Michael-Type Processes

Michael additions of organotitanium or zirconium reagents remain to be explored systematically. Recently, Stork described an interesting stereoselective intramolecular Michael addition in which zirconium enolates appear to be involved113). In another Michael type process, methyltitanium triisopropoxide 6 was added enantioselectively to a chiral a, p-unsaturated sulfoxide, but CH3MgCl was more efficient114). 

Enuminua behave in much the name way aa enolaU ion und enter into many oTthe eame kinds of reactions. In the Stork enamine reaction, for example, an enamine adds to an ar, i unaaturated carbonyl acceptor in a Michael-type process. Theinilial product is than hydrolyzed by aqueouB acid (Section 1. 9) to yield a UMicarbonyl compound. The overall reaction i thua a three-atep sequence ... 

Intermediate enolates derived from Michael-type processes can be isolated. For example, enantiomerically pure enolate (5 )-131 can be isolated, as is the case of the almost enantiomerically pure enolate (5 )-131, prepared by 1,4-addition of the phenyl-substituted borane 130 to enone 129, in the presence of a substoichiometric amount of the chiral rhodium mediator [Rh(OMe)(COD)]2-(5 )-BINAP (COD = 1,5-cyclooctadiene, equation 33). Protonation of (5 )-131 with methanol leads to cyclohexanone (5 )-132 in good yield with no loss of enantiomeric purity (equation 34). The protonation is presumably diastereoselective, taking place on the less hindered face of (5)-131, away from the neighbouring phenyl group, as can be inferred from the stereochemical outcome (133)... 

The 1,4-addition reactions of nucleophiles onto a, / -unsaturated ketones are well-known in Michael-type processes such reactions are run with high regioselectivities when using organocuprate reagents. 

OYEs are oxidoreductases that catalyze the addition of the elements of hydrogen to an electron-poor olefinic double bond in a stereospecific trans-manner [6]. The hydride is delivered from reduced flavin mononucleotide (FMNH2) in a Michael-type process, the proton being donated by a tyrosine residue [8] or by water [9,10] in the so-called oxidative half-reaction (Figure 5.1). NAD(P)H in the reductive half-reaction ensures reduction of the flavin [6]. Mechanistically... 

Addition Reactions. The addition of nucleophiles to quinones is often an acid-catalyzed, Michael-type reductive process (7,43,44). The addition of benzenethiol to 1,4-benzoquinone (2) was studied by A. Michael for a better understanding of valence in organic chemistry (45). The presence of the reduced product thiophenyUiydroquinone (52), the cross-oxidation product 2-thiophenyl-1,4-benzoquinone [18232-03-6] (53), and multiple-addition products such as 2,5-(bis(thiophenyl)-l,4-benzoquinone [17058-53-6] (54) and 2,6-bis(thiophenyl)-l,4-benzoquinone [121194-11-4] (55), is typical ofmany such transformations. 

All of these reacdons ptoceed in a similar pathway which involves the Michael type addidons of enamines to nitroalkenes or addidon of nitroalkanes to Imines and cyclizadon. This process has been achieved by solid-phase variadon fScheme 10.2. ... 

The history of dendrimer chemistry can be traced to the foundations laid down by Flory [34] over fifty years ago, particularly his studies concerning macro-molecular networks and branched polymers. More than two decades after Flory s initial groundwork (1978) Vogtle et al. [28] reported the synthesis and characterization of the first example of a cascade molecule. Michael-type addition of a primary amine to acrylonitrile (the linear monomer) afforded a tertiary amine with two arms. Subsequent reduction of the nitriles afforded a new diamine, which, upon repetition of this simple synthetic sequence, provided the desired tetraamine (1, Fig. 2) thus the advent of the iterative synthetic process and the construction of branched macromolecular architectures was at hand. Further growth of Vogtle s original dendrimer was impeded due to difficulties associated with nitrile reduction, which was later circumvented [35, 36]. This procedure eventually led to DSM s commercially available polypropylene imine) dendrimers. 

Besides the domino Michael/SN processes, domino Michael/Knoevenagel reactions have also been used. Thus, Obrecht, Filippone and Santeusanio employed this type of process for the assembly of highly substituted thiophenes [102] and pyrroles [103]. Marinelli and colleagues have reported on the synthesis of various 2,4-disubstituted quinolines [104] and [l,8]naphthyridines [105] by means of a domino Michael addition/imine cyclization. Related di- and tetrahydroquinolines were prepared by a domino Michael addition/aldol condensation described by the Hamada group [106]. A recent example of a domino Michael/aldol condensation process has been reported by Brase and coworkers [107], by which substituted tetrahydroxan-thenes 2-186 were prepared from salicylic aldehydes 2-184 and cycloenones 2-185 (Scheme 2.43). 

