Wadsworth-Emmons condensation

As latent aldehydes. Dibal-H reduction affords aldehydes for the Emmons-Wadsworth condensation. 

Emmons-Wadsworth condensation. Using chiral phosphonoacetates, the reaction with meso aldehydes and ketones leads mainly to one type of product. 

Emmons-Wadsworth reaction. Conjugate bases of these reagents condense with aldehydes to give dienes with good fEj-selectivity. Diphenyl phosphonates are not suitable because of low yields of their reactions. 

Z)-a,P-Unsaturated esters. The condensation with aldehydes (Emmons-Wadsworth reaction) using these esters is stereoselective. Two convenient preparative methods for the reagents are (1) reaction of (PhO)2P(0)H with bromoacetic esters in dichloromethane, (2) alkoxycarbonylation of (PhO)2P(0)Me with CICOOR. In the latter protoeol, because anions of the methylphosphonate are very unstable, the acylating agents must be present before addition of base to (PhO)2P(0)Me. 

Stobbe condensation. The Emmons-Wadsworth protocol of condensation with an aldehyde is complementary to the classical Stobbe condensation. But here, the product is the diester, which can be hydrolyzed selectively. Thus treatment with CFiCOOH leads to a conjugated ester/saturated acid. 

Emmons-Wadsworth olefination. Condensation with a-ketols leads directly to butenolides (7 examples, 25-70%). 

Muscone (40) is a sex pheromone of the musk deer and a chemical component of cosmetics. A 12-member library of racemic muscone analogs was synthesized by Nicolaou et al.," who anployed a cyclorelease method on solid support to form the macrocycle scaffold (Figure 11.17). A phosphonate-functionalized resin loaded on encoded SMART microreactors 36 was coupled to olelinic esters 35 to form the p-ketophosphonates 37. Sorting and cross olefin metathesis of 37 with two alkenols followed by oxidation with Dess-Martin reagent gave aldehydes 38. An intramolecular ketophosphonate-aldehyde condensation (Homer-Emmons-Wadsworth reaction) of 38 caused smooth cyclorelease of macrocyclic enones 39. Parallel solution-phase chemistry completed the sequence. 

Intramolecular phosphonate-ketone condensation (Homer-Wadsworth-Emmons)... 

Intramolecular condensation of phosphonate carbanions with carbonyl groups carried out under conditions of high dilution have been utilized in macrocycle syntheses. Entries 7 and 8 show macrocyclizations involving the Wadsworth-Emmons reaction. Entries 9 to 11 illustrate the construction of new double bonds in the course of a multistage synthesis. The LiCl/amine conditions are used in Entries 9 and 10. 

A tandem enzymatic aldol-intramolecular Homer-Wadsworth-Emmons reaction has been used in the synthesis of a cyclitol.310 The key steps are illustrated in Scheme 8.33. The phosphonate aldehyde was condensed with dihydroxyacetone phosphate (DHAP) in water with FDP aldolase to give the aldol adduct, which cyclizes with an intramolecular Horner-Wadsworth-Emmons reaction to give the cyclo-pentene product. The one-pot reaction takes place in aqueous solution at slightly acidic (pH 6.1-6.8) conditions. The aqueous Wittig-type reaction has also been investigated in DNA-templated synthesis.311... 

Domino processes involving Homer-Wadsworth-Emmons (HWE) reactions constitute another important approach. Among others, HWE/Michael sequences have been employed by the group of Rapoport for the synthesis of all-cis-substituted pyrrolidines [143], and by Davis and coworkers to access new specific gly-coamidase inhibitors [144]. Likewise, arylnaphthalene lignans, namely justicidin B (2-281) and retrojusticidin B (2-282) [145], have been synthesized utilizing a domino HWE/aldol condensation protocol developed by Harrowven s group (Scheme 2.65) [146]. 

Scheme 8 summarizes the introduction of the missing carbon atoms and the diastereoselective epoxidation of the C /C double bond using a Sharpless asymmetric epoxidation (SAE) of the allylic alcohol 64. The primary alcohol 62 was converted into the aldehyde 63 which served as the starting material for a Horner-Wadsworth-Emmons (HWE) reaction to afford an E-configured tri-substituted double bond. The next steps introduced the sulfone moiety via a Mukaiyama redox condensation and a subsequent sulfide to sulfone oxidation. The sequence toward the allylic alcohol 64 was com-... 

