Michael reaction donors

Thiol protection. As a Michael reaction donor, this reagent forms adducts with thiols. Regeneration of the thiols is by treatment with pyrrolidine in MeCN. 

Michael reactions take place by addition of a nucleophilic enolate ion donor to the /3 carbon of an a,(3-unsaturated carbonyl acceptor, according to the mechanism shown in Figure 23.7. 

The Michael reaction occurs with a variety of a,/3-unsaturated carbonyl compounds, not just conjugated ketones. Unsaturated aldehydes, esters, thio-esters, nitriles, amides, and nitro compounds can all act as the electrophilic acceptor component in Michael reactions (Table 23.1). Similarly, a variety of different donors can be used, including /3-diketones, /3-keto esters, malonic esters, /3-keto nitriles, and nitro compounds. 

A Michael reaction involves the conjugate addition of a stable enolate ion donor to an o,/3-unsaturated carbonyl acceptor, yielding a 1,5-dicarbonyl product. Usually, the stable enolate ion is derived from a /3-diketone, jS-keto ester, malonic ester, or similar compound. The C—C bond made in the conjugate addition step is the one between the a carbon of the acidic donor and the (3 carbon of the unsaturated acceptor. 

What product would you obtain from a base-catalyzed Michael reaction of 3-buten-2-one with each of the following nucleophilic donors ... 

The Robinson annulation is a two-step process that combines a Michael reaction with an intramolecular aldol reaction. It takes place between a nucleophilic donor, such as a /3-keto ester, an enamine, or a /3-diketone, and an a,/3-unsaturated ketone acceptor, such as 3-buten-2-one. The product is a substituted 2-cyclohexenone. 

The conjugate addition of a carbon nucleophile to an a./3-unsiituratcd acceptor is known as the Michael reaction. The best Michael reactions take place between unusually acidic donors (/3-keto esters or /3-diketones) and unhindered n,/3-unsaturated acceptors. Knamines, prepared by reaction of a ketone with a disu Instituted amine, are also good Michael donors. 

How might the following compounds be prepared using Michael reactions Show the nucleophilic donor and the electrophilic acceptor in each case. 

Michael reaction, 894-895 acceptors in, 895 donors in, 895 mechanism of. 894-895 Robinson annulation reactions and, 899-900... 

In 2002, Leadbeater and Torenius reported the base-catalyzed Michael addition of methyl acrylate to imidazole using ionic liquid-doped toluene as a reaction medium (Scheme 6.133 a) [190], A 75% product yield was obtained after 5 min of microwave irradiation at 200 °C employing equimolar amounts of Michael acceptor/donor and triethylamine base. As for the Diels-Alder reaction studied by the same group (see Scheme 6.91), l-(2-propyl)-3-methylimidazolium hexafluorophosphate (pmimPF6) was the ionic liquid utilized (see Table 4.3). Related microwave-promoted Michael additions studied by Jennings and coworkers involving indoles as heterocyclic amines are shown in Schemes 6.133 b [230] and 6.133 c [268], Here, either lithium bis(trimethylsilyl)amide (LiHMDS) or potassium tert-butoxide (KOtBu) was em-... 

Figure 7. Donors in the quinine-catalyzed Michael Reaction (42).

Asymmetric allylic C-H activation of more complex substrates reveals some intrinsic features of the Rh2(S-DOSP)4 donor/acceptor carbenoids [135, 136]. Cyclopropanation of trans-disubstituted or highly substituted alkenes is rarely observed, due to the steric demands of these carbenoids [16]. Therefore, the C-H activation pathway is inherently enhanced at substituted allylic sites and the bulky rhodium carbenoid discriminates between accessible secondary sites for diastereoselective C-H insertion. As a result, the asymmetric allylic C-H activation provides alternative methods for the preparation of chiral molecules traditionally derived from classic C-C bond-forming reactions such as the Michael reaction and the Claisen rearrangement [135, 136]. 

Scheme 6.139) [293]. Ricci and co-workers explained the outcome of their aza-Michael reaction with the mechanistic picture visualized in Scheme 6.140 C9-epi-QN -derived thiourea 121 displayed a bifunctional mode of catalysis, which simultaneously activated both the chalcone Michael acceptor and the donor O-benzylhydroxylamine through explicit hydrogen bonding. 

