Other Michael Reactions

Protected glycine derivatives have been used as the nucleophilic partner in enantioselective syntheses of amino acid derivatives by chiral PTC (Scheme 10.9). Loupy and co-workers have reported the addition of diethyl acetylaminomalonate to chalcone without solvent with enan-tioselectivity up to 82% ee [44]. The recent report from the Corey group, with catalyst 8a used in conjunction with the benzophenone imine of glycine t-butyl ester 35, discussed earlier, results in highly enantioselective reactions (91-99% ee) with various Michael acceptors (2-cyclo-hexenone, methyl acrylate, and ethyl vinyl ketone) to yield products 71-73 [21], Other Michael reactions resulting in amino acid products are noted [45]. 

It seems appropriate to inquire whether or not it is possible to carry out other Michael reactions and, generally, other nucleophilic additions to unsaturated compounds as a sequence of kinetically independent steps using one s choice of nucleophiles and electrophiles The answer is definitely yes . A rationale similar to that used to describe the Robinson annulation provides us with the key to how this goal may be attained. First of all, the initial step of the reaction, addition of the nucleophilic component across a double (or triple) bond, needs to be carried out in the absence of the external electrophiles (preferably in aprotic solvents). Secondly, a carbanionic intermediate, incipiently formed at this step, requires sufficient stabilization to survive as a chemical entity under... 

The asymmetric Michael reaction can be catalysed by enantiomerically pure crown ethers in the presence of base. For instance the addition of cyclic donor (11.16) with acceptor (11.22) occurs with up to 99% ee using an enantiomerically pure crown ether in the presence of potassium tert-butoxide. In fact, enantiomerically pure crown ethers have been used to catalyse other Michael reactions, including the use of crown ether (11.45) in the conjugate addition reaction between the ester (11.46) and Michael acceptor (11.47). The reaction is remarkably rapid (one minute at —78°C). 

So far in this section we have combined enolate anions with other carbonyl compounds by direct attack at the carbonyl group. We can expand the scope of this reaction by using a,p-unsaturated carbonyl compounds as the electrophiles. This is the Michael reaction. Remind yourself of tliis by writing out the mechanism of a Michael reaction such as ... 

Acrolein reacts slowly in water to form 3-hydroxypropionaldehyde and then other condensation products from aldol and Michael reactions. Water dissolved in acrolein does not present a hazard. The reaction of acrolein with water is exothermic and the reaction proceeds slowly in dilute aqueous solution. This will be hazardous in a two-phase adiabatic system in which acrolein is suppHed from the upper layer to replenish that consumed in the lower, aqueous, layer. The rate at which these reactions occur will depend on the nature of the impurities in the water, the volume of the water layer, and the rate... 

Ba.se Catalyzed. Depending on the nature of the hydrocarbon groups attached to the carbonyl, ketones can either undergo self-condensation, or condense with other activated reagents, in the presence of base. Name reactions which describe these conditions include the aldol reaction, the Darzens-Claisen condensation, the Claisen-Schmidt condensation, and the Michael reaction. 

The 1,4-addition of an enolate anion 1 to an o ,/3-unsaturated carbonyl compound 2, to yield a 1,5-dicarbonyl compound 3, is a powerful method for the formation of carbon-carbon bonds, and is called the Michael reaction or Michael addition The 1,4-addition to an o ,/3-unsaturated carbonyl substrate is also called a conjugate addition. Various other 1,4-additions are known, and sometimes referred to as Michael-like additions. 

The best Michael reactions are those that take place when a particularly stable enolate ion such as that derived from a /i-keto ester or other 1,3-dicarbonyl compound adds to an unhindered a,/3-unsaturated ketone. Tor example, ethyl acetoacetate reacts with 3-buten-2-one in the presence of sodium ethoxide to yield the conjugate addition product. 

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. 

The preparation of 5-ACETYL-l,2,3,4,5-PENTAMETHYLCYCLO-PENTADIENE is of value in the synthesis of pentamethyleyclo-pentadiene and many pentamethylcyclopentadienyl metal carbonyl derivatives that are more soluble in organic solvents than those derived from cyclopentadiene. Simple preparations of 5,6-DIHYDRO-2-PYRAN-2-0NE and 2-//-PYRAN-2-ONE make these hitherto rather inaccessible intermediates available for cycloaddition and other reactions. The already broad scope of the Michael reaction has been widened further by including an efficient preparation of ETHYL (E)-3-NITROACRYLATE. Workers in the field of heterocyclic chemistry will find a simplified method for the preparation of 2,3,4,5-TETRA-HYDROPYRIDINE of help. 