Cyclopropanation, Horner-Wadsworth Emmons Reaction, and Darzens Condensation Although induction in the cyclopropanation of alkenes was reported early, this work was disputed [49]. Other reports of cyclopropanations have yielded, at best, low asymmetric inductions [llh,50]. The first example of a catalytic asymmetric Horner-Wadsworth Emmons reaction, which is promoted by a chiral quaternary ammonium salt, was reported recently by the Shioiri group (Scheme 10.10) [51]. The reaction of the prochiral ketone 74 gives optically active a,P-unsaturated ester 76 with 57% ee. 

The first example of a catalytic asymmetric Horner-Wadsworth-Emmons reaction was recently reported by Arai et al. [78]. It is based on the use of a chiral quaternary ammonium salt as a phase-transfer catalyst, 78, derived from cinchonine. Catalytic amounts (20 mol%) of organocatalyst 78 were initially used in the Homer-Wadsworth-Emmons reaction of ketone 75a with a variety of phospho-nates as a model reaction. The condensation products of type 77 were obtained in widely varying yields (from 15 to 89%) and the enantioselectivity of the product was low to moderate (< 43%). Although yields were usually low for methyl and ethyl phosphonates the best enantioselectivity was observed for these substrates (43 and 38% ee, respectively). In contrast higher yields were obtained with phosphonates with sterically more demanding ester groups, e.g. tert-butyl, but ee values were much lower. An overview of this reaction and the effect of the ester functionality is given in Scheme 13.40. 

Homer-Wadsworth-Emmons reactions are C=C-forming condensation reactions between the Li, Na, or K salt of a /1-koto- or an a-(alkoxycarbonyl )phosphomc acid dialkyl ester and a carbonyl compound (see Figure 4.46). These reactions furnish a,/3-unsaturated ketones or 0 ,/3-unsaturated esters, respectively, as the desired products and a phosphoric acid diester anion as a water-soluble by-product. In general, starting from aldehydes, the desired compounds are produced /ra/ov-selectively or, in the case of alkenes with trisubstituted C=C double bonds, -selectively. 

Condensations between aldehydes and metalated phosphonic acid dialkyl esters other than those mentioned previously are also referred to as Homer-Wadsworth-Emmons reactions. Nevertheless, in these esters, too, the carbanionic center carries a substituent with a pi electron withdrawing group, for example, an alkenyl group, a polyene or a C=N group. The Homer-Wadsworth-Emmons reactions of these reagents are also stereoselective and form the new C=C double bond /ra/ ,v-selectively. 

Pommer et al.146) reported a synthesis of a stereoisomer mixture of JH1 using a Homer-Wadsworth-Emmons olefmation for introducing the double bond at C-2 of 184146). Three Wittig olefinations were applied in the condensation of C4 + C6 + + C5 + C2 synthons 147). The isomers obtained were separated by distillation (Scheme 35). 

Horner-Wadsworth-Emmons procedures are also commonplace in synthetic materials chemistry, recent examples including donor-acceptor substituted molecules with bicyclo-spacers, which require napthalene-, anthracene-, and pyrene-substituted phosphonates, (112), (113) and (114) respectively, well-defined, electroactive PPE/PPV copolymers through the condensation of dialdehydes and bisphosphonate (115), ° and triphenylamine-substituted PPV. ° ... 

Starting from (+)-diethyl tartrate (2), bromobutenolide 18 was obtained in nine steps. Three of the four C=C double bonds were built up using a Wittig reaction (11—>12), an Ando- y Q Horner-Wadsworth-Emmons reaction (13— 15) and (3-elimination (16 18). From (-)-actinol (3) stannane 23 and sulfone 24 were synthesized in 9 and 13 steps, respectively. Their common intermediate, alkyne 22, was synthesized using methoxycarbonylation. Sharpless asymmetric epoxidation and Ci-elongation with lithio trimethylsilyldiazomethane. Stannane 23 was obtained upon hydrostannylation and TBS deprotection. Sulfone 24 was obtained after addition to methyl tetrolate, reduction, Mukaiyama redox condensation, acetylation and catalytic oxidation. 

Phenylalanine-derived oxazolidinone has heen used in O Scheme 52 as a chiral auxiliary for as)rmmetric cross-aldolization (Evans-aldol reactions [277,278,279,280,281,282,283,284, 285]). The 6-deoxy-L-glucose derivative 155 has heen prepared by Crimmins and Long [286] starting with the condensation of acetaldehyde with the chlorotitanium enolate of O-methyl glycolyloxazohdinethione 150. A 5 1 mixture is obtained from which pure 151 is isolated by a single crystallization. After alcohol silylation and subsequent reductive removal of the amide, alcohol 152 is obtained. Swem oxidation of 152 and subsequent Homer-Wadsworth-Emmons olefination provides ene-ester 153. Sharpless asymmetric dihydroxylation provides diol 154 which was then converted into 155 (O Scheme 60) (see also [287]). 

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