1.5- Dicarbonyl compounds, synthesis Michael reaction

This sequence illustrates the use of enolates from 1,3-dicarbonyl compounds in Michael reactions they are useful too in alkylations, aldol condensations (Knoevenagel conditions), and reactions with epoxides, as in the synthesis3 of 20. Nowadays they tend to be used if they are readily available, or if the disconnections suggest their use, as in the building of 11 into 18. Examples include the diketone 11 and the six-membered equivalent both used in steroid synthesis, acetoacetates 16 and 19 and the keto-lactones 20, malonic acid 21 and its esters, "Meldrum s acid 22, a very enolisable malonate derivative,4 and the keto-ester 25 formed via its stable enolate 24, by the cyclisation of the diester 23, an intermediate in nylon manufacture. The compounds 11,16, 19, 20 R=H, 21, 22, and 25 are all available commercially. 

Allylic C-H insertions have been used in key steps of the enantioselective synthesis of the pharmaceuticals (+)-ceitedil (26) [21] and (+)-indatraline (27) [22] (Scheme 11). The allylic C-H insertion reaction is an exciting alternative to the Claisen rearrangement as a rapid method for the synthesis of y,c>-unsaturated ester [23 ]. Similarly, the allylic C-H insertion with vinyl silyl ethers generates protected 1,5-dicarbonyl compounds, a complimentary reaction to the Michael addition [24]. Both types of C-H insertion can be achieved with high diastereoselectiv-ity and enantioselectivity [23, 24]. 

Example The lactone (8>, needed for a natural product synthesis, might be made from (6) via epoxide (7) and so a synthesis for (6) was required. Wittlg disconnection reveals a 1,5-dicarbonyl compound (9), best made by Michael addition of a substituted malonate (11) to enone (10). The enone was made by the simple but reliable Grignard route rather than risking a Mannich reaction of unknown regloselectivity. 

On the other hand, the enantioselective 1,4-addition of carbanions such as enolates to linear enones is an interesting challenge, since relatively few efficient methods exist for these transformations. The Michael reaction of p-dicarbonyl compounds with a,p-unsaturated ketones can be catalysed by a number of transition-metal compounds. The asymmetric version of this reaction has been performed using chiral diol, diamine, and diphosphine ligands. In the past few years, bidentate and polydentate thioethers have begun to be considered as chiral ligands for this reaction. As an example, Christoffers et al. have developed the synthesis of several S/O-bidentate and S/O/S-tridentate thioether... 

As depicted in the following scheme, in the presence of sodium iodate and pyridine, several 5,6-dihydroxylated benzofuran derivatives were synthesized via an oxidation-Michael addition of P-dicarbonyl compounds to catechols in a one-pot procedure <06TL2615 06JHC1673>. A novel additive Pummerer reaction of 2-benzo[fc]furan sulfilimines with carbon nucleophiles derived from P-dicarbonyl compounds was also employed to the synthesis of 2,3-disubstituted benzo[b]furans <06TL595>. 

During the coverage period of this chapter, reviews have appeared on the following topics reactions of electrophiles with polyfluorinated alkenes, the mechanisms of intramolecular hydroacylation and hydrosilylation, Prins reaction (reviewed and redefined), synthesis of esters of /3-amino acids by Michael addition of amines and metal amides to esters of a,/3-unsaturated carboxylic acids," the 1,4-addition of benzotriazole-stabilized carbanions to Michael acceptors, control of asymmetry in Michael additions via the use of nucleophiles bearing chiral centres, a-unsaturated systems with the chirality at the y-position, and the presence of chiral ligands or other chiral mediators, syntheses of carbo- and hetero-cyclic compounds via Michael addition of enolates and activated phenols, respectively, to o ,jS-unsaturated nitriles, and transition metal catalysis of the Michael addition of 1,3-dicarbonyl compounds. ... 

