Olefination Horner-Wadsworth-Emmon

Related reactions Horner-Wadsworth-Emmons olefination, Horner-Wadsworth-Emmons olefination - Still-Gennari modification,... 

Related reactions Homer-Wadsworth-Emmons olefination, Horner-Wadsworth-Emmons olefination - Still-Gennari modification, Julia-Lithgoe olefination, Peterson olefination, Takai-Utimoto olefination, Tebbe olefination, Wittig reaction - Schlosser modification ... 

HORNER - WADSWORTH - EMMONS Olelination Wittig type reaction of ptwsptionale stabilized carbanions with aldehydes or ketones to form olefins... 

Scheme 21 Higher order Horner-Wadsworth-Emmons olefination via hexacoordinated intermediates 67...

Similarly, starting from 2,3 5,6-di-0-isopropylidene-D-mannofuranose 72, a one-pot procedure that implies the synthesis of glycosyl sulfones by Horner-Wadsworth-Emmons olefination with phosphonate 73, followed by subsequent Michael addition and Ramberg-Backlund reaction92 gives compound 74 in 78% yield93 (Scheme 24). 

In a different approach, Franck-Neumann et al. [24] utilized the manganese complex 14 (formed by deracemization) to obtain the enantiomerically pure target molecule 12 via Horner-Wadsworth-Emmons olefination and oxidative decomplexation of the intermediate vinylallene complex 15 (Scheme 18.6). 

Syntheses follow a kind of bio-mimetic approach [283, 284] in building up the chain during a sequence of Wittig-type reactions or Horner-Wadsworth-Emmons olefination, adding two carbons to the chain at a time with either methyl- or ethyl-branches. As the final products need to be highly pure (E)-stereoisomers, reaction steps and purification need to be carefully controlled. 

Synthesis of a C(8)-C(18) segment of the larger fragment of lb using the same basic strategy is depicted in Scheme 25. Here, hydroxy ketone 176 was subjected to syn-selective (dr of crude product=90 10) reductive amination [42] with sodium cyanoborohydride and benzylamine followed by tetrahydro-oxazine formation using aqueous formaldehyde. The resulting heterocycle 182 was then converted to unsaturated ester 184 by successive desilylation, oxidation, and entirely (Z)-selective Horner-Wadsworth-Emmons olefination. Re-... 

This variation of the Wittig reaction uses ylides prepared from phosphonates.12 The Horner-Wadsworth-Emmons method has several advantages over the use of phosphoranes. These ylides are more reactive than the corresponding phosphoranes, especially when substituted with an electron withdrawing group. In addition the phosphorus product is a phosphate ester and soluble in water - unlike the Ph3PO product of the Wittig reaction - which makes it easy to separate from the olefin product. Phosphonates are also cheaper than phosphonium salts and can easily be prepared by the Arbuzov reaction from phosphanes and halides. 

We have already seen the bishydroxylation using 0s04 and NMO this time lead tetraacetate is used to cleave the diol and yield the aldehyde. The phosphorane (Me0)2P(0)CHN2 is named the Gilbert-Seyferth reagent. 8 It basically behaves like the phosphoranes in the Horner-Wadsworth-Emmons reaction described above, except that the olefin subsequently loses nitrogen, creating the desired triple bond (also see Chapter 10). 

The protected methyl glycoside 3 is converted to the corresponding aldehyde by Swern oxidation using oxalyl chloride activated DMSO. Further reaction with triethyl phosphonoacetate and sodium hydride -known as the Horner-Wadsworth-Emmons reaction - provides selectively the trans et /Tun saturated ester 4 in 72 % yield. This valuable alternative to the Wittig olefination protocol uses phosphonate esters as substrates which are readily available from alkyl halides and trialkyl phosphites via the Arbuzov rearrangement.9 co2Et Reaction of the phosphonate with a suitable base gives the... 

Epimerizable aldehydes clearly undergo intermolecular Horner-Wadsworth-Emmons olefination with trimethyl phosphonoacetate, by using the weak base, lithium hexaflu-oroisopropoxide [LiOCH(CF3)2], as catalyst.203... 

The enoates 17 were obtained in good yield and diastereoselectivity by subjecting the crude hydroformylation products 6 to Horner-Wadsworth-Emmons olefination conditions (HWE). Reaction of enoates 17 with dialkyl Gilman cuprates gave the anti 1,4-addition... 

Fig. 11.19. Still-Gennari olefination of a racemic a-chi-ral aldehyde with an enan-tiomerically pure phosphonate as kinetic resolution I—Loss of the unreactive enantiomer ent-B of the aldehyde (R stands for the phenylmenthyl group in the Horner-Wadsworth-Emmons products the naming of the products in this figure is in agreement with the nomenclature of Figures 11.17 and 11.18).

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... 

Horner-Wadsworth-Emmons reactions are C—C-forming condensation reactions between the Li, Na, or K salt of a /J-keto- or an -(alkoxycarbonyl)phosphonic acid dialkyl ester and a carbonyl compound (cf. Figure 4.41). These reactions furnish a,f)-unsaturated ketones or a j8-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 fraus-selectively or in the case of olefins with trisubstituted C—C double bonds -selectively. 

The stereostructure of the alkoxide intermediate of a Horner-Wadsworth-Emmons reaction which finally leads to the trans-o cim was recorded in Figure 9.14 (as formula A). The Still-Gennari variant of this reaction (Figure 9.15) must proceed via an alkoxide with the inverse stereostructure because an olefin with the opposite configuration is produced. According to Figure 9.16, this alkoxide is a 50 50 mixture of the enantiomers C and ent-C. Each of these enantiomers contributes equally to the formation of the finally obtained cw-configured acrylic ester D. 

Fig. 11.28. Aldehyde alkyne chain elongation via [1 -rearrangement of a vinyl carbene (Seyferth procedure). First, a Horner-Wadsworth-Emmons olefination of the aldehyde is carried out to prepare alkene A. Upon warming to room temperature, alkene A decomposes and gives the vinyl carbene B. From that, the alkyne is formed by way of a [1,2]-rearrangement.

Ketones are rarely used as electrophiles in the enantioselective aldolization while they find application to enantioselective olefination reactions such as the Horner-Wadsworth-Emmons or the Peterson reaction. For instance, the deprotonation of an achiral phos-phonoacetate by a set of chiral 2-aminoalkoxides led to the corresponding enolate that... 

All the carbons of the target were introduced by a Horner-Wadsworth-Emmons reaction of ent-427 with a-ethylacrolein, which gave a mixture of ( ) and (Z) olefins 437. The synthesis of the E) isomer of 437 constitutes a formal synthesis of coronafacic acid because its conversion to the natural product has been reported by Nara, Toshima, and Ichihara [90]. They reported that 437-E could be cyclized with base to hydrindenones 438 and 439 in 71 % yield. After purification, the major diastereomer 438 could be hydrolyzed to coronafacic acid in 95 % yield. 

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