Bifunctional Lewis bases

The reactivity of BX3 fragments toward bifunctional Lewis bases (e.g. R2ENR2, RE(NR2)2, and E(NR2)3l E=P, As) are also of fundamental interest.It is clear that a combination of substituent inductive effects, E—N pjr-djr electronic effects, as well as steric influences are responsible for the BX3 coordination site selectivity and selected bondbreaking chemistry found in these complexes. The mechanism for hydrolytic decomposition of amine-borane complexes also continues to be of interest. A comparison of the hydrolysis of benzylamine-borane with the hydrolysis of various arylamine-boranes has been reported,and the results are important for the selection of borane adducts as practical hydridic reagents in aqueous phase reductions. 

Heterochain polymers of the type -(M-X) - contain polar M-X bonds (for reviews see [1,2,12-15]). Such polymers are often prepared by polycondensation of a bifimctional metal halide (M = B, Si, Ge, Sn, Pb, Sb, Ni, Pd, Pt, Ti, Hf) with a bifunctional Lewis base such as a diol, diamine, dihydrazine, dihydrazide, dioxime, diamideoxime, dithiol, diacetylene (Eq. 7-2). Another possibilitiy is the polyaddition of a bifunctional metal hydride to bifunctional alkenes (Eq. 7-3). Mn and mg containing poly(p-xylylenes) of the composition -(-CH2-C6H4-CH2-M-) - were produced by solid-state UV-photopolymerization of a cocondensated mixture of p-xylylene with Mn or mg at 80 K [16]. Prolonged storage of the polymers at ambient temperature under vacuum led to gradual decomposition. 

To prepare polymers containing metals (e.g., Sn, Pb, Ni, Pd, Pt, or Ti) in the main chain, use is conunonly made of the linear condensation of metal dihalides and bifunctional Lewis bases [16], such as diols, diamines, dicarboxylic acids, hydrazines, oximes, and dithiols. The preparation of such metal-containing polymers can be represented in Scheme 10.1. 

Well-defined oligoethylenes were also synthesized using organolithium compounds and a bifunctional Lewis bases with the following structures ... 

Bifunctional Lewis base organocatalyst 128 proved to be active in the simultaneous activation of the HOMO of the dienophile and the LUMO of the diene in the asymmetric inverse-electron demand Diels-Alder reaction (Scheme 24.6) [153]. In... 

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... 

Bifunctional Asymmetric Catalysis Promoted by Chiral Lewis Acid -Lewis Base Complexes... 

Naphthalene-based bifunctional Lewis acids that involve boron and a heavier group 13 element have also been prepared starting from the boron/tin derivative 30 (Scheme 15). Thus, the transmetalation reaction of 30 with gallium trichloride or indium trichloride in tetrahydrofuran (THF) results in high yields of l-(dichlorogallium)-8-(dimesitylboron)naphthalenediyl 35 and l-(dichloroindium)-8-(dimesitylboron)... 

CHIRAL LEWIS BASE-LEWIS ACID BIFUNCTIONAL CATALYSIS... 

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. 

In related work, Sasai developed several bifunctional BINOL-derived catalysts for the aza-Morita-Baylis-Hillman (aza-MBH) reaction [111]. In early studies, careful optimization of the catalyst structure regarding the location of the Lewis base unit revealed 41 as an optimal catalyst for the aza-MBH reaction between acyclic a,P-unsaturated ketones and N-tosyl imines. Systematic protection or modification of each basic and acidic moiety of 41 revealed that all four heterofunctionalities were necessary to maintain both chemical and optical yields. As seen in Scheme 5.58, MO calculations suggest that one hydroxyl groups forms a... 

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 ... 

Chiral BINOL (60) is a bifunctional organocatalyst in addition to the phenolic Brpnsted acid groups, it has a Lewis base unit attached via a spacer moiety.167 This particular combination holds the groups in a conformational lock, where they can doubly activate a substrate while giving a high level of stereocontrol. For this example of an aza-Morita-Baylis-Hillman reaction of an enone and an imine, yields up to 100% and ees up to 96% have been achieved. 

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... 

Catalytic, enantioselective addition of silyl ketene acetals to aldehydes has been carried out using a variant of bifunctional catalysis Lewis base activation of Lewis acids.145 The weakly acidic SiCU has been activated with a strongly basic phor-phoramide (the latter chiral), to form a chiral Lewis acid in situ. It has also been extended to vinylogous aldol reactions of silyl dienol ethers derived from esters. 

A bifunctional LA combining the attributes of VIII and the 9-borafluorene LA VI has also been prepared by treating l,2-(BBr2)2C6F4 with the stannole reagent shown in Eq (7).191 This chelating LA is more sterically open than VIII, and this is reflected in the greater propensity of XI to coordinate sterically moderate Lewis bases like THF. In fact, the diborane VIII does not react with THF, while diborole XI is able to coordinate two... 

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. 

Asymmetric organocatalytic Morita-Baylis-Hillman reactions offer synthetically viable alternatives to metal-complex-mediated reactions. The reaction is best mediated with a combination of nucleophilic tertiary amine/phosphine catalysts, and mild Bronsted acid co-catalysts usually, bifunctional chiral catalysts having both nucleophilic Lewis base and Bronsted acid site were seen to be the most efficient. Although many important factors governing the reactions were identified, our present understanding of the basic factors, and the control of reactivity and selectivity remains incomplete. Whilst substrate dependency is still considered to be an important issue, an increasing number of transformations are reaching the standards of current asymmetric reactions. 

Continuing studies on 18F-fluoroalkylation of H-acidic compounds using the bifunctional fluoroalkanes 18F(CH2) X( = 1-3, X = Br, OMs, OTos) in the presence of the aminopolyether 2.2.2/potassium carbonate complex, Stocklin and coworkers171 obtained the best NCA labelling yields with tosylates. Fluoroethylation and fluoropropylation of phenol (equation 79) has been carried out with radiochemical yields of > 90%. In principle all Lewis bases are potential substrates for NCA fluoroalkylation. 

The most commonly used type of catalyst is a relatively small, bifunctional molecule that contains both a Lewis base and a Bronsted acid center, the catalytic properties being based on the activation of both the donor and the acceptor of the substrates. The majority of organocatalysts are chiral amines, e.g. amino acids or peptides. The acceleration of the reaction is either based on a charge-activated reaction (formation of an imminium ion 4), or involves the generalized enamine catalytic cycle (formation of an enamine 5). In an imminium ion, the electrophilicity compared to a keton or an oxo-Michael system is increased. If the imminium ion is deprotonated to form an enamine species, the nucleophilicity of the a-carbon is increased by the electron-donating properties of the nitrogen. ... 

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