Dicarbonyl compounds are widely used in organic synthesis as activated nucleophiles. Because of the relatively high acidity of the methylenic C—H of 1,3-dicarbonyl compounds, most reactions involving 1,3-dicarbonyl compounds are considered to be nucleophilic additions or substitutions of enolates. However, some experimental evidence showed that 1,3-dicarbonyl compounds could react via C—H activations. Although this concept is still controversial, it opens a novel idea to consider the reactions of activated C H bonds. The chiral bifunctional Ru catalysts were used in enantioselective C C bonds formation by Michael addition of 1,3-dicarbonyl compounds with high yields and enantiomeric excesses. ... 

In its original form, the Michael addition consisted on the addition of diethyl malonate across the double bond of ethyl cinnamate in the presence of sodium ethoxide to afford a substituted pentanedioic acid ester. Currently, all reactions that involve a 1,4-addition of stabilized carbon nucleophiles to activated 7i-systems are known as Michael additions. Among the various reactants, enolates derived from p-dicarbonyl compounds are substrates of choice due to their easy deprotonation under mild conditions. Recently, Michael addition-based MCRs emerged as highly potential methodologies for the synthesis of polysubstituted heterocycles in the five- to seven-membered series. 

The competition between Michael addition of a,(3-unsaturated ketones and Diels-Alder reactions involving furan and 2-methylfuran is affected by the catalyst used. Methyl vinyl ketone gives the alkylation product with furan and 2-methylfuran in the presence of silica gel (88TL175). Bis(alkylated) products have also been obtained in reactions of 2-methylene-1,3-dicarbonyl compounds (90H(31)1699). An intramolecular proton catalyzed alkylation reaction of an a,(3-unsaturated ketone provided a straightforward synthesis of norpinguisone (90TL4343) and in the example shown in Equation (4) the cyclization reaction involved an a,(3-y,8-dienone (94TL4887). 

The preparation of (83) (Expt 8.29) is an example of the Hantzsch pyridine synthesis. This is a widely used general procedure since considerable structural variation in the aldehydic compound (aliphatic or aromatic) and in the 1,3-dicarbonyl component (fi-keto ester or /J-diketone) is possible, leading to the synthesis of a great range of pyridine derivatives. The precise mechanistic sequence of ring formation may depend on the reaction conditions employed. Thus if, as implied in the retrosynthetic analysis above, ethyl acetoacetate and the aldehyde are first allowed to react in the presence of a base catalyst (as in Expt 8.29), a bis-keto ester [e.g. (88)] is formed by successive Knoevenagel and Michael reactions (Section 5.11.6, p. 681). Cyclisation of this 1,5-dione with ammonia then gives the dihydropyridine derivative. Under different reaction conditions condensation between an aminocrotonic ester and an alkylidene acetoacetate may be involved. 

According to the classical Hantzsch synthesis of pyridine derivatives, an a,(5-unsaturated carbonyl compound is first formed by Knoevenagel condensation of an aldehyde with a P-dicarbonyl compound. The next step is a Michael reaction with another equivalent of the P-dicarbonyl compound (or its enamine) to form a 1,5-diketone, which finally undergoes a cyclocondensation with ammonia to give a 1,4-dihydropyridine with specific symmetry in its substitution pattern. 

Key Mechanism 22-12 The Claisen Ester Condensation 1071 22-13 The Dieckmann Condensation A Claisen Cyclization 1074 22-14 Crossed Claisen Condensations 1074 22-15 Syntheses Using /3-Dicarbonyl Compounds 1077 22-16 The Malonic Ester Synthesis 1079 22-17 The Acetoacetic Ester Synthesis 1082 22-18 Conjugate Additions The Michael Reaction 1085 Mechanism 22-13 1,2-Addition and 1,4-Addition (Conjugate Addition) 1085... 