With any substrate, when Y is an ion of the type Z—CR2 (Z is as defined above R may be alkyl, aryl, hydrogen, or another Z), the reaction is called the Michael reaction (see 15-21). In this book, we will call all other reactions that follow this mechanism Michael-type additions. Systems of the type C=C—C=C—Z can give 1,2, 1,4, or 1,6 addition. Michael-type reactions are reversible, and compounds of the type YCH2CH2Z can often be decomposed to YH and CH2=CHZ by heating, either with or without alkali. 

In this article, special attention has been paid to cyclopropanations, Diels-Alder reactions, and nucleophilic substitutions, for which numerous works have been devoted to the use of Ar,N-containing ligands. Other classical reactions allowing the formation of a new C - C bond have been omitted here (e.g., Michael-type additions or aldol reactions) where they have also been, to a lesser extent, efficiently performed using nitrogen-containing ligands. 

This was the order followed for TM (42), but in other cases, the Michael reaction came last. 

On the other hand, chiral sulfur-containing but noncoordinating ligands such as sulfonamides have been widely used in the asymmetric Michael reaction. In 1997, Sewald et al. reported the use of a series of chiral sulfonamides depicted in Scheme 2.25 in the Cu-catalysed conjugate addition of ZnEt2 to 2-cyclohexenone. Even the use of a stoichiometric amount of catalyst did not allow the enantioselectivity to be higher than 31% ee. 

On the other hand, the enantioselective 1,4-addition of carbanions such as enolates to linear enones is an interesting challenge, since relatively few efficient methods exist for these transformations. The Michael reaction of p-dicarbonyl compounds with a,p-unsaturated ketones can be catalysed by a number of transition-metal compounds. The asymmetric version of this reaction has been performed using chiral diol, diamine, and diphosphine ligands. In the past few years, bidentate and polydentate thioethers have begun to be considered as chiral ligands for this reaction. As an example, Christoffers et al. have developed the synthesis of several S/O-bidentate and S/O/S-tridentate thioether... 

The previous sections dealt with reactions in which the new carbon-carbon bond is formed by addition of the nucleophile to a carbonyl group. Another important method for alkylation of carbon nucleophiles involves addition to an electrophilic multiple bond. The electrophilic reaction partner is typically an a,(3-unsaturated ketone, aldehyde, or ester, but other electron-withdrawing substituents such as nitro, cyano, or sulfonyl also activate carbon-carbon double and triple bonds to nucleophilic attack. The reaction is called conjugate addition or the Michael reaction. 

Heck reactions can also be combined with anion capture processes, animations, metatheses, aldol and Michael reactions, and isomerizations. The anion capture process has also been widely used with other Pd-catalyzed transformations. Outstanding examples of many different combinations have been developed by Grigg and coworkers, though not all of them match the requirements of a domino process. All of these reactions will be detailed here, despite the fact the nature of these intermediate transformations would also have permitted their discussion in Chapter 2. 

It should be emphasized that in no case were derivatives of AN containing the C-Si bond detected, although the formation of these compounds in certain silylation reactions as kinetic products cannot be ruled out. In particular, this can be expected for nitronates (51 h,i) (Scheme 3.57) generated in the reactions of silylated dimethylformamides with conjugated nitro olefins (202), because this reaction with other Michael substrates affords products with the C-Si bond. 

There are only few examples of organic reactions catalysed effectively by Lewis acids which can be carried out in pure water without any organic co-solvent. While water can be used successfully for the uncatalysed Michael addition of 1,3-diketones (Table 4, entry D)22, the corresponding reaction of /i-kctocsters does not give satisfactory results. On the other hand, the Yb(OTf)3 catalysed Michael reaction of various /i-ketoesters (Table 21, entry A)257 and a-nitroesters (Table 21, entry B)258 takes place. 

Bismaleimides - Bismaleimides resins were first introduced into the market in the early 1970 s. As with other resin systems, there are many variations of bismaleimides. The Kermid and Kinel bismaleimide products as marketed in the U. S. by Rhodia are representative examples. Bismaleimide chemistry is represented in Eq. 3 where curing can be accomplished thermally through the unsaturation in the maleimide or by way of the Michael Reaction where an appropriate curing agent such as aromatic diamine adds across the activated double bond. In most instances, a combination of curing thermally through the double bond and via an aromatic diamine is used in actual practice. Bismaleimides are frequently formulated... 

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