Alkoxides Michael addition

In the above reaction one molecular proportion of sodium ethoxide is employed this is Michael s original method for conducting the reaction, which is reversible and particularly so under these conditions, and in certain circumstances may lead to apparently abnormal results. With smaller amounts of sodium alkoxide (1/5 mol or so the so-called catal3rtic method) or in the presence of secondary amines, the equilibrium is usually more on the side of the adduct, and good yields of adducts are frequently obtained. An example of the Michael addition of the latter type is to be found in the formation of ethyl propane-1 1 3 3 tetracarboxylate (II) from formaldehyde and ethyl malonate in the presence of diethylamine. Ethyl methylene-malonate (I) is formed intermediately by the simple Knoevenagel reaction and this Is followed by the Michael addition. Acid hydrolysis of (II) gives glutaric acid (III). 

The TT-allylpalladium complexes 241 formed from the ally carbonates 240 bearing an anion-stabilizing EWG are converted into the Pd complexes of TMM (trimethylenemethane) as reactive, dipolar intermediates 242 by intramolecular deprotonation with the alkoxide anion, and undergo [3 + 2] cycloaddition to give five-membered ring compounds 244 by Michael addition to an electron-deficient double bond and subsequent intramolecular allylation of the generated carbanion 243. This cycloaddition proceeds under neutral conditions, yielding the functionalized methylenecyclopentanes 244[148], The syn-... 

Purines, N-alkyl-N-phenyl-synthesis, 5, 576 Purines, alkylthio-hydrolysis, 5, 560 Mannich reaction, 5, 536 Michael addition reactions, 5, 536 Purines, S-alkylthio-hydrolysis, 5, 560 Purines, amino-alkylation, 5, 530, 551 IR spectra, 5, 518 reactions, 5, 551-553 with diazonium ions, 5, 538 reduction, 5, 541 UV spectra, 5, 517 Purines, N-amino-synthesis, 5, 595 Purines, aminohydroxy-hydrogenation, 5, 555 reactions, 5, 555 Purines, aminooxo-reactions, 5, 557 thiation, 5, 557 Purines, bromo-synthesis, 5, 557 Purines, chloro-synthesis, 5, 573 Purines, cyano-reactions, 5, 550 Purines, dialkoxy-rearrangement, 5, 558 Purines, diazoreactions, 5, 96 Purines, dioxo-alkylation, 5, 532 Purines, N-glycosyl-, 5, 536 Purines, halo-N-alkylation, 5, 529 hydrogenolysis, 5, 562 reactions, 5, 561-562, 564 with alkoxides, 5, 563 synthesis, 5, 556 Purines, hydrazino-reactions, 5, 553 Purines, hydroxyamino-reactions, 5, 556 Purines, 8-lithiotrimethylsilyl-nucleosides alkylation, 5, 537 Purines, N-methyl-magnetic circular dichroism, 5, 523 Purines, methylthio-bromination, 5, 559 Purines, nitro-reactions, 5, 550, 551 Purines, oxo-alkylation, 5, 532 amination, 5, 557 dipole moments, 5, 522 H NMR, 5, 512 pJfa, 5, 524 reactions, 5, 556-557 with diazonium ions, 5, 538 reduction, 5, 541 thiation, 5, 557 Purines, oxohydro-IR spectra, 5, 518 Purines, selenoxo-synthesis, 5, 597 Purines, thio-acylation, 5, 559 alkylation, 5, 559 Purines, thioxo-acetylation, 5, 559... 

The intramolecular Michael addition11 of a nucleophilic oxygen to an a,/ -unsaturated ester constitutes an attractive alternative strategy for the synthesis of the pyran nucleus, a strategy that could conceivably be applied to the brevetoxin problem (see Scheme 2). For example, treatment of hydroxy a,/ -unsaturated ester 9 with sodium hydride furnishes an alkoxide ion that induces ring formation by attacking the electrophilic //-carbon of the unsaturated ester moiety. This base-induced intramolecular Michael addition reaction is a reversible process, and it ultimately affords the thermodynamically most stable product 10 (92% yield). 

The Michael addition of alkoxides to nitroalkenes gives generally a complex mixture of products due to the polymerization of nitroalkenes.16 The effect of cations of alkoxides has been examined carefully, and potassium- or sodium-alkoxides give pure p-nitro-ethers in 78-100% isolated yield (Eqs. 4.12 and 4.13).17 When lithium-alkoxides are employed, the yields are decreased to 20-40%. 

The importance of substituent and conformational effects in glycal additions was also demonstrated in attempting Michael addition of an alkoxide to the O-linked 2-nitrogalactal 1S3 and its C-linked analog 154. The a-toio-isomer 156 was obtained from 154 in contrast to the result of Michael addition to the analogous O-linked disaccharide 153, which eventually gave the 2-acetamido-a-galactoside-terminated disaccharide 155. 

Nielsen and Bedford synthesized gem-dinitroalkanes (147) from the Michael addition of organolithium reagents to a-nitroalkenes (146) followed by quenching of the resulting nitronate anion with tetranitromethane. The same reaction using alkoxides as bases provides P-alkoxy-gem-dinitroalkanes (148). ... 

The Michael addition followed by Intramolecular Ring Closure (MIRC) reactions have been recognized as a general synthetic approach to carbocyclic three-membered ring derivatives [1]. The enhanced Michael reactivity of methyl 2-chloro-2-cyclopropylideneacetate (1-Me) towards thiolates, alkoxides, lithiated amides and cyclohexadienolates (see below) allows one to perform highly efficient assemblies of spiropentane, tricyclo [3.2.1.0 ]octane, bicyclo [2.2.2] octane... 

