Aldehydes 1 - vinyllithium

Vinyllithium [917-57-7] can be formed direcdy from vinyl chloride by means of a lithium [7439-93-2] dispersion containing 2 wt % sodium [7440-23-5] at 0—10°C. This compound is a reactive intermediate for the formation of vinyl alcohols from aldehydes, vinyl ketones from organic acids, vinyl sulfides from disulfides, and monosubstituted alkenes from organic halides. It can also be converted to vinylcopper [37616-22-1] or divinylcopper lithium [22903-99-7], which can then be used to introduce a vinyl group stereoselectively into a variety of a, P-unsaturated systems (26), or simply add a vinyl group to other a, P-unsaturated compounds to give y, 5-unsaturated compounds. Vinyllithium reagents can also be converted to secondary alcohols with trialkylb o r ane s. 

Removal of the carbonate ring from 7 (Scheme 1) and further functional group manipulations lead to allylic alcohol 8 which can be dissected, as shown, via a retro-Shapiro reaction to give vinyl-lithium 9 and aldehyde 10 as precursors. Vinyllithium 9 can be derived from sulfonyl hydrazone 11, which in turn can be traced back to unsaturated compounds 13 and 14 via a retro-Diels-Alder reaction. In keeping with the Diels-Alder theme, the cyclohexene aldehyde 10 can be traced to compounds 16 and 17 via sequential retrosynthetic manipulations which defined compounds 12 and 15 as possible key intermediates. In both Diels-Alder reactions, the regiochemical outcome is important, and special considerations had to be taken into account for the desired outcome to. prevail. These and other regio- and stereochemical issues will be discussed in more detail in the following section. 

A simple two-step protocol for the generation of a terminal diene is to add allyl magnesium bromide to an aldehyde or a ketone and subsequent acid or base catalysed dehydration (equation 34)72. Cheng and coworkers used this sequence for the synthesis of some indole natural products (equation 35)72a. Regiospecific dienones can be prepared by 1,2-addition of vinyllithium to a,/l-unsaturated carbonyl compounds and oxidative rearrangement of the resulting dienols with pyridinium dichromate (equation 36)73. 

These electrophilic conjunctive reagents require donor reactants. The cyclopropyl-carbinols as precursors to cyclobutanones arise by simple addition of organometallics. For example, the cyclobutanone 47 derives by addition of vinyllithium to 44 followed by rearrangement with aqueous fluoroboric acid 92). In some cases, this route to cyclopropylcarbinols is preferred. Addition of 41 to aldehydes or ketones... 

When methylene bisphosphonate (169) is reacted in a Horner reaction with an aromatic aldehyde, the alkenyl phosphonate 170 is produced (Scheme 5.25). By metalation with LDA in THF, this is converted to the vinyllithium intermediate 171 that, with the ketone 172, affords a Baylis-Hillman reaction-type product, 173 on base treatment, this is converted to the arylallene 174 [67]. 

The /S-bromodihydropyran (652) on halogen-metal exchange with f-butyllithium affords a useful organometallic (653) that can function as the equivalent of a 5-hydroxy aldehyde enolate (Scheme 151) (79TL67). The vinyllithium species adds to ketones and aldehydes at -110 °C in good yield and also reacts in a conjugate mode with a,/S-unsaturated carbonyl compounds in the presence of copper(I) ions. On hydrolysis and oxidation, the dihydropyran component (654) can be transformed into a substituted 5-lactone (655). 

Dienes and trienes.2 Alkyl- or vinyllithium reagents react with 1 to form a 1,2-adduct (a) that rearranges to a (2Z,4E)-5-substituted pentadienal (2) in 50-65% yield. The aldehyde can be used for a Wittig reaction or allowed to react with... 

Since an excess of n-BuLi has been inevitable, iron-ate complexes were proposed as catalytic relevant species, which generate a vinyllithium intermediate by carbometallation. The latter was verified by a quench with aldehydes and ketones with generation of the corresponding allylic alcohol. It is important to note that these reactions took place in low yields with alkyl-Grignard reagents. 

Alkenes can also be obtained by reaction of the silylated p-tosylhydrazone of saturated aldehydes with a vinyllithium. Of further interest, no epimerization occurs at centers adjacent to the aldehyde group. The (E)-configuration is favored in the case of both di- and trisubstituted alkenes. 

On the other hand, the pure (Z)-isomer of 1 on treatment with sec-butyllithium in THF generates the more susbstituted vinyllithium reagent 3. Thus by use of either sequence stereoselective routes are possible to alkenes, allylic aldbhols, and aldehydes. ... 

A novel class of chiral indenes (verbindenes) was prepared from enantiopure verbenone by K.C. Rupert and coworkers who utilized the Shapiro reaction and the Nazarov cyciization as the key transformations. The bicyclic ketone substrate was treated with triisopropylbenzenesulfonyl hydrazide to prepare the trisyl hydrazone that was then exposed to n-BuLi. The resulting vinyllithium intermediate was reacted with various aromatic aldehydes to afford the corresponding allylic alcohols. 

When the vinyllithium intermediate (190) is treated with water, the procedure provides a useful synthetic method for the conversion of ketones to alkenes (Scheme 79). The method is illustrated by the conversions of the tosylhydrazones of phenyl isopropyl ketone (194) and dipropyl ketone (195) to the alkenes (196) and (197), respectively (Scheme 79). In this method, experiments have demonstrated that the hydrogen is derived from the water, as indicated in Scheme 79, and thatTMEDA is an excellent solvent. The vinyllithium intermediate (190) may be trapped by other electrophiles thus, with carbon dioxide and DMF, the reaction affords ,[i-unsaturated carboxylic acids and aldehydes like (198) and (199) (Scheme 80). 

The tin-lithium exchange methodology for access to vinyllithium derivatives has been used for syntliesis of C s-symmetric hydropyran cyclooligolides (Scheme 12.44) [113]. In this process, an aldehyde derived from readily available ethyl (S)-lactate was treated with cuprate which had been prepared by addition of organolithium and Cul to vinylstannanes, and various types of building block were successfully constructed. 

Some typical reactions of 1,1 -difluoroethene with nucleophiles are summarized in Scheme 2.18. Alkoxides [3], trialkylsilyl anion [4], ester enolates [5], and diphenylphosphinyl anion [6] attack the gem-difluorinated carbon of 5. However, it is noteworthy that nucleophilic substitution and proton abstraction are in some cases competitive, and thus s -butyl lithium abstracts the (3 -vinylic proton predominantly to generate vinyllithium. The lithium species can be trapped with an aldehyde, providing difluoroallyl alcohol, which is then hydrolyzed to a, (3-unsaturated carboxylic ester (11) [ 7 ] (Scheme 2.19). Some synthetically useful examples are shown in Schemes 2.20 and 2.21. Tetrathiafulvalene derivative (14) is prepared from difluorinated derivative (13) [8]. An elegant intramolecular version was demonstrated by Ichikawa, which provided a range of cyclized compounds (17), including dihydrofurans, thiophenes, pyrroles, and cyclopentenes, and also corresponding benzo derivatives (20) [2]. 

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