Malonic Michael addition with

The group ofWalborsky probably has described one of the first true anionic/radi-cal domino process in their synthesis of the spirocyclopropyl ether 2-733 starting from the tertiary allylic bromide 2-730 (Scheme 2.161) [369]. The first step is a Michael addition with methoxide which led to the malonate anion 2-731. It follows a displacement of the tertiary bromide and a subsequent ring closure which is thought to involve a SET from the anionic center to the carbon-bromine anti bonding orbital to produce the diradical 2-732 and a bromide anion. An obvious alternative Sn2 halide displacement was excluded due to steric reasons and the ease with which the reaction proceeded. 

A pentopyranoside-fused butenolide is the key intermediate for the synthesis of the natural micotoxin patulin [226, 227]. Its synthesis involves Wittig olefination of a 3,4-di-O-protected arabinopyran-2-uloside, followed by protecting group removal and dehydration (Scheme 47). In other research, the glucopyranosid-2-uloside 190 was converted into the butenolide derivative 191 by aldol condensation with diethyl malonate and transesterification [228]. The latter was shown to be prone to autoxi-dation, leading to 192. Subsequent Michael addition with hydroxide ion, followed by decarboxylation, furnishes C-branched-chain sugar 193. 

As is to be expected, an alkynic ketone undergoes a Michael addition with a carbanion, leading eventually to a pyranone (50JA1022). Using malonic esters, a 3-alkoxycarbonyl derivative results, which is hydrolyzed to the 2-oxopyran-3-carboxylic acid under alkaline conditions, but to the pyranone by sulfuric acid. Rapid ester exchange is observed with the initial products, the alcohol used as solvent determining the nature of the alkyl group in the 3-carboxylic esters (Scheme 90). 

Several structurally different diketones (acetylacetone, methyl 2-oxocyclohex-ane carboxylate) and active methylene compounds (diethyl malonate, ethyl aceto-acetate) and thiols (methyl thioglycolate) underwent clean, fast, and efficient Michael addition with methyl vinyl ketone, acrolein, and methyl acrylate over NaY and Na beta zeolites [88] in high yield (70-80%). The reactions were performed in the absence of solvent, at room temperature, with 1 g catalyst per mmol donor. When HY zeolite was used instead of NaY formation of the desired Michael adduct was low and polymerization of Michael acceptor was the main reaction. 

As a direct route for the constructing carbon-carbon bonds, catalytic asymmetric Michael additions with various carbon-based nucleophiles including malonic esters, cyanide, electron-deficient nitrile derivatives, a-nitroesters, nitroalkanes, Horner-Wadsworth-Emmons reagent, indoles, and silyl enol ethers have attracted considerable attention. 

With the multifunctional primary amine-thiourea catalyst (which was prepared from (l/ ,2/ )-l, 2-diaminocyclo-hexane and 9-amino (9-deoxy) epiquinine) in the absence of additives, the asymmetric Michael addition of malonate to cyclic enone proceeded well to afford 1,4-adducts in excellent yields and enantioselectivities (Table 9.10). Particularly noteworthy is that all examined malonates afforded higher than 95% enantioselectivities. In general, the reaction could even complete within a short period of time (12-18 hours) to give >90% yields and high enantioselectivity (93-96% ee) when the reactions were carried out at an elevated reaction temperature. Moreover, the reaction of 2-cyclohepten-l-one also afforded more than 90% ee and 83% yield. Furthermore, the use of 4,4-dimethylcyclohex-2-enone resulted in 77% yield with 91% ee. Only 2-cyclo-penten-l-one furnished medium yield and enantioselectivity. In contrast to previous reports, this reaction system exhibits excellent catalytic activity in asymmetric Michael addition with a broad scope of both malonate and cyclic enone. 

In the above reaction one molecular proportion of sodium ethoxide is employed this is Michael s original method for conducting the reaction, which is reversible and particularly so under these conditions, and in certain circumstances may lead to apparently abnormal results. With smaller amounts of sodium alkoxide (1/5 mol or so the so-called catal3rtic method) or in the presence of secondary amines, the equilibrium is usually more on the side of the adduct, and good yields of adducts are frequently obtained. An example of the Michael addition of the latter type is to be found in the formation of ethyl propane-1 1 3 3 tetracarboxylate (II) from formaldehyde and ethyl malonate in the presence of diethylamine. Ethyl methylene-malonate (I) is formed intermediately by the simple Knoevenagel reaction and this Is followed by the Michael addition. Acid hydrolysis of (II) gives glutaric acid (III). 

