Wittig reaction formation

Wittig reaction Formation of carbon-carbon double bonds from carbonyl compounds and phosphorous ylides. 486... 

After the isolation of the aigialomycins in 2002 (344), only two years later Danishefsky and co-workers published the first total synthesis of aigialomycin D (482) (5S5). Their synthesis strategy is denoted by a late-state aromatization via Diels-Alder cycUzation. Starting with readily available D-2-deoxyribose (568), alcohol 569 was obtained by protection of the diol, subsequent Wittig reaction, formation of the pivaloyl ether, and concluding hydroboration with oxidative workup (Scheme 9.14). Oxidation of the primary alcohol to aldehyde with a subsequent proparylation, led, after protection and deprotection, to alkyne 570. 

Note Let us see how this stereochemical outcome is controlled. Depending on the stability of phosphonium ylide in the Wittig reaction, formation of an or Z isomer... 

Wittig reaction Formation of an alkene by reaction of a carbonyl compound with a phosphorus ylide. 

The sample solution to Problem 17 16(a) showed the prepara tion of 3 methyl 3 heptene by a Wittig reaction involving the ylide shown Write equations showing the formation of this ylide beginning with 2 bromobutane... 

The Wittig reaction (Sections 17 12-17 13) Reaction of a phosphorus ylide with aldehydes and ketones leads to the formation of an alkene A versa tile method for the regiospecific prepa ration of alkenes... 

The reaction has been extended to include carbanions generated from phosphonates. This is often referred to as the Horner-Wittig or Homer-Emmons reaction. The Horner-Emmons reaction has a number of advantages over the conventional Wittig reaction. It occurs with a wider variety of aldehydes and ketones under relatively mild conditions as a result of the higher nucleophilicity of the phosphonate carbanions. The separation of the olefinic product is easier due to the aqueous solubility of the phosphate by-product, and the phosphonates are readily available from the Arbusov reaction. Furthermore, although the reaction itself is not stereospecific, the majority favor the formation of the trans olefin and many produce the trans isomer as the sole product. 

Fluorotnhalomethanes react with two equivalents of tnphenylphosphme or a tnalkylphosphine to form a fluonnated phosphoraniumsalt [5i] (equation 49). The formation of the phosphoranium salts depends upon the solvent system These salts may in turn be used for Wittig reactions [52, 5J] (equation 50) (Table 20). 

The Peterson olefination can be viewed as a silicon variant of the Wittig reaction, the well-known method for the formation of carbon-carbon double bonds. A ketone or aldehyde 1 can react with an a-silyl organometallic compound 2—e.g. with M = Li or Mg—to yield an alkene 3. 

Retrosynthetic cleavage of the trans A8,9 disubstituted double bond in intermediate 11, the projected precursor of diketone 10, provides phosphorus ylide 12 and aldehyde 13 as potential precursors. In the forward sense, a Wittig reaction could conceivably achieve a convergent coupling of intermediates 12 and 13 with concomitant formation of the requisite trans C8-C9 olefin. Ordinarily, the union of a nonstabilized ylide, such as 12, with an aldehyde would be expected to afford an alkene with a cis geometry.8 Fortunately, however, the Schlosser modification of the Wittig reaction permits the construction of trans olefins from aldehydes and nonstabilized phosphorus ylides.9... 

Triphenylphosphine gives Michael additions to the activated triple bond of acetylene dicarboxylic esters in presence of acidic compounds HY (Scheme 1). The reactions take place easily at room temperature, even at -10°C [1], through formation of intermediate activated vinylic phosphonium salts, which undergo a subsequent Michael addition of HY. The reactions afford various stabilized ylides which can be isolated in high yields or undergo possibly evolution, for example by intramolecular Wittig reaction [2]. 

With a-monosubstituted ylides the oxidation results in the formation of alkenes (by subsequent Wittig reaction on the intermediate aldehyde). A recent example of such synthesis is found in the preparation of all-(Z)-cyclododecate-traene by oxidation of the appropriate bis-ylide [33]. It must be pointed out that an approach of the same macrocycle based on ring closing metathesis was found ineffective. 

The intramolecular approach of Staab and Graf, shown in Scheme 4, precluded formation of 5, but was considerably more involved [12]. The cyclic dienyne 6 was afforded by Wittig reaction of o-phthaldialdehyde with the corresponding bis(ylide) derived from tolane. Bromination of 6 and subsequent treat-... 

Quebrachitol was converted into iL-c/j/roinositol (105). Exhaustive O-isopropylidenation of 105 with 2,2-dimethoxypropane, selective removal of the 3,4-0-protective group, and preferential 3-0-benzylation gave compound 106. Oxidation of 106 with dimethyl sulfoxide-oxalyl chloride provided the inosose 107. Wittig reaction of 107 with methyl(triphenyl)phos-phonium bromide and butyllithium, and subsequent hydroboration and oxidation furnished compound 108. A series of reactions, namely, protection of the primary hydroxyl group, 0-debenzylation, formation of A-methyl dithiocarbonate, deoxygenation with tributyltin hydride, and removal of the protective groups, converted 108 into 7. 

Wittig reactions are versatile and useful for preparing alkenes, under mild conditions, where the position of the double bond is known unambiguously. The reaction involves the facile formation of a phosphonium salt from an alkyl halide and a phosphine. In the presence of base this loses HX to form an ylide (Scheme 1.15). This highly polar ylide reacts with a carbonyl compound to give an alkene and a stoichiometric amount of a phosphine oxide, usually triphenylphosphine oxide. 

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