Michael products

The reaction of a dibromochalcone with hydroxylamine hydrochloride in pyridine gave three products with the expected 2-isoxazoline product as the predominate compound. A ring bromination product and an isoxazole were also isolated (70UC796). The reaction of hydroxylamine with /S-thiosulfates of propiophenone at reflux produced 3-phenyl-2-isoxazo-line (455). At room temperature a bis-Michael product (456) was produced. The reaction with N -phenylhydroxylamine yielded a mono-Michael type product (457) (74CPB1990). 

Display and describe the lowest-unoccupied molecular orbital (LUMO) for cyclohexenone. This is the orbital into which the nucleophile s pair of electrons will go. Does it anticipate both carbonyl and Michael products of nucleophilic addition Explain. A clearer picture is provided by a LUMO map for cyclohexenone. This gives the value of the LUMO on the accessible surface of the molecule, i.e., on the molecule s electron density surface. Does it anticipate both of the observed products If so, which should be the dominant Explain your choice. 

Recently the Bohlmann-Rahtz synthesis has received greater attention. Baldwin has employed this method for the construction of heterocyclic substituted a-amino acids. Exposure of alkynyl ketone 39 to 3-aminocrotoyl ester 40 resulted in the Michael product 41. Thermolysis then gave rise to the desired pyridyl-P-alanines 42. 

The first successful results of the asymmetric Michael addition under phase transfer catalyzed conditions were achieved by use of ingeniously designed chiral crown ethers 13 and 52.1441 The 3-keto ester 49 reacted with methyl vinyl ketone by use of 13 to give the Michael product 50 with excellent enantioselectivity but in moderate yield, as shown in Scheme 18. The Michael addition of methyl 2-phenylpropionate 51 to methyl acrylate afforded the diester 53 by use of another crown ether 52 in good yield with good enantioselectivity.1441 Various chiral crown ethers were studied to... 

The unsaturated retro-Michael product easily isomerizes to a dicarbonyl when the Cy also carries a hydroxyl group (X = OH in Fig. 2.3). Such components are notoriously unstable. They undergo decarbonylation to a shorter aldehyde and CO. The retro-Michael product can also be converted into a carboxylic acid via hydration of the aldehyde function (Fig. 2.3). Notably, the formation of the carboxylic acid is accompanied by the saturation of the Cp it in fact represents an exchange reaction between the OH, and the aldehydic H. 

These retro-Aldol and -Michael reactions can, obviously, follow an isomerization of the aldose to the corresponding ketose, leading thereby to different Aldol fragments or retro-Michael products. Keto-enol exchange as well as the retro-... 

Dixon [75] also investigated the use of unconventional carbon donors, such as the mandelic acid derivative 119 in the highly stereoselective addition to -substituted nitro-olefms. The Michael product 120 was formed smoothly and can be converted in simple one-step procedures to generate various chiral building blocks for syntheses (Scheme 26). 

Knoevenagel adduct 239 of oxohomophthalimide 240 with malononitrile 27a in reactions with CH-acids behaves ambiguously (82CPB1215). Reactions of 239 with acetylacetone, ethyl esters of acetoacetic and ben-zoylacetic acids, as well as methyl pyruvate led to the formation of the desired spiropyrans 241. However, benzoylacetone, dibenzoylmethane, cyanacetamide, and oxindole always gave the same 242. Authors explain this feature in terms of a retro-cleavage of adducts of Michael product 239... 

The addition of nitromethane (56% yield/168h 87% ee) or methyl a-cyanoacetate (94% yield/52h 82% ee) as alternative CH-acidic methylene compounds required increased reaction temperatures (60 to 80 °C) to furnish the adducts 7 and 8. As exemplarily depicted in Scheme 6.69 for benzylic alcohol thiourea 12 catalyzes the transformation of the obtained malononitrile Michael products to the respective carboxyhc acid derivatives (89% yield/88h). This method of derivatization also described for methanol (87% yield/24h rt), benzyl amine (77% yield/3h rt), and N,0-dimethylhydroxyamine (75% yield/20h 60°C) as nucleophiles was reported to be feasible as a one-pot strategy without isolation of the initially formed Michael adduct [222]. 

Scheme 6.101 Typical Michael products obtained from the 97- and 99-catalyzed addition of ketones to frans-P-nitrostyrenes.

With primary halides, dimers (R—R) are formed predominantly, while with tertiary halides, the disproportionation products (RH, R(—H)) prevail. Both alkyl nickel(III) complexes, formed by electrochemical reduction of the nickel(II) complex in presence of alkyl halides, are able to undergo insertion reactions with added activated olefins. Thus, Michael adducts are the final products. The Ni(salen)-complex yields the Michael products via the radical pathway regenerating the original Ni(II)-complex and hence the reaction is catalytic. In contrast to that, the Ni(III)-complex formed after insertion of the activated olefin into the alkyl-nickel bond of the [RNi" X(teta)] -complex is relatively stable. Thus, further reduction leads to the Michael products and an electroinactive Ni"(teta)-species. 

