Bifunctional catalysts Lewis acid/base

The majority of the organocatalysts that are commonly employed are chiral Lewis or Brpnsted bases, and the catalytic potential of base functionalities has been referred to in previous chapters to some extent already. As discussed before, the use of chiral primary or secondary amines for enamine or iminium activation belongs to the most important applications of asymmetric organocatalysts nowadays. In addition, also the interplay between an acidic (thio)urea and a basic amine separated by a chiral linker was shown to enable the simultaneous activation of both the electrophile and nucleophile. In addition to such bifunctional thiourea-containing acid-base catalysts, chiral catalysts containing a (Lewis or... 

Although boron is a metalloid, one can nonetheless include boron-derived compounds in a book on organocatalysis as not being transition metal containing catalysts Planar chiral boronic acids have been employed as amide couphng catalysts, actually as bifunctional Lewis acid/base activators. Whiting s [51] group reported the preparation [52] of two amino-boronic ferrocenes (see Scheme 8.17). Their use... 

Carbon nucleophiles reactions facilitated by Lewis acid/base bifunctional catalysts Phosphine-boronates (354) have been developed as bifiinctional organocatalysts (combining a Lewis base and Lewis acid in the same molecule) for the Michael addition of malonates R CH(C02R )2 to CH2=CHCOMe. The -phosphonium enolate (355)... 

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>. 

Another example is the asymmetric cyanosilylation of aldehydes catalyzed by bifunctional catalyst 131.100 Compound 131 contains aluminum, the central metal, acting as a Lewis acid, and group X, acting as a Lewis base. The asymmetric cyanosilylation, as shown in Scheme 8-50, proceeds under the outlined... 

Snapper and Hoveyda reported a catalytic enantioselective Strecker reaction of aldimines using peptide-based chiral titanium complex [Eq. (13.11)]. Rapid and combinatorial tuning of the catalyst structure is possible in their approach. Based on kinetic studies, bifunctional transition state model 24 was proposed, in which titanium acts as a Lewis acid to activate an imine and an amide carbonyl oxygen acts as a Bronsted base to deprotonate HCN. Related catalyst is also effective in an enantioselective epoxide opening by cyanide "... 

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. 

The oxonium ylide mechanism requires a bifunctional acid-base catalyst. The validity of the oxonium ylide mechanism on zeolites was questioned459,461,464 because zeolites do not necessarily possess sufficiently strong basic sites to abstract a proton from the trimethyloxonium ion to form an ylide. It should, however, be pointed out, as emphasized by Olah,447,465 that over solid acid-base catalysts (including zeolites) the initial coordination of an electron-deficient (i.e., Lewis acidic) site of the catalysts allows formation of a catalyst-coordinated dimethyl ether complex. It then can act as an oxonium ion forming the catalyst-coordinated oxonium ylide complex (10) with the participation of surface bound CH30 ions ... 

A chiral alumi n i u m - s a I e n - PI13 PO combination catalyses addition to ketones in up to 92% ee the catalyst system essentially acts as a Lewis acid-Lewis base bifunctional system.248 A similar chiral manganese(III)-salen-Ph3PO method is comparable.249... 

An enantioselective Strecker cyanation of ketoimines exploits Lewis acid-Lewis base bifunctional catalysts.79... 

Another class of bifunctional organocatalysts for the enantioselective aza-Morita-Baylis-Hillman reaction of imines (112) with enones (113) (Scheme 6) is based on BINOL (115). The efficiency of the catalysts proved to be mainly influenced by the position of the Lewis basic moiety attached to the BINOL scaffold. The activation of the substrate by acid-base functionalities and the fixing of conformation of the catalyst (115) are apparently harmonized to maximize the enantiocontrol (<95% ee) 52... 

Shibasaki and co-workers disclosed a general asymmetric Strecker-type reaction that was controlled by bifunctional Lewis acid-Lewis base catalyst 14 [10], N-Fluorenylimines 15 underwent catalytic asymmetric Strecker-type reactions with binaphthol catalyst 14 to give a-aminonitriles 16 in good to excellent enantioselectivities and yields (Scheme 6). a-Aminonitrile 16 (R = Ph) could then be converted to a-aminoamide 17 in several steps. Aromatic, aliphatic, heterocyclic and a,/f-unsaturated imines 15 were used as general substrates in these reactions. The origin of the highly enantioselective cataylsis by 14 is believed to be attributed to the simultaneous activation of imines and trimethylsilyl cyanide by the... 

Scheme 6. Asymmetric Strecker synthesis with bifunctional Lewis acid-Lewis base catalyst 14 (Shibasaki and co-workers). DDQ = 2,3-dichloro-5,6-dicyano-l, 4-benzoquinone.

