Reactions Michael-alkylation

SCHEME 243 Chiral thiourea-catalyzed Michael-aldol cascade reaction. 

Highly strained spirocyclic oxindole structures (less than five-manbered rings) represents one of the most important but less studied spirocyclic skeletons. In 2011, 

SCHEME 2.AA Asymmetric synthesis of bispirooxindoles via a Michael—aldol cascade. 

SCHEME 2.45 Chiral thiourea-catalyzed Mannich-alkylation cascade reaction. 

SCHEME 2.46 Asymmetric synthesis of spiro-3,3 -cyclopropyl oxindoles via a Michael-aldol cascade reaction. 

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In the domino Michael/alkylation reaction applied to the synthesis of 3-(2H)-furanones, the ethyl 4-bromoacetoacetate 203 and nitrostyrene 204 were first trialed with a range of catalysts. In this instance, the so-called modified Feist Binary reaction was completed with an I-threonine bifunctional tertiary amine/thiourea catalyst 205 to produce the furanone 206 in excellent yield and high enantioselec-tivity (Scheme 7.42) [107]. In another report, the furan ring as part of other bicyclic or tricyclic systems was also prepared through an enantioselective Michael addi-tion/nucleophilic substitution reaction (Scheme 7.43) [108]. When diketones and ( )-P,P-bromonitrostyrenes 207 were stirred, again with a bifunctional thiourea... 

Historically the first cascade Michael-alkylation reaction was described almost simultaneously by the Wang and the Cordova groups by using a,(i-unsaturated aldehydes with bromomalonates or bromoacetoacetates. The reaction afforded cyclopropanes or cyclopentenones depending on the position of the halogen and was catalyzed by diphenylproHnol TMS ether (6) (Scheme 25.2) [5a,b]. 

Scheme 25.2 Enantioselective cascade Michael-alkylation reactions and the postulated mechanism.

Scheme 25.3 Michael-alkylation reactions with (a) stabilized" and (b) non-stabilized" alkyl halides.

Scheme 37.9 Synthesis of mono-, bi-, and tricyclic 2,3-dihydrofurans through domino Michael-alkylation reactions.

In contrast to the use of the specific type of sulfur ylides and related compounds, the employment of readily available alkyl halides for a catalytic Michael-alkylation reaction with enals to produce the corresponding formal [2-1-1] cycloadducts is an extremely challenging task. As an example, Wang [82a] and Cordova [82b, 83a] independently reported the enantioselective organocatalytic reaction of bromoma-lonates 78 and enals, which led to the corresponding cyclopropanes 79. In both cases, chiral diarylprolinol trimethylsilyl ethers 8 and 80 were involved as catalysts, giving access to the corresponding 2-formylcyclopropane derivatives 79 in... 

Purines, N-alkyl-N-phenyl-synthesis, 5, 576 Purines, alkylthio-hydrolysis, 5, 560 Mannich reaction, 5, 536 Michael addition reactions, 5, 536 Purines, S-alkylthio-hydrolysis, 5, 560 Purines, amino-alkylation, 5, 530, 551 IR spectra, 5, 518 reactions, 5, 551-553 with diazonium ions, 5, 538 reduction, 5, 541 UV spectra, 5, 517 Purines, N-amino-synthesis, 5, 595 Purines, aminohydroxy-hydrogenation, 5, 555 reactions, 5, 555 Purines, aminooxo-reactions, 5, 557 thiation, 5, 557 Purines, bromo-synthesis, 5, 557 Purines, chloro-synthesis, 5, 573 Purines, cyano-reactions, 5, 550 Purines, dialkoxy-rearrangement, 5, 558 Purines, diazoreactions, 5, 96 Purines, dioxo-alkylation, 5, 532 Purines, N-glycosyl-, 5, 536 Purines, halo-N-alkylation, 5, 529 hydrogenolysis, 5, 562 reactions, 5, 561-562, 564 with alkoxides, 5, 563 synthesis, 5, 556 Purines, hydrazino-reactions, 5, 553 Purines, hydroxyamino-reactions, 5, 556 Purines, 8-lithiotrimethylsilyl-nucleosides alkylation, 5, 537 Purines, N-methyl-magnetic circular dichroism, 5, 523 Purines, methylthio-bromination, 5, 559 Purines, nitro-reactions, 5, 550, 551 Purines, oxo-alkylation, 5, 532 amination, 5, 557 dipole moments, 5, 522 H NMR, 5, 512 pJfa, 5, 524 reactions, 5, 556-557 with diazonium ions, 5, 538 reduction, 5, 541 thiation, 5, 557 Purines, oxohydro-IR spectra, 5, 518 Purines, selenoxo-synthesis, 5, 597 Purines, thio-acylation, 5, 559 alkylation, 5, 559 Purines, thioxo-acetylation, 5, 559... 

