Michael addition of ethyl cyanoacetate

The same hyperbranched polyglycerol modified with hydrophobic palmitoyl groups was used for a noncovalent encapsulation of hydrophilic platinum Pincer [77]. In a double Michael addition of ethyl cyanoacetate with methyl vinyl ketone, these polymer supports indicated high conversion (81 to 59%) at room temperature in dichloromethane as a solvent. The activity was stiU lower compared with the noncomplexed Pt catalyst. Product catalyst separation was performed by dialysis allowing the recovery of 97% of catalytic material. This is therefore an illustrative example for the possible apphcation of such a polymer/catalyst system in continuous membrane reactors. 

The phosphine-containing ruthenium dihydride dendrimer 33 was found to be an active catalyst for the diastereoselective Michael addition of ethyl cyanoacetate to diethyl ethylidenemalonate in THF (Scheme 12). The dendritic catalyst showed an activity and selectivity similar to those of the reference compound RuH2(PPh3)4 (100% conversion after 24 h and a diastereoselectivity of 7/3) (40). The dendritic catalyst was recycled twice by precipitation with diethyl ether without loss of activity or selectivity. Complex 34 showed similar activity and recoverability over three runs like that of complex 33. 

The cyclization of 5-oxonitriles offers an attractive route to 2-amino-4//-pyrans (Scheme 18) (78JHC57). The starting materials, a-benzoylcinnamonitriles, are available from benzoyl-acetonitrile and an aromatic aldehyde. Michael addition of ethyl cyanoacetate or malononitrile to the benzoylcinnamonitrile affords the oxonitrile and is followed by cyclization to the imine. The reaction proceeds at room temperature in the presence of either piperidine or sodium ethoxide. 

In Michael additions of ethyl cyanoacetate, diethylmalonate and 1,3-diones to acrolein, methylvinylketone and other enones, the catalytic activity on the system was... 

CsLa-MCM-41 catalyzes the Michael addition of ethyl cyanoacetate (2) to ethyl acrylate (14) (Scheme 9). Besides formation of the mono adduct (15), bis adduct 16, formed by a double Michael addition, is produced consecutively. Although the basicity of CsLa-MCM-41 is quite mild, its performance in this reaction is very good. Table 4 compares the activity and selectivity obtained with different catalysts. Although product selectivity is probably also controlled by the mesoporous MCM-41 support, the basicity of CsLa-MCM-41 is too weak to catalyze the Michael addition of diethyl malonate under the same conditions. 

A Michael addition of ethyl cyanoacetate followed by protection of the cyclohexanone carbonyl group of the major cis isomer 18 as a cyclic acetal led to cyanoester 19. Hydroxymethylation with formaldehyde and subsequent protection of the hydroxy group as a MOM-ether provided the substituted cyclohexane derivative 20 as a mixture of diastereoisomers. 

Scheme 2 shows Rapoport s synthesis [15]. The cinnamic acid derivative 3 prepared from m-methoxy benzaldehyde [20] was ethylated by diethyl sulfate to give ethyl cinnamate derivative 4, followed by Michael addition with ethyl cyanoacetate to afford compound 5. Compound 5 was converted to lactam 6 by the reduction of the cyano group and subsequent cyclization. Selective reduction of the lactam moiety of 6 was achieved by treatment with trimethy-loxonium fluorob orate followed by sodium borohydride reduction. Amine 8 was obtained by the reductive methylation of amine 7. Amine 8 was converted to compound 9 by methylene lactam rearrangement [21], followed by selenium dioxide oxidation to provide compound 10. Allylic rearrangement of compound 10 and subsequent hydrolysis gave compound 12. The construction of the decahydroisoquinoline structure began with compound 12,... 

Carbon-carbon bond formation via the Michael addition of a,P-unsaturated ketone and 1,3-diketone is achieved in high yields and short times to give (61) by employing catalytic amounts of EUCI3 in dry media under microwave irradiation (Soriente et al, 1997). Ranu et al. (1997) reported the Michael addition of ethyl acetoacetate, acetyl acetone, and ethyl cyanoacetate to cycloalkenones, P-substituted enones and enal. The reaction accomplished efficiently on the surface of alumina under microwave irradiation in dry media. Baruah et al. (1997a,b) also demonstrated the BiClj and Cdl2 catalyzed solvent-free Michael addition of 1,3-dicarbonyl compounds under microwave irradiations with good yields. 

Lasperas et al. [73,74,78] have studied the Knoevenagel condensation between benzaldehyde (1) and ethyl cyanoacetate (2) in the presence of over-exchanged CsY zeolites. The reaction was performed under a nitrogen atmosphere in dimethyl sulfoxide (DMSO), the best solvent for eliminating interference from the non-catalyzed reaction. The use of equimolar amounts of each reactant suppressed successive Michael addition between ethyl cyanoacetate and ethyl cyanocinna-mate (3) to give compound 4 (Scheme 5) this resulted in high selectivity for the Knoevenagel product (3) (95 % at 90 % conversion). 