Considerable effort has been devoted to the development of enantiocatalytic MBH reactions, either with purely organic catalysts, or with metal complexes. Paradoxically, metal complex-mediated reactions were usually found to be more efficient in terms of enantioselectivity, reaction rates and scope of the substrates, than their organocatalytic counterparts [36, 56]. However, this picture is actually changing, and during the past few years the considerable advances made in organocatalytic MBH reactions have allowed the use of viable alternatives to the metal complex-mediated reactions. Today, most of the organocatalysts developed are bifunctional catalysts in which the chiral N- and P-based Lewis base is tethered with a Bronsted acid, such as (thio)urea and phenol derivatives. Alternatively, these acid co-catalysts can be used as additives with the nucleophile base. 

Artificial enzymes with metal ions can also hydrolyze phosphate esters (alkaline phosphatase is such a natural zinc enzyme). We examined the hydrolysis of p-nitro-phenyfdiphenylphosphate (29) by zinc complex 30, and also saw that in a micelle the related complex 31 was an even more effective catalyst [118]. Again the most likely mechanism is the bifunctional Zn-OH acting as both a Lewis acid and a hydroxide nucleophile, as in many zinc enzymes. By attaching the zinc complex 30 to one or two cyclodextrins, we saw even better catalysis with these full enzyme mimics [119]. A catalyst based on 25 - in which a bound La3+ cooperates with H202, not water - accelerates the cleavage of bis-p-nitrophenyl phosphate by over 108-fold relative to uncatalyzed hydrolysis [120]. This is an enormous acceleration. 

Lectka and colleagues have reacted achiral ketenes with achiral imines to achieve asymmetric induction in the synthesis of cfs-P-lac tarns through the use of a bifunctional catalyst system consisting of a chiral base (benzoylquinine) and an achiral Lewis acid <020L1603> <02JACS6626>. 

Shibasaki and Groger developed lanthanide/alkali binapthoxide-based Lewis acid-Brpnsted base bifunctional catalysts [44]. One such example, the (R,R)-Ln-M-linked BINOL complex. 

A mechanism for this reaction has been proposed and is summarized in Sch. 10. The catalyst 64 is thought to be bifunctional with the aluminum center operating as a Lewis acid and the lithium naphthoxide operating as a Lowry-Brpnsted base. It was envisaged that the aldehyde coordinates with the aluminum to give the complex 69 and deprotonation of the dimethyl phosphite then gives the aggregate 70 in which the phosphite anion is positioned for P-alkylation of the aldehyde that will occur selectively from the si face when the catalyst is prepared from (f )-BINOL. 

The assymetric Strecker reaction of diverse imines, including aldimines as well as ketoimines, with HCN or TMSCN provides a direct access to various unnatural and natural amino acids in high enantiomeric excesses, using soluble or resin-linked non-metal Schiff bases the corresponding chiral catalysts are obtained and optimized by parallel combinatorial library synthesis [93]. A rather general asymmetric Strecker-type synthesis of various imines and a, 9-unsaturated derivatives is catalyzed by chiral bifunctional Lewis acid-Lewis base aluminum-containing complexes [94]. When chiral (salen)Al(III) complexes are employed for the hydrocyanation of aromatic substituted imines, excellent yields and enatio-selectivities are obtained [94]. 

Takamura, M., Hamashima, Y., Usuda, H., Kanai, M., Shibasaki, M. A catalytic asymmetric Strecker-type reaction promoted by Lewis acid-Lewis base bifunctional catalyst. Chem. Pharm. Bull. 2000,48, 1586-1592. 

On the basis of the achievements described above, the opening of the oxaza-phospholidine ring would lead to the formation of a new bifunctional chiral catalyst possessing Lewis acid and Lewis base moieties [39]. This catalyst could activate both electrophiles and nucleophiles at defined positions. 

The bifunctional Lewis acid-Lewis base catalyst 55 has been applied with success to the asymmetric Strecker type reaction [61] (Table 8). 

As above, the driving force for both reactions is ammonia removal. Both reactions (10a) and (10b) are catalyzed by a combination of a weak Lewis acid and a weak Lewis base, such as equimolar amounts of A1(/-Bu)2H and PPh3. These bifunctional catalysts reduce the formation of by-products from carbamate decomposition. The above reactions could be carried out in two separate steps or in one pot when in the presence of tin(IV) compounds as catalysts for the second reaction. 

The Lewis acid-Lewis base bifunctional catalyst 178a, prepared from Ti(Oi-Pr)4 and diol 174 (1 1), realizes highly enantioselective cyanosilylation of a variety of ketones to (R)-cyanohydrin TMS ethers (Scheme 10.241) [645]. The proposed mechanism involves Ti monocyanide complex 178b as the active catalyst this induces reaction of aldehydes with TMSCN by dual activation. Interestingly, the catalyst prepared from Gd(Oi-Pr)3 and 174 (1 2) serves for exclusive formation of (S)-cyanohy-drin TMS ethers [651]. The catalytic activity of the Gd complex is much higher than that of 178a. The results of NMR and ESI-MS analyses indicate that Gd cyanide complex 179 is the active catalyst. It has been proposed that the two Gd cyanide moieties of 179 play different roles - one activates an aldehyde as a Lewis acid and the other reacts with the aldehyde as a cyanide nucleophile. 

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