General methods for the preparation of a.jS-unsaturated iron-acyl complexes are deferred to Section D 1.3.4.2.5.1.1. examples of the alkylation of enolates prepared via Michael additions to ii-0 ,/ -unsaturated complexes prepared in situ are included here. Typical reaction conditions for these one-pot processes involve the presence of an excess of alkyllithium or lithium amide which first acts as base to promote elimination of alkoxide from a /f-alkoxy complex to generate the -a,)S-unsaturated complex which then suffers 1,4-nucleophilic addition by another molecule of alkyllithium or lithium amide. The resulting enolate species is then quenched with an electrophile in the usual fashion. The following table details the use of butyllithium and lithium benzylamide for these processes44,46. 

It is interesting to note that the oxa-analogous Michael addition was reported for the first time in 1878 by Loydl et al. [19] in their work on the synthesis of artificial malic acid, which was five years ahead of the discovery of the actual Michael reaction described first by Komnenos [20], Claisen [21], and later Michael in 1887 [22] as one of the most important methods for C—C bond formation. In continuation of the early work on the oxa-Michael addition [23], the inter- and intramolecular additions of alkoxides to enantiopure Michael acceptors has been investigated, leading to the diastereo- and enantioselective synthesis of the corresponding Michael adducts [24]. The intramolecular reaction has often been used as a key step in natural product synthesis, for example as by Nicolaou et al. in the synthesis of Brevetoxin B in 1989 [25]. The addition of oxygen nucleophiles to nitro-alkenes was described by Barrett et al. [26], Kamimura et al. [27], and Brade and Vasella [28]. 

Ethyl-2-(sulfonylmethyl)- and 2-(cyanomethyl)-allyl carbonates133 as well as (methoxycarbo-nyl)methylallyl carbonates136 serve as substrates for the [3 + 2] cycloaddition. Oxidative addition into the allylic C—O bond of the carbonate, followed by decarboxylation, gives a 2-substituted allylpalladium al-koxide. The alkoxide then deprotonates the C—H a to the electron-withdrawing substituent at the 2-position of the allyl. This anion then undergoes a Michael addition to an a,(3-unsaturated ketone or ester, followed by intramolecular allylation of the anion of the Michael product (Scheme 2). 

Significant improvement in the catalytic activity of ALB was realized without any loss of enantioselectivity by using the second-generation ALB [27] generated by the self-assembled complex formation of ALB with alkali metal-malonate or alkoxide. This protocol allowed the catalyst loading to be reduced to 0.3 mol %, for example, the Michael addition of methyl malonate to cyclohexenone catalyzed by the self-assembled complex of (ff)-ALB (0.3 mol %) and KO Bu (0.27 mol %) in the presence of MS 4A gave the adduct in 94% yield and 99% ee [28]. This reaction has been successfully carried out on a 100-g scale wherein the product was purified by recrystallization. The kinetic studies of the reactions catalyzed by ALB and ALB/Na-malonate have revealed that the reactions are second-order to these catalysts (the rate constant ALB = 0.273 M 1h 1 ALB/Na-maionate = 1-66 M 1h 1) [27]. This reaction was used as the first key step for the catalytic asymmetric total synthesis of tubifolidine (Scheme 8D. 11) [28]. 

In a similar manner, Lu and Liu have more recently utilized the hetero-Michael addition of lithium propargylic alkoxides to alkylidene malonates in a synthesis of stereodefined allylidene tetrahydrofurans, based on the use of allylic chloride as coupling partner [98]. In this case, the cydization reaction is initiated by a catalytic amount of palladium salt [Pd(OAc)2] rather than by an organopalladium species as mentioned above. 

A Michael addition consists of the addition of the enolate of an active-methylene compound, the anion of a nitroalkane, or a ketone enolate to an acceptor-substituted alkene. Such Michael additions can occur in the presence of catalytic amounts of hydroxide or alkoxide. The mechanism of the Michael addition is shown in Figure 13.67. The addition step of the reaction initially leads to the conjugate base of the reaction product. Protonation subsequently gives the product in its neutral and more stable form. The Michael addition is named after the American chemist Arthur Michael. 

Table 5) [28], and heteroatom Diels-Alder reactions (Sch. 50) [79,80] but no X-ray structure had ever been reported for it or for the 3,3 -disubstituted derivatives which were first introduced as an asymmetric Claisen catalyst [24-27]. Although compound 435 was found not to induce any reaction between cyclohexenone and phosphonate 425 under the standard conditions for catalyst 428, consistent with the proposed equilibrium of species 394, 431, 432, 433, and 434 is the finding that catalysis of the reactions between cyclohexenone or cyclopentenone and phosphonate 425 with a 2 1 mixture of 434 (M = Li) and 435 gave only the Michael adducts 426 and 427 in 96 % ee and 92 % ee, respectively. Because 394 and 432 are inactive catalysts and 434 results in much lower induction and some 1,2-adduct, it was proposed that the active catalyst in the Michael addition of phosphonate 425 to cyclohexenone was the species 431 resulting from association of ALB catalyst with a metal alkoxide. It was proposed that the stereochemical determining step involved intramolecular transfer of the enolate of 425 to the coordinated cyclohexenone in species 436. 

In the lactone acylations discussed above, there was never any evidence for a competing side reaction due to break down of the hemiketal moiety and Michael addition of the alcohol to the newly formed pro-pargylic ketone. This may be taken as filler evidence for the stability of the ketal-alkoxide intermediate however, hemiketal ring opening and intramolecular Michael addition would provide an... 

The highly reactive carbonyl of lactone (60), an intermediate in the synthesis of forskolin, was easily converted to propargyl ketone (61) by addition of the lithium alkynide as shown in equation (48). It is possible that the intermediate ketal alkoxide was not stable in solution because of ring strain however, no multiple addition products were reported, nor was there any Michael addition of the alkoxide to the resulting ynone. 

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