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Copper Michael addition

Copper-mediated Addition Reactions to Extended Michael Acceptors... [Pg.146]

The Michael addition of the copper-zinc reagent derived from ethyl 4-bromobntyrate to the plperonal-derived nitroalkene proceeds cleaniy to give the nitre ester, which is an intermediate for the synthesis of lycoricidine alkaloids fEq. 4.85. ... [Pg.98]

In contrast, the diastereoselectivity of the conjugate addition of a chiral alkenylcoppcr-phosphinc complex to 2-mcthyl-2-cyclopentenone was dictated by the chirality of the reagent63. The double Michael addition using the cyclopentenone and 3-(trimethylsilyl)-3-buten-2-one and subsequent aldol condensation gave 4 in 58 % overall yield. The first Michael addition took place from the less hindered face of the m-vinylcopper, in which chelation between copper and the oxygen atom fixed the conformation of the reagent. [Pg.913]

In addition to a-additions to isocyanides, copper oxide-cyclohexyl isocyanide mixtures are catalysts for other reactions including olefin dimerization and oligomerization 121, 125, 126). They also catalyze pyrroline and oxazoline formation from isocyanides with a protonic a-hydrogen (e.g., PhCH2NC or EtOCOCHjNC) and olefins or ketones 130), and the formation of cyclopropanes from olefins and substituted chloromethanes 131). The same catalyst systems also catalyze Michael addition reactions 119a). [Pg.49]

Example The use of orgaiio copper compounds in Michael additions (p T 118) has a disadvantage in that one of the two starting R groups in (1) is wasted. [Pg.164]

No copper is necessary for the Michael addition. Alcohol (50) is dehydrated to a mixture of alkenes, all giving (45) on hydrogenation. The two phenol groups are protected throughout as their methyl ethers. [Pg.287]

Scheme 2.26. Copper-mediated Michael addition/electrophilic trapping. Scheme 2.26. Copper-mediated Michael addition/electrophilic trapping.
The key step in Hu s synthesis of 51 was cyclization of 50 by heating with copper(I) iodide and sodium hydride in DME, followed by a 10% aqueous ammonia work-up. Intermediate 50 was prepared via Michael addition of ethyl acetamidocyano acetate to the appropriate chalcone followed by acid-catalyzed ring closure [42,43]. [Pg.117]

Addition reactions depend on the metal used for the transmetalation of the zirconacyclo-pentadiene. After transmetalation to copper, an addition reaction occurs to the carbon-carbon double bond or to a carbon—carbon triple bond bearing electron-withdrawing groups (Michael addition reactions). On the other hand, transmetalation to Ni allows the use of carbon—carbon triple bonds bearing electron-donating groups. [Pg.67]

The utilization of copper complexes (47) based on bisisoxazolines allows various silyl enol ethers to be added to aldehydes and ketones which possess an adjacent heteroatom e.g. pyruvate esters. An example is shown is Scheme 43[126]. C2-Symmetric Cu(II) complexes have also been used as chiral Lewis acids for the catalysis of enantioselective Michael additions of silylketene acetals to alkylidene malonates[127]. [Pg.32]

Intermediates such as 224 resulting from the nudeophilic addition of C,H-acidic compounds to allenyl ketones such as 222 do not only yield simple addition products such as 225 by proton transfer (Scheme 7.34) [259]. If the C,H-acidic compound contains at least one carbonyl group, a ring dosure is also possible to give pyran derivatives such as 226. The reaction of a similar allenyl ketone with dimethyl mal-onate, methyl acetoacetate or methyl cyanoacetate leads to a-pyrones by an analogous route however, the yields are low (20-32%) [260], The formation of oxaphos-pholenes 229 from ketones 227 and trivalent phosphorus compounds 228 can similarly be explained by nucleophilic attack at the central carbon atom of the allene followed by a second attack of the oxygen atom of the ketone at the phosphorus atom [261, 262], Treatment of the allenic ester 230 with copper(I) chloride and tributyltin hydride in N-methylpyrrolidone (NMP) affords the cephalosporin derivative 232 [263], The authors postulated a Michael addition of copper(I) hydride to the electron-... [Pg.389]

During the last decade, a substantial number of novel (sometimes even stereoselective) strategies for the preparation of allenic prostaglandins have been devised. The approach used by Patterson involves a three-component coupling via a 1,4-addi-tion of the organocopper compound 121 to the enone 120, followed by alkylation of the enolate formed with the bromide 122 (Scheme 18.40) [121]. However, due to the notoriously low reactivity in the alkylation of the mixed copper-lithium enolate formed during the Michael addition [122], the desired product 123 was obtained with only 28% chemical yield (the alkylation was not even stereoselective, giving 123 as a 1 1 mixture of diastereomers). [Pg.1022]

Additional routes to a-allenic-a-amino acids were described more recently and utilize radical [136] or transition metal-catalyzed [137] allenylations, in addition to copper-promoted Michael additions [15b]. Thus, sterically demanding amino acid derivatives (e.g. 151) are accessible via a 1,6-addition reaction of lithium di-tert-butyl-cyanocuprate with acceptor-substituted enynes of type 150 (Scheme 18.48). [Pg.1027]

Zinc-copper compounds readily undergo Michael addition reactions in the presence of TMSCl, selectively affording 1,4-adducts [7, 34, 41, 42]. In the case of yS-disubstituted enones, the 1,4-addition proceeds well in the presence of BF3 OEt2 (Scheme 2.43) [89]. [Pg.65]

Scheme 2.43. Michael additions of copper-zinc reagents to enones. Scheme 2.43. Michael additions of copper-zinc reagents to enones.
In general, copper-zinc compounds, unlike organolithium-derived organocopper reagents, undergo clean addition reactions to nitroolefins. After Michael addition, the resulting zinc nitronates can be oxidatively converted into polyfunctional ketones, such as 117 (Scheme 2.45) [96]. [Pg.66]

Scheme 2.S7. Copper-catalyzed Michael addition reactions between organomanganese reagents and pulegone. Scheme 2.S7. Copper-catalyzed Michael addition reactions between organomanganese reagents and pulegone.
Similarly, alkenylzirconium species prepared by the hydrozirconation of alkynes add in a conjugated fashion to enones. Formation of an intermediate zincate prior to transmetalation to the copper species facilitates the Michael addition (Scheme 2.62) [135]. This methodology has been applied to the preparation of protected misoprostol 129 (Scheme 2.63) [136, 137]. [Pg.72]

Scheme 2.62. Michael addition of an alkenylzirconium compound", by successive transmetalation into zinc and copper intermediates. Scheme 2.62. Michael addition of an alkenylzirconium compound", by successive transmetalation into zinc and copper intermediates.
Thanks to their ambident character, acceptor-substituted dienes can provide several isomeric products in copper-mediated Michael additions, therefore making it particular important to control not only the regioselectivity but also the stereoselectivity of these transformations (Scheme 4.1). [Pg.146]

See other pages where Copper Michael addition is mentioned: [Pg.49]    [Pg.113]    [Pg.4]    [Pg.151]    [Pg.319]    [Pg.56]    [Pg.16]    [Pg.25]    [Pg.144]    [Pg.207]    [Pg.439]    [Pg.35]    [Pg.654]    [Pg.65]    [Pg.70]    [Pg.148]    [Pg.151]    [Pg.153]    [Pg.154]    [Pg.160]   
See also in sourсe #XX -- [ Pg.344 , Pg.352 , Pg.353 , Pg.354 , Pg.355 , Pg.356 , Pg.357 , Pg.358 , Pg.359 ]



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