Stabilized carbanions with carbonyl compounds

The formation of /3-hydroxyselenides through the reaction of a selenium-stabilized carbanion with carbonyl compounds has been extensively used also in the context of natural product synthesis. The phenylselenoalkyllithium compound 115 was reacted with aldehyde 116 to afford /3-hydroxyselenide 117. In a radical cyclization cascade the tricyclic molecule 118 was generated in good yields and subsequent transformations led to the synthesis of pentalenene 119 (Scheme 28).1 9 Also other natural products like zizaene and khusimone have been synthesized via a similar route.200... 

Reaction of stabilized carbanions with carbonyl compounds Aldol condensation... 

Trialkylsilyl groups have a modest stabilizing effect on adjacent carbanions (see Part A, Section 3.4.2). Reaction of the carbanions with carbonyl compounds gives (3-hydroxyalkylsilanes. (3-Hydroxyalkylsilanes are converted to alkenes by either acid or base.270 These eliminations provide the basis for a synthesis of alkenes. The reaction is sometimes called the Peterson reaction.211 For example, the Grignard reagent derived from chloromethyltrimethylsilane adds to an aldehyde or ketone and the intermediate can be converted to a terminal alkene by acid or base.272... 

An important complement to the Wittig reaction is the reaction of phosphonate carbanions with carbonyl compounds.151 The alkylphosphonate esters are made by the reaction of an alkyl halide, preferably primary, with a phosphite ester. Phosphonate carbanions are more nucleophilic than an analogous ylide, and even when R is a carbanion-stabilizing substituent, they react readily with aldehydes and ketones to give alkenes. Phosphonate carbanions are generated by treating alkylphosphonate esters with bases such as sodium hydride, w-butyllithium, or sodium ethoxide. Alumina coated with KF or KOH has also found use as the base.152... 

Review. Bergbreiter and Killough have discussed the various uses of CsK, particularly in comparison with the reactions of the soluble analog sodium naphthalenide. Perhaps the most useful role of CsK is for the rapid formation of alkoxides from alcohols and of stabilized carbanions from carbonyl compounds. In these two reactions, it reacts more readily than potassium itself and can be separated from the products by filtration. The authors conclude that it has only limited value for reduction of alkyl and aryl halides and sulfonates, reactions accomplished more readily by other reagents. They also note that CeK can be regarded as a suitable reagent for reactions in which sodium naphthalenide is useful. 

The decarboxylation reaction usually proceeds from the dissociated form of a carboxyl group. As a result, the primary reaction intermediate is more or less a carbanion-like species. In one case, the carbanion is stabilized by the adjacent carbonyl group to form an enolate intermediate as seen in the case of decarboxylation of malonic acid and tropic acid derivatives. In the other case, the anion is stabilized by the aid of the thiazolium ring of TPP. This is the case of transketolases. The formation of carbanion equivalents is essentially important in the synthetic chemistry no matter what methods one takes, i.e., enzymatic or ordinary chemical. They undergo C—C bond-forming reactions with carbonyl compounds as well as a number of reactions with electrophiles, such as protonation, Michael-type addition, substitution with pyrophosphate and halides and so on. In this context,... 

The addition reaction of enolates and enols with carbonyl compounds is of broad scope and of great synthetic importance. Essentially all of the stabilized carbanions mentioned in Section 1.1 are capable of adding to carbonyl groups, in what is known as the generalized aldol reaction. Enolates of aldehydes, ketones, esters, and amides, the carbanions of nitriles and nitro compounds, as well as phosphoms- and sulfur-stabilized carbanions and ylides undergo this reaction. In the next section we emphasize the fundamental regiochemical and stereochemical aspects of the reactions of ketones and aldehydes. 

Current results indicate that stabilized arsonium ylides such as phenacylide, carbomethoxymethylide, cyanomethylide, fluorenylide, and cyclopentadienylide afford only olefinic products upon reaction with carbonyl compounds. Nonstabilized ylides such as ethylide afford almost exclusively epoxides or rearranged products thereof. However, semi-stabilized arsonium ylides, such as the benzylides, afford approximately equimolar amounts of olefin and epoxide. Obviously, the nature of the carbanion moiety of the arsonium ylide greatly affects the course of the reaction. It is reasonable to suppose that a two-step mechanism is involved in the reaction of heteronium (P, S, and As) ylides with carbonyl compounds (56). 

Fig. 6.40. On the chemo-selectivity of the reactions of hydride donors, organometallic compounds, and heteroatom-stabilized "carbanions with acylating agents (kM t refers to the rate constant of the addition of the nucleophile to the carboxyl carbon, and kadd2 refers to the rate constant of the addition of the nucleophile to the carbonyl carbon).

For the reaction of hydride donors, organometallic compounds and heteroatom-stabilized carbanions with acylating agents or carbonyl compounds one encounters a universal reactivity order RC(=0)C1 > RC(=0)H > R2C=0 > RC(=0)0R > RC C NR It applies to both good and poor nucleophiles, but—in agreement with the reactivity/selectivity principle (Section 1.7.4)—the reactivity differences are far larger for poor nucleophiles. 