For years most Michael reactions were carried out under protic conditions so that rapid proton transfer was possible. However, in the early 1970s several groups performed Michael reactions under aprotic conditions and these processes are now quite common. Early attempts at trapping a kinetic enolate in aprotic solvents with simple enones such as methyl vinyl ketone or an a. -unsaturated ester such as acrylate led to a scrambling of the enolate (using the Michael product as proton source).8 However, the introduction of an a-trialkylsilyl group in the enone (93 Scheme 10) permitted the trapping of kinetic... 

Ethyl-2-(sulfonylmethyl)- and 2-(cyanomethyl)-allyl carbonates133 as well as (methoxycarbo-nyl)methylallyl carbonates136 serve as substrates for the [3 + 2] cycloaddition. Oxidative addition into the allylic C—O bond of the carbonate, followed by decarboxylation, gives a 2-substituted allylpalladium al-koxide. The alkoxide then deprotonates the C—H a to the electron-withdrawing substituent at the 2-position of the allyl. This anion then undergoes a Michael addition to an a,(3-unsaturated ketone or ester, followed by intramolecular allylation of the anion of the Michael product (Scheme 2). 

Another highly useful heterobimetallic catalyst is the aluminum-lithium-BINOL complex (ALB) prepared from LiAlH4 and 2 equiv. of (/ )-BINOL. The ALB catalyst (10 mol %) is also effective in the Michael reaction of enones with various malonates, giving Michael products generally with excellent enantioselectivity (91-99% ee) and in excellent yields [23]. These results ate summarized in Table 8D.3. Although LLB and LSB complement each other in their ability to catalyze asymmetric nitroaldol and Michael reactions, respectively, the Al-M-(/ )-BINOL complexes (M = Li, Na, K, and Ba) are commonly useful for the catalytic asymmetric Michael reaction. 

Michael additions of C-nudeophiles such as the indanone 1 have been the subject of numerous further studies For example, the reaction between the indanone 1 and methyl vinyl ketone was effected by a solid-phase-bound quinine derivative in 85% yield and with remarkable 87% ee by d Angelo, Cave et al. [5], Co-polymers of cinchona alkaloids with acrylonitrile effected the same transformation Kobaya-shi and Iwai [6a] achieved 92% yield and 42% ee and Oda et al. [6b] achieved almost quantitative yield and up to 65% ee. Similarly, partially resolved 2-(hydroxy-methyl)quinudidine was found to catalyze the reaction between 1 and acrolein and a-isopropyl acrolein with induction of asymmetry, but no enantiomeric excesses were determined [7]. As shown in Scheme 4.4, the indanone 7 could be added to MVK with up to 80% ee under phase-transfer conditions, by use of the Cinchona-derived PT-catalysts 9a and 9b, affording the Michael-product 8 or enf-8, respectively [8]. The adducts 8 or ent-8 were intermediates in the stereoselective Robinson anellation of a cydohexenone ring to the indanone 7 [8],... 

The Michael addition of methyl a-acetamidoacrylate (196) with pyrrole (1) under silica-supported Lewis acid (Si(M) Si(Zn), Si(Al) and Si(Ti)) assisted by microwave irradiation (MW) afforded the alanine derivatives 395 and 396 dependent on the reaction conditions (Scheme 81) [153]. Both MW and thermal activation for pyrrole gave only Michael product 396, whereas alanine derivatives 395, which are the a-Michael addition product, and 396 were observed with A1 and Ti-catalyst. This behavior shows that aluminium and titanium Lewis acids can form a new acceptor in an irreversible way. The Si(M) or p-TsOH catalyzed reactions of N-benzylpyrrolc 397 with the acrylate 196 under MW gave the product 398 as sole product. The reaction yield has been increased by using a catalytic amount of p-TsOH (Scheme 82). 

The electron-rich oxygen atom of a secondary amide derivative of cinnamic acid can be as effective as that of a cinnamyl ether or alcohol in directing anr/-Michael additions to some amide Michael acceptors. For example, BuLi adds to the amide 51 to give a 90 10 ratio of anti-Michael Michael addition products 52 53.31 With the alkyne54 the effect is even more pronounced MeLi gives solely the anti-Michael product 55. These reactions are however very sensitive to starting material and reagent structure. 

Michael addition of tin enolates to a,/3-unsaturated esters is accomplished in the presence of catalytic amount of Bu4NBr. Other typical system using lithium enolates or silyl enolates with catalysts (Lewis acid or Bu4NF) fails to give the Michael products. An ab initio calculation reveals that higher reactivity is caused by high coordination of the tin enolate and the keto enol tautomerization for Michael adducts contributes to thermodynamical stabilization (Equation (77)).231 232... 

The third situation usually arises when the molecule has a stereogenic centre. As an example we can take the Michael product from the beginning of this section. 

Reaction of 4,7-dihydroindoles with DMAD led to Michael product 644 (ratio of (E) (Z) = 1 2.5). Aromatization of the cyclohexadiene ring by DDQ gave the not easily accessible 2-vinylindole 645 (Scheme 129) <2006JOC7793>. 4,5,6,7-Tetrahydroindole with DMAD (CH2CI2, 20°C, 36h) gives addition product in a yield of 50% (ratio of (E) (Z) = 1 3.3). 

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