From Michael alkenes

However, use of a less reactive reagent where [R = R =(CH2)4, (CH2)s, (CH2)20(CH2)2] led to the isolation of products 61 and 62, with a reduction in the yields of the desired cycloadducts. The product 62 arises from Michael addition of the liberated methanethiol to A-methylmaleimide. The protocol was further extended to olefinic dipolarophiles with dimethyl fiimurate, dimethyl maleate, fumaronitrile, and 2-chloroacrylonitrile leading to the corresponding adducts, although these dipolarophiles proved somewhat less reactive with reduced yields being observed. Where applicable, the alkene configuration was reflected in the relative stereochemistry of the cycloadducts (Fig. 3.5). 

The multiple alkylation of carbanions with electron-deficient alkenes (Michael addition) only yields the expected products if the carbanion is less basic than the initial product of Michael addition. If the attacking carbanion and the carbanion resulting from Michael addition have similar basicity, oligomerization of the Michael acceptor can occur instead of multiple alkylations of the same carbon atom (Scheme 10.21). 

Cleavage of the hetero ring of 3-nitrobenzo[A]thiophene is the first step in a synthesis of ( )-2-aryl-l-[2-(methylsul-fonyl)phenyl]-l-nitroethenes (Scheme 176). The sulfonyl-stabilized anion derived from these alkenes by metallation adds in Michael fashion to the nitrovinyl unit to form 4-nitrothiochroman 1,1-dioxides as an inseparable mixture of two diastereomers. The overall process corresponds to expansion of a thiophene ring to a thiopyran unit <2004T4967>. 

Diethyl malonate adds to diethyl fumarate in a conjugate addition reaction promoted by sodium ethoxide in dry ethanol to give a tetraester, Diethyl fumarate is an excellent Michael acceptor because two ester groups withdraw electrons from the alkene, The mechanism involves deprotonation of the malonate, conjugate addition, and reprotonation of the product enolate by ethanol solvent, In this reaction two ester groups stabilize the enolate and two more promote conjugate addition. 

Several heteroatom nucleophiles, for example, amines, alcohols, thiols, carboxylates, and dialkylphosphines, undergo Michael addition reactions with alkene- and alkyne-substituted carbene complexes. Reaction of alkyne-substituted chromium carbenes with urea affords products derived from Michael... 

The radical anions of carbonyl groups can also be generated via PET from activated alkenes, e.g. allylic silanes or stannanes. Triplet excited aromatic ketones, a-dicarbonyls and Michael systems are suitable substrates for oxidizing allylic Group 14 organometallic compounds with subsequent formation of homoallylic alcohols or S-allylated ketones (Scheme 32) [120-122]. 

Azide additions to a,P-unsatnrated systems are another method for the preparation of 1,2,3-triazoles. Cydoaddition of aryl azides to a,P-unsaturated aldehydes 88 in the presence of catalytic diethylamine and DBU afforded 1,4-disubstituted-l,2,3-triazoles 89 via an inverse electron-demand process (13CC10187). Michael addition of sodium azide with ethyhdene bisphospho-nates 90 in cydoaddition reactions via sonication afforded bisphosphono-1,2,3-triazoles 91 (13T4047).A one-pot protocol for the synthesis of 1,2,3-triazoles was prepared from unactivated alkenes with azidosulfenylation of the carbon-carbon double bond followed by the copper-catalyzed azide—alkyne cycloaddition (13JOC5031). 1,5-Disubstituted-l,2,3-triazoles 93 were synthesized from enamides 92 with tosyl azide (13AG(E)13265). Reaction of ethyl 3-(alkylamino)-4,4,4,-trifluoro-but-2-enoates 94 with mesyl azide in the presence of DBU afforded l,2,3-triazole-4-carboxylates 95 (13EJ02891). 

The addition of B pin to activated alkenes is an efficient way to generate alkylboronates. One version of this reaction entailed the use of a platinum complex to catalyze the addition, which generated remarkably high yields of the boronates when heated (Scheme 6.6) [12, 13]. While there was some substrate specificity, this was an effective approach to the synthesis of alkylboronate compounds from Michael acceptors. It should be noted that a chiral imidazolinium salt catalyzed the enantioselective borylation of acyclic enones with excellent selectivity (up to er=98 2 [ 14]). The copper-catalyzed borylation of cyclopropenes has also been reported using bisphosphine as the chiral ligand (Schanes 6.7 and 6.8) [15,16] in... 

A short enandoselecdve synthesis of f- -f/f,/f -pytenophorin, a naturaUy occurring and-fun-giil 16-membered macrohde dilactone, is prepared from fS -5-nitropentan-2-ol via the Michael addidon and Nef reacdon fScheme 4.23. The choice of base Is important to get the E-alkene in the Michael addidon, for other bases give a rruxture of and Z-alkenes. The reqidslte chiriil fS -5-nitropentan-2-ol Is prepared by enandoselecdve redncdon of 5-nitropentan-2-one v/ith baker s yeast. ... 

Aromatic hydrocarbons, sometimes referred to as arenes, can be considered to be derived from benzene, C6H6. Benzene is a transparent, volatile liquid (bp = 80°C) that was discovered by Michael Faraday in 1825. Its formula, C6H6, suggests a high degree of unsaturadon, yet its properties are quite different from those of alkenes or alkynes. 

