Organolithium compounds carbonyl compound reactions

CARBONYL ADDITIONS, CERIUM(III) CHLORIDE-PROMOTED, 76, 237 Carbonyl compounds, reactions with organolithiums or Grignard reagents, 76, 228 Carboxylic acid amides, 77, 27 Cells, storage of, 76, 80 Centrifugation, 76, 78... 

With organolithium compounds, their substitution reactions proceed without affecting the carbonyl groups as shown in eq. (3.14), and in this regard they are different from Grignard reactions [34]. 

The reactions of organolithium compounds with carbonyl compounds, including carbon dioxide, may be interpreted as follows ... 

Alkyltriphenylphosphonium halides are only weakly acidic, and a strong base must be used for deprotonation. Possibilities include organolithium reagents, the anion of dimethyl sulfoxide, and amide ion or substituted amide anions, such as LDA or NaHMDS. The ylides are not normally isolated, so the reaction is carried out either with the carbonyl compound present or with it added immediately after ylide formation. Ylides with nonpolar substituents, e.g., R = H, alkyl, aryl, are quite reactive toward both ketones and aldehydes. Ylides having an a-EWG substituent, such as alkoxycarbonyl or acyl, are less reactive and are called stabilized ylides. 

The most important reactions of Grignard reagents and organolithium compounds are the nucleophilic attack to the carbonyl group. 

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). 

The chemical behavior of heteroatom-substituted vinylcarbene complexes is similar to that of a,(3-unsaturated carbonyl compounds (Figure 2.17) [206]. It is possible to perform Michael additions [217,230], 1,4-addition of cuprates [151], additions of nucleophilic radicals [231], 1,3-dipolar cycloadditions [232,233], inter-[234-241] or intramolecular [220,242] Diels-Alder reactions, as well as Simmons-Smith- [243], sulfur ylide- [244] or diazomethane-mediated [151] cyclopropanati-ons of the vinylcarbene C-C double bond. The treatment of arylcarbene complexes with organolithium reagents ean lead via conjugate addition to substituted 1,4-cyclohexadien-6-ylidene complexes [245]. 

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. 

The reaction shown in Scheme 39 was also performed starting from a chiral carbamoyl chloride (91, Y = O) derived from (f )-iV-methyl-iV-(l-phenylethyl)amine, in order to study the possible asymmetric induction using prochiral carbonyl compounds. Thus, with pivalaldehyde or benzaldehyde the mixture of diastereomers obtained was ca 1 1. This behavior was also observed with other chiral functionalized organolithium compounds ". ... 

The only way to introduce two different electrophilic fragments in compounds such as 508 is to have a starting material with different halogens. This is the case with 510, which could be lithiated (bromide-lithium exchange) with t-butyllithium in THF at — 100°C giving intermediates 511, which reacted with a carbonyl compound R R CO and, after naphthalene-catalyzed lithiation, gave the new functionalized organolithium intermediate 512. Final reaction with 3-pentanone followed by hydrolysis yielded mixed products 513 (Scheme 142) °. 

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