Table 4. Michael addition of ethyl acrylate (14 10 mmol) and ethyl cyanoacetate (2 10 mmol) with either MCM-41 or Si02-supported cesium oxide, cesium or cesium-lanthanum oxide in ethanol under reflux at 30 % mhn ethyl acrylate conversion.

The above is an example of the Guareschi reaction. It is applicable to most dialkyl ketones and to alicyclic ketones (e.., cj/clohexanone, cyclopentanone, etc.). The condensation product (I) is probably formed by a simple Knoe-venagel reaction of the ketone and ethyl cyanoacetate to yield ethyl a-cyano-pp dimethylacrylate (CH3)2C=C(CN)COOC2Hj, followed by a Michael addition of a second molecule of ethyl cyanoacetate finally, the carbethoxyl groups are converted to the cyclic imide structure by the action of ammonia. 

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). 

Michael addition to unsaturated amides. This system (1 equiv. of each) effects Michael addition of ketones, nitro compounds, ethyl cyanoacetate, and diethyl malonate to a,(3-unsaturated amides. Addition to methacrylamides is interesting because the final products are glutarimides or dihydropyridinones. 

The first investigations on iron-catalyzed Michael reactions utilized Fe(acac)3 as catalyst. However, this metal complex is itself catalytically almost inactive. Yields of only up to 63% could be achieved, if BF3OEt2 is used as a co-catalyst [55], Polystyrene-bound Fe(acac)3 catalysts were also reported to give yields up to 63% [56], FeCl3 was used as a co-catalyst for clay-supported Ni(II). Yields achieved with this heterogeneous system ranged from 40 to 98% [57]. The double Michael addition of acrylonitrile to ethyl cyanoacetate is smoothly catalyzed by a complex generated from [Fe(N2) (depe)2] [depe = l,2-bis(diethylphosphano)ethane]. At 23 °C and after 36h, an 88% yield is obtained with 1 mol% of this Fe(0) catalyst [58]. 

The Michael addition of oxygen nucleophiles to vinyl sulfones185 and the addition of dimethyl malonate and ethyl cyanoacetate to a,fl-unsaturated sulfones in the presence of Triton-B and K2CO3 have been studied.186... 

The racemic complex 4 containing 50% of NCN-pincer platinum(II) and 50% of tosylate groups has been tested in catalytic double Michael addition of methyl vinyl ketone and ethyl cyanoacetate using (1 mol %) of catalyst. 

CsX is useful for the simple Knoevenagel reaction of benzaldehyde with ethyl cyanoacetate even a simple NaY is sufficiently basic to form carbamates starting from primary aromatic amines and dialkyl carbonates (35, 36). At contrast CsjO-MCM-41 can also be used for the addition of C02 to epoxides, or for Michael addition of one or two molecules of diethyl malonate on neopentylglycol diacrylate (37, 38) ... 

Rann et al. reported the dramatic influence of a new tailor-made, task-specific, and stable ionic liquid, butyl methyl imidazolium hydroxide ([bmim][OH]), in Michael addition. They have discovered that a task-specific ionic liqnid [bmim][OH] efficiently promoted the Michael addition of 1,3-dicarbonyl compounds, cyano esters, and nitro alkanes to a variety of conjugated ketones, carboxylic esters, and nitriles withont reqniring any other catalyst and solvent (Fig. 12.21) [16]. Very interestingly, all open-chain 1,3-dicarbonyl componnds such as acetylacetone, ethyl ace-toacetate, diethyl malonate, and ethyl cyanoacetate reacted with methyl vinyl ketone and chalcone to give the usual monoaddition products, whereas the same reactions with methyl acrylate or acrylonitrile provided exclusively bis-addition products. 

Michael additions of cyanide anions have been synthetically useful in the past, and such reactivity has been utilised in the development of a phase-transfer catalysed tandem Michael addition-electrophilic alkylation procedure using benzylidene malonate and ethyl (1-methylpropylidene )cyanoacetate. Anions derived from... 

To decide whether disconnection (a) or (b) suggests a synthetically more convenient route, we consider the relative reactivities of single reactants. Benzaldehyde is more reactive with the acetonide anion than with enone TM 4.9b. Therefore, in the first step, aldol condensation is preferred, followed by Michael addition of enone to the carbanion of ethyl cyanoacetate. Consequently, retrosynthesis (b) suggests the preferred synthetic route to TM 4.9 (Scheme 4.30). 

The Michael addition of malononitrile and/or ethyl cyanoacetate (386) to nitrostyrenes has been reported to proceed in water at 80 C over 3h. In the presence of an orthohydroxy group, as in (385), the reaction is complete within 12 h at 40 C and gives rise to 2-amino-2-chromene derivatives (387) as a result of the subsequent cyclization. ... 