The decarboxylation of allyl /3-keto carboxylates generates 7r-allylpalladium enolates. Aldol condensation and Michael addition are typical reactions for metal enolates. Actually Pd enolates undergo intramolecular aldol condensation and Michael addition. When an aldehyde group is present in the allyl fi-keto ester 738, intramolecular aldol condensation takes place yielding the cyclic aldol 739 as a main product[463]. At the same time, the diketone 740 is formed as a minor product by /3-eIimination. This is Pd-catalyzed aldol condensation under neutral conditions. The reaction proceeds even in the presence of water, showing that the Pd enolate is not decomposed with water. The spiro-aldol 742 is obtained from 741. Allyl acetates with other EWGs such as allyl malonate, cyanoacetate 743, and sulfonylacetate undergo similar aldol-type cycliza-tions[464]. 

Incorporation of a carbonyl group into the alkyl side chain also proved compatible with biologic activity. The key intermediate (76) is obtainable by Michael addition of the anion from diethyl malonate to methylvinyl ketone followed by ketalization with ethylene glycol. Condensation of 76 with hydrazobenzene leads to the pyrazolodione hydrolysis of the ketal group affords ketasone (78). ... 

The application of 3-aminopropyl phosphine (3) [41,46] as a building block for incorporation into -COOH functionalized frameworks provides an excellent example of the utility of preformed primary phosphine frameworks (Scheme 8) [46]. The reactions involved Michael addition of ferf-butyl acrylate to malonic acid dimethyl ester to produce the intermediate adduct, 2-methoxycarbonyl-pentanedioc acid 5-ferf-butyl ester 1-methyl ester, which upon treatment with trifluro-acetic acid (TFA) produced the corresponding diester acid,2-methoxy-carbonyl-pentanedioic acid 1-methyl ester, in near quantitative yield. It is remarkable to note that the reaction of NH2(CH2)3PH2 (3) with the diester acid is highly selective as the -COOH group remained unattacked whereas the reaction occurred smoothly and selectively at the -COOMe groups to pro-... 

A Knoevenagel condensation/Michael addition sequence has been reported by Barbas III and coworkers (Scheme 2.70) [158] using benzaldehyde, diethyl malonate, and acetone in the presence of the chiral amine (S)-l-(2-pyrrolidinyl-methyl)-pyrrolidine (2-301). As the final product the substituted malonate 2-302 was isolated in 52% yield with 49% ee. 

Michael addition has been shown to lead to useful building blocks. According to a publication by Johnson and coworkers, highly functionalized unsymmetrical malonic acid derivatives are accessible in this way [268]. Moreover, as described by Takeda and coworkers, substituted four- to six-membered carbocycles 2-507 can be prepared starting from 2-504 by reaction with PhLi via the intermediates 2-505 and 2-506 (Scheme 2.115) [269]. 

Reactions of a,(3-unsaturated acylzirconocene chlorides with stable carbon nucleophiles (sodium salts of dimethyl malonate and malononitrile) at 0°C in THF afford the Michael addition products in good yields (Scheme 5.38). Direct treatment of the reaction mixture with allyl bromide in the presence of a catalytic amount of Cul -2LiCl (10 mol%) in THF at 0 °C gives the allylic ketone in a one-pot reaction. This sequential transformation implies the electronic nature of a,P-unsaturated acylzirconocene chloride to be of type E as shown in Scheme 5.37. 

Michael additions to acceptor-substituted dienes are often followed by (spontaneous or induced) cyclizations. This was already noted by Vorlander and Groebel4 who obtained a substituted 1,3-cyclohexanedione by treatment of 6-phenyl-3,5-hexadien-2-one with diethyl malonate (equation 5). Obviously, the 1,4-addition product which is formed initially then undergoes cyclization, ester hydrolysis and decarboxylation. Similarly, reaction of methyl sorbate with methyl 4-nitrobutyrate gave the 1,6-adduct which was reductively cyclized to 6-methyl-l-azabicyclo[5.3.0]decane18 (equation 6). 

