% loading) in xylenes at 0°C reaction temperature producing the desired chiral succinimide-containing substituted thiochromanes 1-5 in high yields (83-96%), in synthetically useful ee values (74—94%), and diastereoselectivities (up to dr 20 1) in 7h reaction time (Scheme 6.71). 

The modification of thiourea catalyst 93 through incorporation of the (S,S)-diaminocyclohexane backbone as an additional chirality element and a Schiff base imidazoyl-moiety led to the bifunctional catalyst 94 that, in contrast to 93 in the Strecker reaction (Scheme 6.99), exhibited enantioinduction (83-87% ee) in the nitro-Michael addition of acetone to trons-P-nitrostyrenes. The desired adducts were isolated in moderate yields (46-62%) as depicted in Scheme 6.100) [259]. 

M. Shi and Y.-L. Shi reported the synthesis and application of new bifunctional axially chiral (thio) urea-phosphine organocatalysts in the asymmetric aza-Morita-Baylis-Hillman (MBH) reaction [176, 177] of N-sulfonated imines with methyl vinyl ketone (MVK), phenyl vinyl ketone (PVK), ethyl vinyl ketone (EVK) or acrolein [316]. The design of the catalyst structure is based on axially chiral BINOL-derived phosphines [317, 318] that have already been successfully utilized as bifunctional catalysts in asymmetric aza-MBH reactions. The formal replacement of the hydrogen-bonding phenol group with a (thio)urea functionality led to catalysts 166-168 (Figure 6.51). 

The asymmetric alcoholytic ring opening of 4-substituted-2-phenyl-4,5-dihydro-l,3-oxazin-6-ones proved to be a efficient method for the preparation of enatiomerically pure /3-amino acid derivatives <2005AGE7466>. Treatment of 2,4-diphenyl-4,5-dihydro-l,3-oxazin-6-one 208 in the presence of the bifunctional chiral thiourea catalyst 211 resulted in formation of an enantiomerically enriched mixture of the unchanged oxazinone (iJ)-208 and allyl (4)-3-benzoyl-amino-3-phenylpropanoate 209. The resolved material (iJ)-208 and the product 209 could easily be separated by a selective hydrolytic procedure that converted oxazinone (iJ)-208 quantitatively into the insoluble iV-benzoyl /3-amino acid 210 (Scheme 37). 

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