Another procedure relies on a domino Michael-O-alkylation reaction sequence to yield a variety of dihydrofurans. Combination of cyclohexanedione (30) with vinyl bromide 50 in the presence of l,8-diazabicyclo[5.4.0]undec-7-ene (DBU) provides dihydrofuran 51 in 83% yield. Numerous 1,3-dicarbonyls and vinyl bromides are amenable to this methodology, and thus a wide range of products like 51 are available via this strategy. 

This type of reaction usually gives good yields here the possible iV-alkylation is reversible—through a retro-Michael-type reaction ... 

The Michael type reaction of f3/f -5-r-butyldimethysiloxy-3-phenyl-l//-pyrrolo[l,2-c oxa2ole with nitroethylene proceeds in the presence of Lev/is acid to give the alkylated product in good chemical yield and diastereoselecdvity In the case of nitroethylene, the Diels-Alder type transition state is favored to give the ryu-adduct selectively fEq 4 72 ... 

A common reaction sequence is shown in the schemes printed above. The sulfosuccinate monoesters are produced by a two-step reaction. In the first step 1 mol of maleic anhydride is reacted with a hydroxyl group-bearing component. In the second step the monoester is reacted with sodium sulfite (or sodium bisulfite) to form the disodium alkyl sulfosuccinate. At the so-called halfester stage, there are two possibilities for an electrophilic attack [61] (Michael-type reaction) at the double bond (Scheme 6). Reactivity differences between the two vinylic carbons should be very small, so that probably an exclusive formation of one single regioisomer can be excluded. 

The method is quite useful for particularly active alkyl halides such as allylic, benzylic, and propargylic halides, and for a-halo ethers and esters, but is not very serviceable for ordinary primary and secondary halides. Tertiary halides do not give the reaction at all since, with respect to the halide, this is nucleophilic substitution and elimination predominates. The reaction can also be applied to activated aryl halides (such as 2,4-dinitrochlorobenzene see Chapter 13), to epoxides, " and to activated alkenes such as acrylonitrile. The latter is a Michael type reaction (p. 976) with respect to the alkene. 

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. 

The Michael-type reaction of an anion (generated from compound 77) with ethyl crotonate yielded the corresponding ester 78 in 82% yield (Scheme 19). Alkylation of compound 77 with benzyl bromide afforded derivative 79 in 85% yield. The attempted reactions of the anion with oxiranes and trimethylsilyl chloride did not lead to the expected substitution products and the starting oxadiazoles were recovered in 70-80% yields <2001ARK101>. 

Standard cyclisation methodology was used to access the cyclic monophosphinic acid derivative 78 by reaction of ammonium phosphonate and ethyldiisopropylamine, followed by the addition of chlorotrimethylsilane, with 2,2 -bis (bromomethyl)-l,l -biphenyl. Silane reduction of 78 gave the secondary phosphine. The secondary phosphine borane complex 79 could be used in alkylation or Michael addition reactions. For example the Michael adduct 80 was produced in high yield by treatment of 78 with a NaH suspension in THF followed by the addition of diethylvinylphosphonate . 

By using diamines, the 2-alkyl-(benzo)imidazolines 581 and 582 were formed by a double Michael addition reaction and subsequent elimination of MeCN [266, 267]. 

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