The Michael Addition Reaction consists in the addition of the sodio-derivative of ethyl acetoacetate, ethyl malonate or ethyl cyanoacetate to an olefine group... 

A dodecakis(NCN-Pdn) catalyst, synthesized in the group of Van Koten (Figure 4.24), was applied in the a continuous double Michael addition reaction between methyl vinyl ketone (MVK) and ethyl a-cyanoacetate.[34] The reaction was performed in the deadend reactor discussed in paragraph 4.2.1. Two catalytic runs were performed differing in the amount of catalyst and in the applied flow (both increased by a factor 2.5). Both runs showed high productivity for more than 24 h (Figure 4.25). 

In 2007, Chen and co-workers reported the 122-catalyzed (10mol% loading) enantioselective Michael addition [149-152] of ethyl a-cyanoacetate to various electron-rich and electron-deficient trans-chalcones [283]. The reaction was performed for a broad spectrum of chalcones and gave the corresponding adducts in yields of 80-95% and in ee values of 83-95%, but at low sy /a ti-diastereoselectiv-ities as shown for representative products 1-8 in Scheme 6.125. 

Reaction of carbanions with dialkynic ketones, the so-called skipped diynes, can produce pyranones through an initial Michael condensation. It should be noted however that diynones are vulnerable to attack at several sites and that mixed products can be formed. Addition of the anions derived from diethyl malonate and ethyl cyanoacetate to hepta-2,5-diyn-4-one (313 R1 = Me) gives the pyranones (314 R2 = C02Et or CN Scheme 91) (74JOC843). The former carbanion reacts similarly with the diynone (313 R1 = Bun) (68T4285). The second alkyne moiety appears to have little effect on the course of the reaction, which parallels the synthesis of pyranones from monoalkynic ketones. 

The synthesis of 2,2-dimethylsuccinic acid (Expt 5.135) provides a further variant of the synthetic utility of the Knoevenagel-Michael reaction sequence. Ketones (e.g. acetone) do not readily undergo Knoevenagel reactions with malonic esters, but will condense readily in the presence of secondary amines with the more reactive ethyl cyanoacetate to give an a, /f-unsaturated cyanoester (e.g. 15). When treated with ethanolic potassium cyanide the cyanoester (15) undergoes addition of cyanide ion in the Michael manner to give a dicyanoester (16) which on hydrolysis and decarboxylation affords 2,2-dimethylsuccinic acid. 

Three equivalents of FeCl3 are required for the reaction of chalcone 41 j with ethyl cyanoacetate to give a-pyridone derivative 72 (Scheme 8.32) [100]. The reaction is carried out at 140 °C under strongly acidic conditions (FeCl3 dissolved in propionic acid). It proceeds presumably by an initial Michael addition yielding intermediate 73. Excess of iron(III) is required, because this is the oxidizing reagent for the introduction of the second C—C double bond in intermediate 74. 

In contrast with the widespread application of zeolites as solid acid catalysts (see earlier), their use as solid base catalysts received scant attention until fairly recently [121]. This is probably because acid-catalyzed processes are much more common in the oil refining and petrochemical industries. Nonetheless, basic zeolites and related mesoporous molecular sieves can catalyze a variety of reactions, such as Knoevenagel condensations and Michael additions, which are key steps in the manufacture of flavors and fragrances, pharmaceuticals and other specialty chemicals [121]. Indeed, the Knoevenagel reaction of benzaldehyde with ethyl cyanoacetate (Fig. 2.36) has become a standard test reaction for solid base catalysts [121]. 

Cesium-exchanged zeolite X was used as a solid base catalyst in the Knoevenagel condensation of benzaldehyde or benzyl acetone with ethyl cyanoacetate [121]. The latter reaction is a key step in the synthesis of the fragrance molecule, citronitrile (see Fig. 2.37). However, reactivities were substantially lower than those observed with the more strongly basic hydrotalcite (see earlier). Similarly, Na-Y and Na-Beta catalyzed a variety of Michael additions [122] and K-Y and Cs-X were effective catalysts for the methylation of aniline and phenylaceto-nitrile with dimethyl carbonate or methanol, respectively (Fig. 2.37) [123]. These procedures constitute interesting green alternatives to classical alkylations using methyl halides or dimethyl sulfate in the presence of stoichiometric quantities of conventional bases such as caustic soda. 

Alkali-exchanged mesoporous molecular sieves are suitable solid base catalysts for the conversion of bulky molecules which cannot access the pores of zeolites. For example, Na- and Cs-exchanged MCM-41 were active catalysts for the Knoevenagel condensation of benzaldehyde with ethyl cyanoacetate (pKa=10.7) but low conversions were observed with the less acidic diethyl malonate (pKa=13.3) [123]. Similarly, Na-MCM-41 catalyzed the aldol condensation of several bulky ketones with benzaldehyde, including the example depicted in Fig. 2.38, in which a flavonone is obtained by subsequent intramolecular Michael-type addition [123]. 

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