Nucleophilic addition with carbonyl compounds

The stereoselectivity of organometallic additions with carbonyl compounds fits into the general pattern for nucleophilic attack discussed in Chapter 3. With 4-r-butylcyclohex-anone, there is a preference for equatorial approach but the selectivity is low. Enhanced steric factors promote stereoselective addition. 

Alkyl substituents accelerate electrophilic addition reactions of alkenes and retard nucleophilic additions to carbonyl compounds. The bonding orbital of the alkyl groups interacts with the n bonding orbital, i.e., the HOMO of alkenes and raises the energy (Scheme 22). The reactivity increases toward electron acceptors. The orbital interacts with jt (LUMO) of carbonyl compounds and raises the energy (Scheme 23). The reactivity decreases toward electron donors. 

These reactions comprise nucleophilic SN2 substitutions, -eliminations, and nucleophilic additions to carbonyl compounds or activated double bonds, etc. They involve the reactivity of anionic species Nu associated with counterions M+ to form ion-pairs with several possible structures [52] (Scheme 3.4). 

The most important application of organolithium reagents is their nucleophilic addition to carbonyl compounds. One of the simplest cases would be the reaction with the molecule CO itself, whose products are stable at room temperature. Recently, it was shown that a variety of RLi species are able to react with CO or f-BuNC in a newly developed liquid xenon (LXe) cell . LXe was used as reaction medium because it suppresses electron-transfer reactions, which are known to complicate the reaction . In this way the carbonyllithium and acyllithium compounds, as well as the corresponding isolobal isonitrile products, could be characterised by IR spectroscopy for the first time. 

Nucleophilic Addition to Carbonyl Compounds and -Unsaturated Carbonyl Compounds.—Although the reactions of 17-oxo-steroids with various carbanion reagents are reported to have varying success/ the use of alcohols or DMF as solvents appears to facilitate the Wittig-Horner reaction/ For example, the ketone (97) was converted with (Et0)2P0CHC02Et into the E-ethyl ester (98) in... 

Allyl- and vinylsilane chemistry was one of the first areas of reagent synthesis impacted by CM methodology. Allylsilanes are commonly employed in nucleophilic additions to carbonyl compounds, epoxides, and Michael acceptors (the Sakurai reaction) vinylsilanes are useful reagents for palladium-coupling reactions. As the ubiquitous application of CM to this substrate class has recently been described in several excellent reviews, this topic will not be discussed in detail, with the exception of the use of silane moieties to direct CM stereoselectivity (previously discussed in Section 11.06.3.2). 

In 1977, an article from the authors laboratories [9] reported an TiCV mediated coupling reaction of 1-alkoxy-l-siloxy-cyclopropane with aldehydes (Scheme 1), in which the intermediate formation of a titanium homoenolate (path b) was postulated instead of a then-more-likely Friedel-Crafts-like mechanism (path a). This finding some years later led to the isolation of the first stable metal homoenolate [10] that exhibits considerable nucleophilic reactivity toward (external) electrophiles. Although the metal-carbon bond in this titanium complex is essentially covalent, such titanium species underwent ready nucleophilic addition onto carbonyl compounds to give 4-hydroxy esters in good yield. Since then a number of characterizable metal homoenolates have been prepared from siloxycyclopropanes [11], The repertoire of metal homoenolate reactions now covers most of the standard reaction types ranging from simple... 

Hydroboration of allenes 65 with pinacolborane in the presence of Pt(DBA)2 and a trialkylphosphine provides either the allyl boronate 66 or the vinyl boronate 67 regioselectively, depending on the stereoelectronic factors of the phosphine employed (Equation 2) <1999CL1069>. Allyl and vinyl boronates are synthetically important because of their ability to undergo nucleophilic addition to carbonyl compounds as well as transition metal-catalyzed cross-coupling. 

Jencks (1972, 1969b) has proposed a model which maintains the significance of a as a measure of transition state structure and yet provides a very elegant rationalization of the fact that linear Br nsted plots are often obtained over large reactivity ranges, both by variation in catalyst pKa and substrate reactivity. Jencks noted that the acid catalysed nucleophilic addition to carbonyl compounds (21) yielded linear Br nsted plots (in apparent violation of the reactivity-selectivity principle) yet as the basicity of the nucleophile N was increased the Br nsted slope decreased (in agreement with the... 

