Michael-type alkenes, addition

In the reaction of Q,/3-unsaturated ketones and esters, sometimes simple Michael-type addition (insertion and hydrogenolysis, or hydroarylation, and hydroalkenylation) of alkenes is observed[53,54]. For example, a simple addition product 56 to methyl vinyl ketone was obtained by the reaction of the heteroaromatic iodide 55[S5]. The corresponding bromide affords the usual insertion-elimination product. Saturated ketones are obtained cleanly by hydroarylation of o,/3l-unsaturated ketones with aryl halides in the presence of sodium formate, which hydrogenolyses the R—Pd—I intermediate to R— Pd—H[56]. Intramolecular hydroarylation is a useful reaction. The diiodide 57 reacts smoothly with sodium formate to give a model compound for the afla-toxin 58. (see Section 1.1.6)[57]. Use of triethylammonium formate and BU4NCI gives better results. 

The Michael-type addition of maleic hydrazide and other pyridazinones to activated alkenes, such as methyl acrylate, acrylonitrile, methyl vinyl ketone and other a,/3-unsatu-rated carbonyl compounds, results in the formation of mono-lV-substituted products. 

Aziridines have been prepared stereospecifically by the nucleophilic addition of the nitrogen residue to alkenes <80T73). Introduction of the nitrene is accomplished readily via a Michael-type addition with free diphenylsulfilimine (Scheme 12), and where a chiral sulfilimine is used the chirality is transferred to the aziridine with optical yields in excess of 25%. 

The intramolecular Michael-type addition of the nitrogen atom of piperidines to activated alkenes located at a C(2)-side chain is a quite common way of access to the quinolizidine system. Some examples are given below. 

The base-catalysed addition of thiols to Jt-electron-deficient alkenes is an important aspect of synthetic organic chemistry. Particular use of Triton-B, in place of inorganic bases, has been made in the reaction of both aryl and alkyl thiols with 1-acyloxy-l-cyanoethene, which behaves as a formyl anion equivalent in the reaction [1], Tetra-n-butylammonium and benzyltriethylammonium fluoride also catalyse the Michael-type addition of thiols to a,P-unsaturated carbonyl compounds [2], The reaction is usually conducted under homogeneous conditions in telrahydrofuran, 1,2-dimethoxyethane, acetone, or acetonitrile, to produce the thioethers in almost quantitative yields (Table 4.22). Use has also been made of polymer-supported qua-... 

Examples of the Michael-type addition of carbanions, derived from activated methylene compounds, with electron-deficient alkenes under phase-transfer catalytic conditions have been reported [e.g. 1-17] (Table 6.16). Although the basic conditions are normally provided by sodium hydroxide or potassium carbonate, fluoride and cyanide salts have also been used [e.g. 1, 12-14]. Soliddiquid two-phase systems, with or without added organic solvent [e.g. 15-18] and polymer-supported catalysts [11] have been employed, as well as normal liquiddiquid conditions. The micellar ammonium catalysts have also been used, e.g. for the condensation of p-dicarbonyl compounds with but-3-en-2-one [19], and they are reported to be superior to tetra-n-butylammonium bromide at low base concentrations. 

Michael-type addition of activated methylene compounds to electron-deficient alkenes... 

Nitroalkanes react with Jt-deficient alkenes, for example, p-nitro ketones are produced from a,P-unsaturated ketones [41], whereas allylic nitro compounds have been prepared via the Michael-type addition of nitroalkanes with electron-deficient alkynes (Table 6.19). The reaction in either dimethylsulphoxide [42] or dimethyl-formamide [43] is catalysed by potassium fluoride in the presence of benzyltriethyl-ammonium chloride the reaction with dimethyl acetylenedicarboxylate is only successful in dimethylsulphoxide [42], Primary nitroalkanes produce double Michael adducts [42,44], A-Protected a-aminoacetonitriles react with alkynes under catalysed solidiliquid conditions to produce the Michael adducts [45] which, upon treatment with aqueous copper(Il) sulphate, are converted into a,p-unsaturated ketones. 

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 Cp2TiCl/H20 couple can also be used to achieve inter- and intramolecular Michael-type additions of aldehydes to conjugated alkenals (Scheme 34) [84]. 

Good reversible binding of O2 and CO was observed for Cu(I)-dielate (Table 18) The Cu(I)- and Cu(n)-chelates (122) show a high activity in the Michael-type addition of alcohols to acrolein Up to 66 mol /3-alkoxypropionaldehyde per mol metal center were obtained the yield decreased with lower Cu content in (122) Acrylonitrile is polymerized in the presence of (122)-Cu(II) under H2 pressure. The Co containing complex is able to polymerize styrene and to catalyze Michael additions. For a Pd-complex CO binding and afterwards catalytic hydrogenation of alkenes are reported ... 

One possible mechanism is the following. The allenyl geminal diester 70 is expected to be susceptible to Michael-type addition of LnPd(O) species to the allenyl sp carbon, resulting in the formation of the palladacyclopropane 71. Insertion of carbon monoxide into 71 and methanolysis afford the triester 72 (Scheme 11-20). The alkene geometry of the product 72 is exclusively E. The high stereoselectivity can be rationalized by assuming that a nucleophilic attack of Pd(0) species on the allenyl sp carbon in 70 takes place from the less-hindered side of a smaller alkyl substituent (R ). Needless to say, in allene 70, the two ester groups are perpendicular to the two substituents Rl and Rg. 

Ruder, S.M., and Kulkarni, V.R., Michael-type additions of 2-(diethoxyphosphinyl) cyclohexanone to activated alkenes and alkynes, J. Chem. Soc.. Chem. Commun., 2119, 1994. 

They speculated that the imidazolium cation of [pmim][Br] activates CS toward nucleophilic attack by amine to generate a dithiocarbamate anion, which can then undergo Michael-type addition to conjugated alkenes to afford the substituted dithiocarbamate (Fig. 12.59). 

Similarly, PT-catalyzed condensation of a-chlorocarbanions, or of sulfonium and ammonium ylides, with electron-deficient alkenes, which proceeds via Michael-type addition followed by intramolecular substitution, is the most efficient procedure for synthesis of substituted cyclopropanes ... 

As an intramolecular version, the vinylcyclopentane 89 was obtained from methyl 4,5-hexadienylcyanoacetate (88) by C-1 attack in 57 % yield using DPPF in the absence of a base [24]. In the intermolecular reaction of 2,3-butadienyl-malononitrile (90) with the activated alkene 91, at first Michael-type addition of malononitrile to the alkene occurred to give 93, which underwent cyclization to give the cyclopentane 92 via the formation of hydridopalladium 94 [25]. 

Despite of the fact that Baylis and Hillman reported the synthesis of a-hydr-oxyethylated nitroethylene through the reaction between nitroethylene and acetaldehyde in the presence of DABCO, nitroalkenes employed as activated olefins in MBH reaction have not received much attention until recently. Prompted by the fact that nitroalkenes have shown superior Michael acceptor abilities, and that the first step in the MBH reaction is the Michael-type addition of the catalyst to substrate, Namboothiri et al. have published a series of papers on nitroalkenes involved the MBH reaction. The MBH reactions between nitroalkenes and various electrophiles such as formaldehyde, activated carbonyl compounds, imines, alkenes and azodicarboxylates " in the presence... 

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