The developmenf of self-curing resins, i.e., systems curing without photoinitiators or, in some cases, with just small amounts of photoinitiators, has been reported recently. Such resins are synthesized by Michael reaction of acrylic functional materials with Michael donor compounds such as acetoacetates. The resulting product has an increased molecular weight compared to the parent acrylate(s). This provides resins with reduced volatility and propensity for skin absorpfion. This new technology is versatile and flexible and opens a possibility of synfhesis of a large number of different acrylate resins. The novel resins reportedly exhibit unique depth of cure capability. In the absence of a photoinitiator (PI), film of approximately 10 mils (0.25 mm) thick can be cured at a line speed of 100 fpm (30.5 m/min). When only 1% of PI is added, the thickness of film that can be cured increases to over 100 mils (2.5 mm). 

Quantitative conversion is one of the essential preconditions to achieve a significant molecular weight in stepwise polymerization process. Consequently, an iron-catalyzed Michael reaction would be a suitable elementary step for a polyaddition. Bis-donor 24c and bis-acceptor 41b, readily accessible from common starting materials [69], were converted with FeCl3-6H20 to yield a poly-addition product... 

The iron catalysis of vinylogous Michael reactions is not only restricted to dimerizations. The y-donor 46b can be converted with MVK (41a) to give the 1,7-dioxo-constituted product 49 when the catalyst is Fe(III) (Scheme 8.21) [75]. If NaOMe in MeOH is applied as the catalyst, reaction of the dienolate of donor 46b in the a-position with acceptor 41a proceeds via a normal Michael reaction and 1,5-dioxo-constituted product 50 is obtained. 

The ability of the maleimide unit to switch off emission is also exemplified by 86, due to Verhoeven s coworkers [161] at the University of Amsterdam and Akzo Nobel in The Netherlands. Again the Michael reaction of the maleimide with thiols produces nicely emissive material. Solvent-sensitive emission, characteristic of these donor-acceptor systems with strongly coupling bridges, is a special feature of 86 after thiolation. An added interest of 86 stems from the occurrence of PET to the maleimide unit from the through-bond charge-transfer excited state [162], an unusual combination of photophenomena. 

The 1,4-addition (or conjugate addition) of resonance-stabilized carbanions. The Michael Addition is thermodynamically controlled the reaction donors are active methylenes such as malonates and nitroalkanes, and the acceptors are activated olefins such as a,P-unsaturated carbonyl compounds. 

Amino Acid-catalyzed Asymmetric Michael Reaction Using C-donors... 

Recent contributions by several groups revealed that L-proline is also a suitable catalyst for the asymmetric Michael reaction using C-donors [1, 13-15]. In the first reports, in general... 

Scheme 6. Asymmetric L-proline-catalyzed Michael reactions with C-donors.

Scheme 7. Asymmetric tripeptide-catalyzed Michael reaction with an N-donor.

In contrast, asymmetric Michael reactions are promoted by alkali metal free La-BINOL ester enolate complexes (Scheme 28) [251]. The catalyst is best prepared by successive addition of the Michael donor and (S)-BINOL to La(0 Pr)3. 

With respect to the site at which the new asymmetric carbon center is created, the catalytic enantioselective Michael reaction can be categorized into two groups (Fig. 1) in Type I an asymmetric center is generated on the Michael donor side in Type II an asymmetric center is generated on the Michael acceptor side. 

The general reaction mechanism of the Michael reaction is given below (Scheme 4). First, deprotonation of the Michael donor occurs to form a reactive nucleophile (A, C). This adds enantioselectively to the electron-deficient olefin under the action of the chiral catalyst. In the final step, proton transfer to the developed enolate (B, D) occurs from either a Michael donor or the conjugate acid of a catalyst or a base, affording the desired Michael adduct. It is noteworthy that the large difference of stability between the two enolate anions (A/B, C/D) is the driving force for the completion of the catalytic cycle. 

Dihydropyridine 129 has been shown to catalyze Michael reactions in aqueous cationic micelles of cetyltri-methylammonium bromide (Scheme 34) <2003CL1064>. In the micelles, dihydropyridine 129 ionizes to form an acetophenone enolate salt 130. The highly basic enolate deprotonates the Michael donor which then rapidly reacts with the Michael acceptor. The use of anionic surfactants did not promote Michael reactions, suggesting that the cationic micelles promote the dissociation of salt 130. 

Polymer-supported quaternary ammonium hydroxides have been used to catalyse Michael reactions between various alkyl methacrylates, acrylonitrile, and methyl vinyl ketone as acceptors and nitro or keto derivatives as donors.[116,117]... 

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