Alkenes Wittig-Horner reaction

The nucleophilic addition of the a-lithiated alkyldiphenylphosphine oxide B to the carbonyl group of an aldehyde at the beginning of a Wittig-Horner reaction results in the phos-phorylated lithium alkoxide D. If the alkene synthesis is carried out in a single step, the Li of the intermediate D is, without workup, reversibly replaced by K by adding potassium-ferf-butoxide. In this way, the phosphorylated potassium alkoxide F is made available. Only in F... 

Another variation of the Wittig reaction is the Wittig-Horner reaction, in which the anion generated ot- to phosphine oxide is used as a nucleophile to react with carbonyl compounds. The intermediate formed in this reaction, -hydroxyphosphine oxide, is isolable particularly when bases with lithium counterion are used for deprotonation. Since the j6-hydroxyphosphine oxides are diastereomers, they can be separated and subjected to elimination to form the corresponding alkenes. Since the elimination of phosphonate moiety is syn, stereospecific alkenes are obtained from the elimination step. As expected, the generation of erythro and threo isomers is dependent on the solvent and the reaction conditions. 

PTC is a method of choice for the Wittig-Horner reaction of carbanions derived from esters of alkanephosphonic acids, activated with additional car-banion stabilizing groups, with aldehydes and ketones.. E-Alkenes are usually formed as the main products in good yields. Solid-liquid system KOH/benzene with 18-crown-6 as the catalyst is recommended for these processes however, K2C03/H20/dioxane or 50% NaOH aq was also used. Although the yields are sometimes low, because of the simplicity of the procedure, it can be favorably compared with other base/solvent systems used for this reaction (eqs. 72 and 73). 

In the Peterson reaction of an a-silyl carbanion bearing a phosphorus substituent on the anionic carbon atom, there are two possibilities for alkene formation, that is, the Peterson reaction to form phosphorus-substituted alkenes and the Wittig-Horner reaction and the Wadsworth-Emmons reaction to form silicon-substituted alkenes. Most of the reports on these competing reactions have been focused on the reactions of a-silyl phosphonates with carbonyl compounds. It is noteworthy that the alkenylphosphonates have been exclusively obtained in almost every case. That is, the Peterson reactions override the Wittig and Wadsworth-Emmons reactions. 

On the other hand, high Z-selectivity is seen in the olefination reactions of the carbanion 19 derived from 3,3-diethoxybutylphosphonate with aldehydes (Scheme 2.16) [41, 42]. Similarly, Z-selective Peterson reactions of the in situ generated a-phosphoryl-a-(trimethylsilyl)allyl anion 104 with aldehydes or alkyl formates to afford the 2-dienylphosphonates 105 have been reported (Scheme 2.63) [168, 169]. These methods allow access to (Z)-alkenylphosphonates, whereas Wittig-Horner reactions give the thermodynamic ( )-alkenes almost exclusively. These excellent Z-selectivities can be rationalized in terms of the chelation control mechanism (see Section 2.2.2.3). 

The Wittig-Horner (W-H) reaction is a versatile method for the synthesis of functionalized alkenes. The synthesis of 3-substituted ethyl acrylates and acrylonitriles, which are used as monomers in polymerization, were successfully carried out by the reaction of triethyl phosphonoacetate or cyanomethanephosphonate, respectively, with various aldehydes with activated Ba(OH)2 as the catalyst in the presence of dioxane solvent at 343 K (294). As was observed for other basic solid... 

Other commonly used synthetic routes to alkenes are also affected by crown ethers. The Wittig (80TL4831), Wittig-Horner and Wadsworth-Emmons (81S117) reactions all give pure trans- alkene products in higher yields in the presence of crown ethers. 

Fig. 11.10. Wittig-Horner synthesis of alkenes with stereogenic C=C double bond via condensation of lithiated phosphine oxides B <-> B with aldehydes. In the two-step reaction the initially formed addition products syn- and anti-D are protonated and the resulting alcohols syn- and anti-C are isolated and separated the suitable diastere-omer is then stereoselectively converted into the desired alkene isomer. The one-step reaction leads to the same alkene in a cis,trans mixture.