Electron-rich aromatic systems can act efficiently as Michael donors, as shown recently by Krohn s group (Scheme 2.46) [111]. For example, reaction of the enone 2-193 with the resorcine derivative 2-194 in a domino Michael/acetalization process led to various naturally occurring xyloketals of type 2-196 in excellent yield. 

Another option is the twofold Michael addition/SN-type sequence of which manifold versions have been published. Thus, Padwa s group reported on the di-astereoselective synthesis of bicydo[3.3.0]octenes [199], while in another approach by Hagiwara and coworkers various tricyclo[3.2.1.0]octane derivatives and similar bridged compounds have been constructed [200]. The group of Spitzner has also been engaged intensively in Michael/Michael/SN-type processes [201]. One such ex-... 

A fourfold anionic domino process consistingofadominoMichael/aldol/Michael/ aldol process was used by Koo and coworkers for the synthesis of bicyclo[3.3.1]non-anes. They employed 2 equiv. of inexpensive ethyl acetoacetate and 1 equiv. of a simple a, 3-unsaturated aldehyde [290]. Differently substituted dihydroquinolines were assembled in a Michael/aldol/elimination/Friedel-Crafts-type alkylation protocol by the Wessel group [291]. An impressive approach in this field, namely the construction of the indole moiety 2-557, which represents the middle core of the man-zamines, has been published by Marko and coworkers [292]. Manzamine A (2-555) and B (2-556) are members of this unique family of indole alkaloids which were isolated from sponges of the genus Haliclona and Pelina (Scheme 2.126) [293]. 

As already described for the all-carbon-Diels-Alder reaction, a hetero-Diels-Alder reaction can also be followed by a retro-hetero-Diels-Alder reaction. This type of process, which has long been known, is especially useful for the synthesis of heterocyclic compounds. Sanchez and coworkers described the synthesis of 2-aminopyridines [48] and 2-glycosylaminopyridines 4-144 [49] by a hetero-Diels-Alder reaction of pyrimidines as 4-143 with dimethyl acetylenedicarboxylate followed by extrusion of methyl isocyanate to give the desired compounds (Scheme 4.30). This approach represents a new method for the synthesis of 2-aminopyridine nucleoside analogues. In addition to the pyridines 4-144, small amounts of pyrimidine derivatives are formed by a Michael-type addition. 

In the epoxidation process (Figure 4.4), the oxygen of the enone s carbonyl function first coordinates with the zinc atom. The ethylperoxy anion then attacks the (3-position, which constitutes a Michael-type addition. The subsequent cyclization gives the epoxy ketone and the zinc alkoxide. 

Balme G, Bouyssi D, Monteiro N (2006) The Virtue of Michael-Type Addition Processes in the Design of Transition Metal-Promoted Cyclizative Cascade Reactions. 19 115-148 Barluenga J, Rodriguez F, Fanands FJ, Fldrez J (2004) Cycloaddition Reaction of Group 6 Fischer Carbene Complexes. 23 59-121 Basset J-M, see Candy J-P (2005) 16 151-210... 

Enamine nucleophiles react readily with soft conjugated electrophiles, such as a, 3-unsaturated carbonyl, nitro, and sulfonyl compounds [20-22], Both aldehydes and ketones can be used as donors (Schemes 27 and 28). These Michael-type reactions are highly useful for the construction of carbon skeletons and often the yields are very high. The problem, however, is the enantioselectivity of the process. Unlike the aldol and Mannich reactions, where even simple proline catalyst can effectively direct the addition to the C = O or C = N bond by its carboxylic acid moiety, in conjugate additions the charge develops further away from the catalyst (Scheme 26) ... 

Compound 388 is an acylating agent for electron-deficient alkenes, in a Michael addition process. It is formed by treating molybdenum hexacarbonyl with an organolithium compound, followed by quenching the intermediate 387 with boron trifluoride (equation 104). The structure of 388 (R = Ph) can be elucidated by NMR spectroscopy. Other examples of enantioselective and diastereoselective Michael-type additions involving lithium-containing intermediates in the presence of chiral additives can be found elsewhere in the literature . 

The diquinone 300 has been shown to react with a variety of primary amines producing carbazole quinones 301, a process which presumably involves an intermediate such as 302 formed by Michael-type addition. Alkyl-, aryl-, and heteroarylamines and amino acids have been utilized. The reaction failed with p-nitro- and p-acetylanilines neutral and acidic amino acids required base catalysis. Hydroxyl-... 

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