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Other Michael-type Reactions

Other Michael-Type Reactions Oxidation of Sulfide to a Sulfoxide... [Pg.125]

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. [Pg.976]

Other interesting multicomponent sequences utilizing isocyanides have been elaborated by Nair and coworkers. In a recent example, this group exploited the nucleophilic nature of the isocyanide carbon, which allows addition to the triple bond of dimethyl acetylenedicarboxylate (DMAD) (9-90) in a Michael-type reaction (Scheme 9.19) [59]. As a result, the 1,3-dipole 9-91 is formed, which reacts with N-tosylimines as 9-92 present in the reaction vessel to give the unstable iminolactam 9-93. Subsequently, this undergoes a [1,5] hydride shift to yield the isolable aminopyrroles 9-94. In addition to N-tosylimine 9-92 and cyclohexyl isocyanide (9-89), substituted phenyl tosylimines and tert-butyl isocyanide could also be used here. [Pg.555]

Wang and co-workers [57,58] reported several Michael-type enantioselective additions with nitro-olefins. Under neat conditions, 1,3-dinitro compounds were generated in the 74 addition of nitroalkanes 75 to various P-substituted nitro-olefins (Scheme 15). Other Michael-type involving nitro-olefins reactions were illustrated using triazole donors 77 to offer good yields and high enantioselectivities (Scheme 16). [Pg.158]

Diketones. A new synthesis of 0-diketones depends on a Michael-type reaction of lithium 1-alkynyltrialkylborates with methyl vinyl ketone in the presence of an excess of TiCl4 (equation 1). Other Lewis acids are considerably less effective. [Pg.402]

Pyridines add to quinones in Michael-type reactions to give phenolbetaines (64). Many other Michael acceptors behave similarly, e.g. acrylate esters and acrylamides in the presence of acid yield quaternary ions py+CH2CH2COY. Pyridazine at room temperature with maleic anhydride gives the 2 1 adduct (65). [Pg.181]

Attack at a ring carbon atom, other than that of the carbonyl group, can be followed by proton addition, i.e., overall Michael-type reaction. Examples of this rather rare reaction type, which involves loss of aromaticity, are given in Section 3.2.I.6.8. [Pg.353]

The method is quite useful for particularly active alkyl hahdes, such as allylic, benzyhc, and propargyhc halides, and for a-halo ethers and esters. Other primary and secondary halides can show sluggish reactivity. The react of enamines with benzotriazole derivatives has been reported. Tertiary hahdes do not give the reaction at all since, with respect to the halide, this is nucleophilic substitution and ehmination predominates. The reaction can also be applied to activated aryl halides (e.g., 2,4-dinitrochlorobenzene see Chapter 13), to epoxides, and to activated alkenes, such as acrylonitrile. The latter is a Michael-type reaction (15-24) with respect to the alkene. [Pg.635]

The major adducts formed when phenanthridine is allowed to react with dimethyl acetylenedicarboxylate have been reformulated. - An initial Michael-type reaction gives the zwitterion (206) and succeeding reactions depend on the nature of the solvent. Adduct (207) is formed in anhydrous methanol by the addition of a proton and methoxide ion, while in benzene nucleophilic attack on the carbonyl group of a second ester molecule and subsequent cyclization provides 208. Alternatively, reaction at the triple bond of a second molecule of ester followed by ring closure of the new zwitterion gives 209. Other products related to 207 arise if the methanol contains water. 6-Methylphenanthridine with dimethyl acetylenedicarboxylate in benzene gives a mixture of the azepine (210) and tetramethyl 9a-methyl-9aA-dibenzo[a,c]quinolizine-6,7,8,9-tetracarboxylate. The... [Pg.384]

Synthetic peptide dendrimers, catalytic antibodies, RNA catalysts, peptide foldamers as well as other native or modified enzymes with completely different fxmctions were discovered to catalyze carbon-carbon bond formation [15]. 4-Oxalocrotonate tau-tomerase (4-OT) catalyzes in vivo the conversion of 2-hydroxy-2,4-hexadienedioate (136) to 2-oxo-3-hexenedioate (137) (Scheme 10.33a), and it belongs to the catabolic pathway for aromatic hydrocarbons in P. putida mt-2 [200]. This enzyme carries a catalytic amino-terminal proline, which could act as catalyst in the same fashion as the proline mediated by organocatalytic reactions. Initial studies demonstrate that this enzyme was able to catalyze aldol condensations of acetaldehyde to a variety of electrophiles 138 (Scheme 10.33b) [200]. This enzyme was also examined as a potential catalyst for carbon-carbon bond forming Michael-type reactions of acetaldehyde to nitroolefins 139 (Scheme 10.33c) [201,202]. [Pg.293]

Conventional synthetic schemes to produce 1,6-disubstituted products, e.g. reaction of a - with d -synthons, are largely unsuccessful. An exception is the following reaction, which provides a useful alternative when Michael type additions fail, e. g., at angular or other tertiary carbon atoms. In such cases the addition of allylsilanes catalyzed by titanium tetrachloride, the Sakurai reaction, is most appropriate (A. Hosomi, 1977). Isomerization of the double bond with bis(benzonitrile-N)dichloropalladium gives the y-double bond in excellent yield. Subsequent ozonolysis provides a pathway to 1,4-dicarbonyl compounds. Thus 1,6-, 1,5- and 1,4-difunctional compounds are accessible by this reaction. [Pg.90]

Other reactions that show preference for the acidic N-3—H group include Mannich aminomethylation by treatment with formaldehyde and an amine (38) to yield compound (8), reaction with ethyleneimine (39) to give (9), and Michael-type additions (40) such as the one with acrylonitrile to give (10) ... [Pg.251]

Class (2) reactions are performed in the presence of dilute to concentrated aqueous sodium hydroxide, powdered potassium hydroxide, or, at elevated temperatures, soHd potassium carbonate, depending on the acidity of the substrate. Alkylations are possible in the presence of concentrated NaOH and a PT catalyst for substrates with conventional pX values up to - 23. This includes many C—H acidic compounds such as fiuorene, phenylacetylene, simple ketones, phenylacetonittile. Furthermore, alkylations of N—H, O—H, S—H, and P—H bonds, and ambident anions are weU known. Other basic phase-transfer reactions are hydrolyses, saponifications, isomerizations, H/D exchange, Michael-type additions, aldol, Darzens, and similar... [Pg.186]

See other pages where Other Michael-type Reactions is mentioned: [Pg.136]    [Pg.184]    [Pg.350]    [Pg.179]    [Pg.136]    [Pg.184]    [Pg.350]    [Pg.179]    [Pg.161]    [Pg.239]    [Pg.235]    [Pg.96]    [Pg.273]    [Pg.326]    [Pg.212]    [Pg.384]    [Pg.187]    [Pg.250]    [Pg.56]    [Pg.149]    [Pg.403]    [Pg.161]    [Pg.18]    [Pg.119]    [Pg.190]    [Pg.219]    [Pg.245]    [Pg.245]    [Pg.257]    [Pg.300]    [Pg.655]    [Pg.27]    [Pg.135]    [Pg.7]    [Pg.93]    [Pg.60]   


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