Fig. 11.11. Wittig-Horner synthesis of stereouniform alkenes via ketophosphine oxide B. The reaction proceeds via its Felkin-Anh-selective or chelate-controlled reduction to form the syn-configured hydroxyphosphine oxides D and the anti-configured hydroxyphosphine oxides E. D and E continue to react—after deprotonation with KO-tert-Bu—via a syn-elimination to give the trans- and cis-alkene, respectively. R1 in the formula A-C corresponds to a primary (prim-alkyl) or a secondary alkyl residue (sec-altyl).

Standard Wittig/Horner-Wadsworth-Emmons reaction conditions (Table 8, entries 25, 26) [477] The method presented here yields predominantly (E)-alkenes. 

The other half was made from 172 by formation of the protected keto-aldehyde 183 followed by successive stereoselective Wittig-Horner and Wittig reactions to put in the two alkenes with control over stereochemistry. The Wittig-Horner is under thermodynamic control giving the trisubstituted E-alkene 185 while the Wittig is under kinetic control giving the Z-iodoalkene 175 R = Ac (chapter 15). 

A.iu. Phosphine Oxides and Phosphonate Esters. Many extensions of the Wittig reaction have been introduced that improve or modify the reactivity and/or stereoselectivity of the ylid. Horner et al. showed that a-lithiophosphine oxides such as that derived from 552 react with aldehydes or ketones to give a p-hydroxy phosphine oxide (553) as an isolable species. Subsequent treatment with base liberates the alkene, (554). Wadsworth and Emmons modified the Horner reaction to use phosphonate ester derivatives such as... 

The Wittig-Horner olefination of the aldehyde 28 provided alkenes 29 which were subjected to radical cyclization leading to benzofused tricyclic j6-lactams 30, obtained as single diastereomers (Scheme 8) [36]. A convenient, direct regio- and stereoselective route to optically pure unusually fused or bridged tricyclic /3-lactams has been developed by the use of intramolecular nitrone-alkene cycloaddition reactions. For example, the aldehyde 21 can be transformed into nitrone 31 which subsequently was used for a variety... 

The Wittig reaction wherein a phosphonate is substituted for the more traditional phosphonium salt is called either the Wittig-Horner [8] or Wittig-Emmons [9] reaction. The synthesis of alkenes via base catalyzed phosphonate addition to an aldehyde or ketone has been accomplished under phase transfer conditions [10—13]. 

Wittig reactions (Equation 3) in non-polar media can be initiated by solid-liquid phase transfer of potassium carbonate or t-butoxide with 18-crown-6. Typical salt-free product distributions (Z-disubstituted alkene predominant) are observed with non-stabilized ylidcs in THF, but they are surprisingly reversed in dichloro-methane solution. -Alkenes usually predominate in both solvents when stabilized ylides are involved. Two-phase Wittig-Horner syntheses of ajS-unsaturated sulphides etc. (Equation 5) are also crown-catalysed, as is the Darzens-type process (Equation 14). ... 

The (Horner-)Wadsworth-Emmons reaction generally is superior to the Wittig reaction, and has found application in many cases for the synthesis of a ,/3-unsaturated esters, a ,/3-unsaturated ketones and other conjugated systems. Yields are often better then with the original Wittig procedure. However the Wadsworth-Emmons method is not suitable for the preparation of alkenes with simple, non-stabilizing alkyl substituents. 

Carbanions derived from phosphine oxides also add to carbonyl compounds. The adducts are stable but undergo elimination to form alkene on heating with a base such as sodium hydride. This reaction is known as the Horner-Wittig reaction.268... 

The unique feature of the Horner-Wittig reaction is that the addition intermediate can be isolated and purified, which provides a means for control of the reaction s stereochemistry. It is possible to separate the two diastereomeric adducts in order to prepare the pure alkenes. The elimination process is syn, so the stereochemistry of the alkene that is formed depends on the stereochemistry of the adduct. Usually the anti adduct is the major product, so it is the Z-alkene that is favored. The syn adduct is most easily obtained by reduction of (3-ketophosphine oxides.269... 

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