Aldehydes addition reactions with organozinc compounds

One of the important new directions in the study of addition reactions of organozinc compounds to aldehydes is the use of ionic liquids. Usually, application of these compounds in reactions with common organometallic reagents has a serious problem ionic solvents are usually reactive toward them, particularly Grignard and organolithium derivatives. It has been recently reported that carbonyl compounds react with allylzinc bromide formed in situ from allyl bromide and zinc in the ionic liquid 3-butyl-l-methylimidazolium tetrafluoroborate, [bmim][BF4].285 Another important finding is that the more reactive ZnEt2 alkylates aldehydes in a number of ionic liquids at room temperature.286 The best yields (up to 96%) were obtained in A-butylpyridinium tetrafluoroborate, [bpy][BF4] (Scheme 107). 

Besides the aldol reaction to form y0-hydroxyketone, 1,3-Dipolar Cycloaddition can also form similar molecules. In addition to the Mukaiyama Aldol Reaction, the following are also similar or closely related to the aldol reaction the Claisen-Schmidt Condensation (the aldol reaction between benzaldehyde and an aliphatic aldehyde or ketone in the presence of relatively strong bases to form an o, )0-unsaturated aldehyde or ketone), the Henry Reaction (base-catalyzed addition of nitroalkane to aldehydes or ketones), the Ivanov Reaction (the addition of enediolates or aryl acetic acid to electrophiles, especially carbonyl compounds), the Knoevenagel Reaction (the condensation of aldehydes or ketones with acidic methylene compounds in the presence of amine or ammonia), the Reformatsky Reaction (the condensation of aldehydes or ketones with organozinc derivatives of of-halo-esters), and the Robinson Annulation Reaction (the condensation of ketone cyclohexanone with methyl vinyl ketone or its equivalent to form bicyclic compounds). 

An interesting feature of the reaction of organozinc compounds is shown in Scheme 4. Reaction of /3-iodozinc derivative 1 with benzoyl chloride in the presence of Pd[P(o-tol)3l4 catalyst gave the iyn-isomer 2, while the anti-isomer 3 was produced by reaction of 1 with benzaldehyde followed by oxidation. The nucleophilic addition to the aldehyde occurs via inversion of the configurations in contrast to the Pd-catalyzed cross-coupling reaction, which proceeds via retention of the configurations. 

Zaitsev reactions also proceed similar to the Reformatsky reactions. Namely, organozinc compounds are synthesized in advance, and subsequently they react with aldehydes or ketones. Therefore, addition to the carbonyl of arylzinc compounds as shown in eq. (5.15) is also known as the Zaitsev reaction. Not only the addition to the carbonyl group of aldehydes or ketones but also the addition to carbon—carbon double bonds are the related reactions of Zaitsev reactions as shown in eq. (5.26) [37]. 

Nucleophilic addition of metal alkyls to carbonyl compounds in the presence of a chiral catalyst has been one of the most extensively explored reactions in asymmetric synthesis. Various chiral amino alcohols as well as diamines with C2 symmetry have been developed as excellent chiral ligands in the enantiose-lective catalytic alkylation of aldehydes with organozincs. Although dialkylzinc compounds are inert to ordinary carbonyl substrates, certain additives can be used to enhance their reactivity. Particularly noteworthy is the finding by Oguni and Omi103 that a small amount of (S)-leucinol catalyzes the reaction of diethylzinc to form (R)-l-phenyl-1 -propanol in 49% ee. This is a case where the... 

Several papers are concerned with the threo-erythro stereoselectivity of the reaction of allylic organozinc reagents with carbonyl compounds. The addition (involving allylic rearrangement) of crotylzinc derivatives to various aldehydes occurs stereoselectively, and the relative amount of tAreo-alcohol increases with increasing steric demand of the group R tert-Bu, S4% f-Pr, 707o n-Bt, 46%) and in the sequence of metals Mg < Zn < Cd 3, 7). The temperature or the polarity of the solvent... 

Organozinc addition reactions to unsaturated systems lead to an intermediate zinc compound which is in most cases further hydrolyzed to give the corresponding protonated organic compound. This intermediate can also be trapped by reaction with electrophiles (see Electrophile) (E+) such as aldehydes, acyl chlorides, organic halides, silyl halides, and so on. Depending on the nature of the electrophile (see... 

Addition to Carbonyl Compounds. (TMSM)2Zn can be used for the preparation of a wide range of mixed organozinc compounds, in which the (trimethylsilyl)methyl (TMSM) moiety acts as a non-transferable group.As a result only a slight excess of the mixed zinc reagent is required in the reaction with aldehydes, a process which affords secondary alcohols in good yields (eq... 

The research on asymmetric organozinc additions to carbonyl compounds started in 1984 when Oguni and Omi obtained 49% e.e. in the reaction of diethylzinc with benzaldehyde catalyzed by (X)-leucinol. Since then, a huge number of chiral (see Chiral) catalysts, mostly derived from amino alcohols, have been developed and the subject has been extensively reviewed. 63.264 jjjg highly enantioselective (see Electrophile) ligand (—)-3-exo-dimethylaminoisobomeol [(-)-DAIB] developed by Noyori and coworkers in 1986 is still used even if its application is mostly limited to aromatic and heteroaromatic aldehydes (equation 62). As shown by previous studies, chiral (see Chiral) ligands have a dual... 

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