Michael addition side reaction

We anticipated that the Michael addition which is known to occur with bis(acrylamides) and primary amines might be a troublesome side reaction, expecially in the the latter stages of reaction when the concentration of acrylamide groups is very much higher than residual azlactone groups. This Michael addition side reaction is depicted in Equation 2. 

The Ir(lll) complex also funchoned as a catalyst in a tandem Nazarov cyclization-Michael addition. The reaction of monocyclic a-alkylidene-P-keto-y.b-unsaturated ester with nitroalkene gave bicyclic cyclopentenones which possessed an alkyl side chain, with high yield and diastereoselectivity (Scheme 11.36) [47]. 

Another important reaction in synthetic chemistry leading to C-C bond formation is the Michael addition. The reaction typically involves a conjugate or nucleophilic 1,4-addition of carbanions to a,/l-unsaturated aldehydes, ketones, esters, nitriles, or sulfones 157) (Scheme 21). A base is used to form the carbanion by abstracting a proton from an activated methylene precursor (donor), which attacks the alkene (acceptor). Strong bases are usually used in this reaction, leading to the formation of byproducts arising from side reactions such as condensations, dimerizations, or rearrangements. 

The N-H groups in the benzimidazole rings of PBIs are chemically reactive. Side-chain-grafted PBI can be achieved via a standard Sn2 or Michael addition type reaction between the amine moiety of PBI and the electrophile. In the 1990s, Bower and Sansone et al. [129-131] first developed the approach for preparing N-substituted PBIs. The pristine PBI was first reacted with an alkali hydride (NaH or LiH) to produce a PBI poly-anion in DMAc or NMP, which was then reacted with a substituted or unsubstituted alkyl, aryl, or alkenyl methyl halide to produce an M-substituted PBI, as shown in Fig. 7.7. The alkali hydride was used to increase the nucleophilicity of the amine. 

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). 

Classical syntheses of steroids consist of the stepwise formation of the four rings with or without angular alkyl groups and the final construction of the C-17 side-chain. The most common reactions have been described in chapter 1, e.g. Diels-AIder (p. 85) and Michael additions (p. 

Especially with the ordinary aldol reaction a number of side reactions can be observed, as a result of the high reactivity of starting materials and products. For instance, the a ,/3-unsaturated carbonyl compounds 4 can undergo further aldol reactions by reacting as vinylogous components. In addition compounds 4 are potential substrates for the Michael reaction. 

Various competitive reactions can reduce the yield of the desired Michael-addition product. An important side-reaction is the 1,2-addition of the enolate to the C=0 double bond (see aldol reaction, Knoevenagel reaction), especially with a ,/3-unsaturated aldehydes, the 1,2-addition product may be formed preferentially, rather than the 1,4-addition product. Generally the 1,2-addition is a kinetically favored and reversible process. At higher temperatures, the thermodynamically favored 1,4-addition products are obtained. 

The apparently loose structural requirements for antihista-iiiinic agents have already been alluded to. Thus, active compounds. ire obtained almost regardless of the nature of the atom that connects the side chain with the benzhydryl moiety. In fact, a methylene group, too, can also serve as the bridging group. Reaction of the aminoester, 95 (obtained by Michael addition of... 

The yield of the cyclization step under the influence of a metal template can be increased when the corresponding dialdehyde 19 of the tetrapyrrole 16 is used. The reaction sequence is initiated by insertion of palladium(II) or nickel(II) into the tetrapyrrole to give 20 followed by Michael addition of one acrylaldehyde side chain to the other yielding the macrotetracycle 21 from which in a retro-Michael reaction acetaldehyde is eliminated to give 22. 

In particular, a,P-unsaturated aldehydes seldom give 1,4 addition. The Michael reaction has traditionally been performed in protic solvents, with catalytic amounts of base, but more recently better yields with fewer side reactions have... 

The Michael addition of nitro compounds is a useful method for the preparation of various natural products. The Michael addition of nitroalkanes to dehydroalanines gives y-nitro-a-amino acids, which provides a convenient synthesis of side-chain modified a-amino acids (Eq. 4.114).152 Transformations of y-nitro-a-amino acid derivatives into a-amino acids occur by reductive denitration (see Section 7.2) into y-oxygenated a-amino acids by the Nef reaction (Eq. 

The controlled polymerization of (meth)acrylates was achieved by anionic polymerization. However, special bulky initiators and very low temperatures (- 78 °C) must be employed in order to avoid side reactions. An alternative procedure for achieving the same results by conducting the polymerization at room temperature was proposed by Webster and Sogah [84], The technique, called group transfer polymerization, involves a catalyzed silicon-mediated sequential Michael addition of a, /f-unsaluralcd esters using silyl ketene acetals as initiators. Nucleophilic (anionic) or Lewis acid catalysts are necessary for the polymerization. Nucleophilic catalysts activate the initiator and are usually employed for the polymerization of methacrylates, whereas Lewis acids activate the monomer and are more suitable for the polymerization of acrylates [85,86]. 

It has been shown that Lewis acid catalyzed isomerization of thionolactones provides access to thiolactones. For example, exposure of the substrate 22 to catalytic amounts of BF3 OEt2 led to efficient conversion to the thiolactone 23. Such transformations were also found to give minor amounts of lactone or dithiolactone side products <06TL6067>. Substituted tetrahydrothiophene derivatives have also been obtained from 1,4-dithiane-2,5-diol and 2-nitroethyl acetate derivatives by a base induced sequence featuring a Michael addition and a Henry reaction <06TL8087>. 

The more hindered (37c) is to be preferred the PB is less susceptible to Michael addition and (37c) as well as (37cH) are less nucleophilic than those of the lower esters (see Sect. 14.8.5 for an example). In the absence of side reactions these PBs are, upon workup, converted into the dihydro derivatives that can be reoxidized back to the PBs by bromine or by anodic oxidation [68, 87, 88]. The base strength of (38) can be modified either by substitution [89] or by complexation with alkali metal counterions [86, 89]. 

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