Tan and co-workers reported the Michael reactions of di-thiomalonates and P-keto-thioesters to a range of acceptors, including maleimides, cyclic enones, furanones and acyclic dioxobutenes [129]. Unlike dimethyl malonate, additions with acidic thioesters proceeded in higher yields, and overall better enantioselectivities (Scheme 74). 

Barbas developed this procedure further by introducing an asymmetric three-component Michael reaction that should be applicable to many other conjugate addition reactions. He used a Wittig olefmation to prepare, in situ, an a,P-unsatu-rated ketone that subsequently underwent a conjugate addition with malonates (Scheme 21) [94]. The rate of the conjugate addition process was observed to be considerably faster than the analogous reaction reported by Jprgensen which was attributed to the presence of triphenylphosphine oxide within the reaction mixture. 

In a similar vein, Knoevenagel condensation of nicotinaldehyde (88) with diethyl malonate gives the unsaturated ester Michael addition of dimethylamine... 

A chiral phase transfer catalyst was dissolved in ionic liquid media for the enantioselective Michael reaction of dimethyl malonate with l,3-diphenylprop-2-en-l-one with K2CO3 203). The phase-transfer catalyst was a chiral quininium bromide (Scheme 20). The reaction proceeded rapidly with good yield and good enantioselectivity at room temperature in all three ionic liquids investigated, [BMIM]PF6, [BMIM]BF4 and [BPy]BF4. In the asymmetric Michael addition, the enantioselectivity or the reaction in [BPy]Bp4 was the same as in conventional organic solvents. 

The strong basic sites associated with surface OH groups are responsible for the catalytic activity of the activated Ba(OH)2 in organic reactions, such as the Michael addition (285). The authors showed, for example, that the Michael addition of diethyl malonate to chalcone catalyzed by activated Ba(OH)2 yielded 95% of the Michael adduct. When Ba(OH)2 was selectively poisoned with TBMPHE, a conversion of only 5% was observed, however when Ba(OH)2 was poisoned with DNB a conversion of 58% was obtained. The small poisoning effect of DNB indicates that only a small number of reducing sites with basic character (e.g., 0 ) can act in the process as basic sites. Thus, it was concluded that the basic sites responsible for the catalytic activity must be surface OH groups on the Ba(OH)2 H2O. 

The Michael addition of nucleophiles to coumarins catalyzed by solid bases provides an interesting approach to the synthesis of 4-substituted 3,4-dihydrocumarins, because with the conventional Michael catalysts the alkaline hydrolysis of the 8-lactone predominates (Scheme 44). Results were obtained when the Michael addition of diethyl malonate to coumarin was catalyzed by the activated Ba(OH)2 292). An unusual 1,2-addition-elimination process at the C = 0 bond was observed. The mechanism of this reaction was explained on the basis of the microcrystalline structure of the catalyst. It was suggested that the rigid coumarin molecule interacts with the Ba ions through the lone-pair electrons of both oxygen atoms of the... 

Scheme 6.61 Mechanistic proposals of the 12-catalyzed asymmetric Michael addition of diethyl malonate to trans-P-nitrostyrene proposed by the Takemoto group (A, B, and C) and initial enolate complex (D) with the ammonium group as additional hydrogen-bond donor initiating an alternative mechanism suggested by Sods, Ptipai, and coworkers.

Mettler and colleagues reported an alternative synthesis of malonate 16 in the same paper (Griffiths et al., 1991) in which they condensed cyclohexanone with ethyl cyano-acetate instead of diethyl malonate in the Knoevenagel reaction to give ethyl cyano(cyclohexylidene)-acetate (18). In the presence of a catalytic amount of sodium cyanide, the Michael addition of HCN to cyanoacetate 18 proceeded in good yield at room temperature to generate the dicyanoester 19. Intermediate 19 was selectively converted to malonate 16 with pressurized HCI treatment in ethanol (Scheme 16.4). 

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