Aromatic oxazolines such as (99 Scheme 10) have also been used as chiral nucleophiles. Additions to carbonyl compounds occur with only modest stereoselectivities. Hie highest ratio of dia-stereomers produced (64 36) occurs when acetophenone is used as substrate. A stericdly undemanding transition state probably accounts for these disappointing results. 

Alkyltitanium(IV) complexes having N -dialkylamino ligand systems, RTi(NR 2)3, fail to give nucleophilic additions to carbonyl compounds (Section 1.5.3.1.1). Their reaction with aldehydes leads instead to tertiary amines by addition of both the alkyl moiety of the reagent and one of the N, -dialkylamino ligands (equation 59). The synthetic interest of the reaction is restricted to noneno-lizable aldehydes, since enolizable carbonyl compounds lead to enamines. ... 

Dimethyl-4,8-dioxaspiro[2.5]oct-l-ene is a synthetically useful precursor for cyclopropenones because of its stability and ready availability. The sodium derivative 1 of the cyclopropenone acetal in liquid ammonia reacted with alkyl halides giving alkyl-substituted cyclopropenone acetals 3. The lithiated cyclopropenone acetal 4 was generated by treating the cyclopropenone acetal with one equivalent of butyllithium in tetrahydrofuran. Reaction of the lithium carbanion 4 with alkyl halides proceeded cleanly in the presence of two equivalents of hexamethylphosphoric triamide (Table 1, entries 1-4). The lithium compound underwent nucleophilic addition to carbonyl compounds smoothly at — 70 C giving hydroxymethyl derivatives 5 (Table 1, entries 5-10). 

Abstract This chapter deals with the facial selectivity of nucleophilic additions to carbonyl compounds. This is explained using models such as the Cram s model, Anh-Felkin modification of Cram s model, Houk s transition structure model, Houk s electrostatic model, Cieplak s a —> cr model, and cation coordination model. The intricacies, variations, and predicted selectivities of these models are elaborated with examples. It has been argued that the Cieplak s cr > cr model is applicable to only those reactions that proceed through product-like transition structures. Using the cation coordination model, the facial selectivities of a number of substrates, including the better anrf-selectivity of endo,endo-2,3-die hyl-l -norbomanone in comparison to that of en[Pg.71]

There are two major reactions of enolates (1) displacement reactions with alkyl halides or other suitable electrophiles and (2) nucleophilic addition to carbonyl compounds. Reaction of 58 with butanal to give 59 and reaction of 61 with bromopentane to give 62 are simple examples of each process. Enolate anions function as carbon nucleophiles and their reactions are fundamentally the same as those discussed in Section 8.3.C for acetylides. Although there are interesting differences, treating an enolate anion as a carbon nucleophile is very reasonable. 

Another often discussed set of electronic effects in the transition state involves interaction of a stretched or forming (incipient) bond with the adjacent donors and acceptors. This interaction has been discussed particularly frequently in relation to the selectivity of nucleophilic additions to carbonyl compounds. Cram first proposed arguments based on steric effects, which were expanded upon by Felkin and Anh. The Felkin-Anh model suggests that the best acceptor group is positioned antiperiplanar to the incoming nucleophile in order to maximize a... 

Following from the examples of allyltrichlorosilanes 21.5, Denmark introduced the related eno)g4 richlorosilanes 21.97 (Scheme 21.13) to cany out Mukaiyama-lype nucleophilic additions to carbonyl compounds. " According to Mayr s nucleophilicity scale, silyl enol ethers derived from aldehydes and ketones and, in particular, silyl ketene acetals are even more powerful nucleophilic reagents than the respective allyl silanes. Indeed, the aldol-type addition of trichlorosilyl enol ethers 21.97a-d to aldehydes 21.4 proceeds readily at room temperature without a catalyst exhibiting simple first-order kinetics in each component (Scheme 21.13), which contrasts with the lack of reactivity of allyl silanes in the absence of a catalyst. 

Although the present chapter includes the usual collection of topics designed to acquaint us with a particular class of compounds its central theme is a fundamental reaction type nucleophilic addition to carbonyl groups The principles of nucleophilic addition to aide hydes and ketones developed here will be seen to have broad applicability m later chap ters when transformations of various derivatives of carboxylic acids are discussed... 

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