The catalytic conditions (aqueous concentrated sodium hydroxide and tetraalkylammonium catalyst) are very useful in generating dihalo-carbenes from the corresponding haloforms. Dichlorocarbene thus generated reacts with alkenes to give high yields of dichlorocyclopropane derivatives,16 even in cases where other methods have failed,17 and with some hydrocarbons to yield dicholromethyl derivatives.18 Similar conditions are suited for the formation and reactions of dibromocar-benc,19 bromofluoro- and chlorofluorocarbene,20 and chlorothiophenoxy carbene,21 as well as the Michael addition of trichloromethyl carbanion to unsaturated nitriles, esters, and sulfones.22... 

If the carbanion has even a short lifetime, 6 and 7 will assume the most favorable conformation before the attack of W. This is of course the same for both, and when W attacks, the same product will result from each. This will be one of two possible diastereomers, so the reaction will be stereoselective but since the cis and trans isomers do not give rise to different isomers, it will not be stereospecific. Unfortunately, this prediction has not been tested on open-chain alkenes. Except for Michael-type substrates, the stereochemistry of nucleophilic addition to double bonds has been studied only in cyclic systems, where only the cis isomer exists. In these cases, the reaction has been shown to be stereoselective with syn addition reported in some cases and anti addition in others." When the reaction is performed on a Michael-type substrate, C=C—Z, the hydrogen does not arrive at the carbon directly but only through a tautomeric equilibrium. The product naturally assumes the most thermodynamically stable configuration, without relation to the direction of original attack of Y. In one such case (the addition of EtOD and of Me3CSD to tra -MeCH=CHCOOEt) predominant anti addition was found there is evidence that the stereoselectivity here results from the final protonation of the enolate, and not from the initial attack. For obvious reasons, additions to triple bonds cannot be stereospecific. As with electrophilic additions, nucleophilic additions to triple bonds are usually stereoselective and anti, though syn addition and nonstereoselective addition have also been reported. 

For those substrates more susceptible to nucleophilic attack (e.g., polyhalo alkenes and alkenes of the type C=C—Z), it is better to carry out the reaction in basic solution, where the attacking species is RO . The reactions with C=C—Z are of the Michael type, and OR goes to the side away from the Z. Since triple bonds are more susceptible to nucleophilic attack than double bonds, it might be expected that bases would catalyze addition to triple bonds particularly well. This is the case, and enol ethers and acetals can be produced by this reaction. Because enol ethers are more susceptible than triple bonds to electrophilic attack, the addition of alcohols to enol ethers can also be catalyzed by acids. " One utilization of this reaction involves the compound dihydropyran... 

Conjugate reductions and Michael Alkylations of conjugated aldehydes are listed in Section 74 (Alkyls from Alkenes). 

This section contains alkylations of ketones and protected ketones, ketone transpositions and annulations, ring expansions and ring openings and dimerizations. Conjugate reductions and Michael alkylations of enone are listed in Section 74 (Alkyls from Alkenes). 

PTC has been extensively used for making cyclopropyl derivatives. The most common reaction involves generation of dichlorocarbene from chloroform, using NaOH and a quaternary ammonium hydroxide. The carbene subsequently reacts with an alkene in high yield. Hydrolysis of dichlorocarbene, normally rapid in the presence of water, is minimal. An interesting and very efficient example of a Michael addition to produce a cyclopropyl derivative is shown in Scheme 4.26. 

Unlike the late metal chemistry reviewed above, these reactions did not require Michael acceptor substrates, but the reactions were rather slow (turnover frequencies range from 2 to 13 h at 22°C). For phosphino-alkenes (Scheme 5-15, Eqs. 1-3), a competing uncatalyzed reaction gave six-membered phosphorinane rings (Scheme 5-15, Eq. 6) this could be minimized by avoiding light and increased temperature. For phosphino-alkynes (Scheme 5-15, Eqs. 4 and 5), the products were unstable and could not be isolated [14]. 

The synthesis of 2,3,5-trialkylpyrroles can be easily achieved by conjugate addition of nitroalkanes to 2-alken-l,4-dione (prepared by oxidative cleavage of 2,5-dialkylfuran) with DBU in acetonitrile, followed by chemoselective hydrogenation (10% Pd/C as catalyst) of the C-C- double bond of the enones obtained by elimination of HN02 from the Michael adduct. The Paal-Knorr reaction (Chapter 10) gives 2,3,5-trialkylpyrroles (Eq. 4.124).171... 

From the foregoing it can be seen that the nitro group can be activated for C C bond formation in various ways. Classically the nitro group facilitates the Henry reaction, Michael addition, and Diels-Alder reaction. Kornblum and Russell have introduced a new substitution reaction, which proceeds via a one electron-transfer process (SrnI). The SrnI reactions have recently been recognized as useful tools in organic synthesis. All these reactions can be used for the preparation of alkenes as described in this chapter. 

By contrast, L-phenylalanine methyl ester does not react with BENA generated from 1-nitropropane (R =H) due apparently to low nucleophilicity of the amino group. However, the N, C -coupling reaction of the ester of this amino acid with another internal BENA (R = CC>2Me) proceeds rather readily but is characterized by extremely low diastereoselectivity. Probably, the last N,C-coupling does not occur via an intermediate a-nitroso alkene but by a classical Michael addition to BENA MeCH=C(C02Me)N(05i )2 as to Michael substrate. 

As depicted in Scheme 11, ylides 39 derived from 4-methyl-[l,2,3]triazolo[l,5- ]pyridine react with Michael acceptors, which, upon nucleophilic attack at C3 and ring opening, lead to nucleophilic displacement of nitrogen. The intermediate diradical led to a mixture of compounds, including alkenes and a cyclobutane derivative when methyl acrylate was used, and the indolizine 40 with methyl propiolate as the electrophile <1998T9785>. Heating 4-methyl triazolopyridine with benzenesulfonyl chloride in acetone also confirmed decomposition via a radical pathway. 

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