At this point it should be noted, that olefination involving reaction of PO-stabilized carbanions like those from phosphonates, phosphinates, phosphine oxides, phos-phonamides or thiophosphonates (Horner reaction 47), Horner-Wadsworth-Emmons reaction48 ) with carbonyl compounds almost exclusively yields ( )-olefins. This olefination is essentially restricted to PO-activated compounds carrying stabilizing groups on the carbanionic C-atom. However, these compounds are more reactive than the corresponding resonance-stabilized ylides. Therefore, this olefination method... 

Alternatives to the standard Wittig reaction have been developed, including the Homer-Wadsworth-Emmons (HWE) reaction which involves the reaction of a phosphonate stabilized carbanion with a carbonyl compound (Scheme 2). These carbanions are generally more reactive than the traditional phosphoranes and they will often react with ketones that are unreactive to stabilized phosphoranes.2 3,8... 

Phosphoranes and phosphonate derived carbanions are also known to react with carbonyl compounds other than aldehydes and ketones, in reactions often referred to as non-classical Wittig reactions.35 Wittig olefination products can be obtained from the reaction of esters, anhydrides and some amides and imides with a range of stabilized and reactive phosphoranes. The reaction of stabilized and semi-stabilized phosphoranes with esters gives alkenes (Scheme 7). However, non-stabilized phosphoranes, such as methylenetriphenylphosphorane, tend to give P-keto phosphoranes on reaction with esters (Scheme 7)—the careful choice of the reaction conditions can also permit the preparation of the alkene in these reactions. 

The formation of -hydroxy selenides through reaction of a selenium-stabilized carbanion with a carbonyl compound has been extensively used, in particular for the synthesis of natural products [1 - 4, 33]. The most recent... 

The preparation and use of silicon-stabilized carbanions is well documented the vast majority of reports are concerned with the reaction of these reagents with carbonyl compounds to form alkenes. 

The chemistry of carbanions stabilized by the heavy main group elements has been extensively investigated by Kauffmann, and a thorough description of his work can be found in a recent review. There are many similarities between the elements. The anions stabilized by the heavy main group elements listed above can generally be alkylated, and in some cases their reaction with carbonyl compounds is a useful alternative to the Wittig reaction. All the stabilized metallomethyl lithium anions (except bismuth) exhibit marked thermal stability. 

Alkylthiazoles are CH-acidic compounds. They are deprotonated by bases on the or-C-atom of the alkyl group [97]. The resulting carbanions, stabilized by conjugation, react, for example, with carbonyl compounds to form alcohols ... 

A very useful modification of the Wittig reaction involves the reaction of phosphonate-stabilized carbanions with aldehydes or ketones, which is known as the Homer-Wadsworth-Emmons (HWE) reaction [7, 151,152], This reaction was originally described by Homer et al. [153, 154] and further defined by Wadsworth and Emmons [155]. Phosphonate-stabilized carbanions are more nucleophilic and more basic than phosphonium ylides. They are prepared by the addition of suitable bases to the corresponding alkylphosphonates, which are readily accessible through the Michaelis-Arbuzov reaction of trialkyl phosphites with alkyl halides (usually a-halo carbonyl compounds) [143]. In contrast to the Wittig reaction, the HWE reaction yields phosphate salt byproducts that are water-soluble and hence are readily separated from the desired alkene products by simple extraction. 

Various [l- C]carboxylic acids have been prepared by carboxylation of carbanions stabilized by -I or -M substituents. The examples in Figure 5.7 have been selected here as prototypes, since they are of strategic interest. Deprotonation of diethyl methylphos-phonate (18 with n-BuLi followed by [ CJcarboxylation and esterification with diazoethane provided triethyl phosphonoll- Clacetate (19) in an overall radiochemical yield of 62%. Compound 19 has been widely exploited for chain extensions by a labeled two-carbon unit via its alkenylation reaction with carbonyl compounds (Homer-Wadsworth-Emmons reaction). Similarly, reaction of alkyl halides, tosylates or carbonyl compounds with LiC = CH or LiC=CH H2NCH2CH2NH2 followed by deprotonation and [ C]carboxylation of the resulting terminal alkynes has been used as a strategic tool for the incorporation of a labeled three-carbon unit, as exemphfied in a steroid platform (20 to 21). This chemistry provides outcomes complementary to those using [ C2]acetylene (Chapter 8, Section 5.1). Finally, the [ CJcarboxylation of lithiated dimethylsulfide provided an alkylthio[l- C]acetic acid 22 and thence a functionalized 2-alkylthio[l- C]ethyl derivative 23 useful, in this case, for elaboration into e.p. 

The Julia olefination involves the addition of a sulfonyl-stabilized carbanion to a carbonyl compound, followed by elimination to form an alkene.277 In the initial versions of the reaction, the elimination was done under reductive conditions. More recently, a modified version that avoids this step was developed. The former version is sometimes referred to as the Julia-Lythgoe olefination, whereas the latter is called the Julia-Kocienski olefination. In the reductive variant, the adduct is usually acylated and then treated with a reducing agent, such as sodium amalgam or samarium diiodide.278... 

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