As previously mentioned, 1-alkynyltrialkylborates (18) have become increasingly important in the formation of carbon-carbon bonds via attack of electrophiles. However, such complexes cannot react with simple Qc,P-unsaturated carbonyl compounds such as methyl vinyl ketone, because of their weak electrophilicity. Recently it was ascertained that ,P-unsaturated carbonyl compounds react with 18 via a Michael-type reaction in the presence of titanium tetrachloride, and the usual alkaline hydrogen peroxide oxidation leads to the synthesis of 5-dicarbonyl compounds... 

The 1,5-diketone foimation by the Michael addition of allylsilane (48) to a, -unsaturated ketones was applied to the synthesis of (-i-)-nootkatone." Reaction of the keto group of keto aldehyde (58) with allyl Grignaid reagent and dehydration gave the diene aldehyde (59). The selective oxidation of the terminal double bond afforded the 1,5-dicarbonyl compound (60), which is not stable and converted directly to pyridines and phenols (Scheme 18)." ... 

Michael addition of metal enolates to a,/3-unsaturated carbonyls has been intensively studied in recent years and provides an established method in organic synthesis for the preparation of a wide range of 1,5-dicarbonyl compounds (128) under neutral and mild conditions . Metal enolates derived from ketones or esters typically act as Michael donors, and a,-unsaturated carbonyls including enoates, enones and unsaturated amides are used as Michael acceptors. However, reaction between a ketone enolate (125) and an a,/3-unsaturated ester (126) to form an ester enolate (127, equation 37) is not the thermodynamically preferred one, because ester enolates are generally more labile than ketone enolates. Thus, this transformation does not proceed well under thermal or catalytic conditions more than equimolar amounts of additives (mainly Lewis acids, such as TiCU) are generally required to enable satisfactory conversion, as shown in Table 8. Various groups have developed synthons as unsaturated ester equivalents (ortho esters , thioesters ) and /3-lithiated enamines as ketone enolate equivalents to afford a conjugate addition with acceptable yields. 

In recent years, many chiral catalysts for the enantioselective synthesis of optical active 1,5-dicarbonyl compounds have been developed, such as chiral crown ethers with potassium salt bases and chiral palladium complexes, including bimetallic systems. Nakajima and coworkers reported on enantioselective Michael reactions of S-keto esters to a,/3-unsaturated carbonyl compounds in the presence of a chiral biquinoline N,N dioxide-scandium complex, which catalyzed the additions in high yields and with enan-tioselectivities up to 84% ee . Kobayashi and coworkers found that the combination of Sc(OTf)3 with the chiral bipyridine ligand 149 (equation 41) was also effective as a chiral catalyst for asymmetric Michael additions of 1,3-dicarbonyl compounds 147 to a,/3-unsaturated ketones 148. The corresponding Michael adducts 150 were obtained in good to high yields with excellent enantiomeric excesses in most cases (Table 10). 

When the product of a Michael reaction is also a p-keto ester, it can be hydrolyzed and decar-boxylated by heating in aqueous acid, as discussed in Section 23.9. This forms a 1,5-dicarbonyl compound. Figure 24.7 shows a Michael reaction that was a key step in the synthesis of estrone, a female sex hormone. 

Michael reactions of silyl enolates or ketene silyl acetals with a, -unsaturated carbonyl compounds are among the most important carbon-carbon bond-forming processes in organic synthesis. Sc(OTf)3 was found to be effective [4], and the reactions proceeded smoothly in the presence of a catalytic amount of Sc(OTf)3, under extremely mild conditions, to give the corresponding 1,5-dicarbonyl compounds in high yields after acid work-up (Eq. 2). Silyl enolates derived from ketones, thioesters, and esters were applicable, and no 1,2-addition products were obtained. The products could, furthermore, be isolated as synthetically valuable silyl enol ethers (I) when acid-free work-up was performed. The catalyst could be recovered almost quantitatively and could be re-used. 

The Michael reaction of 1,3-dicarbonyl compounds with an enone on the surface of Cu " montmorillonite provides 1,5-dioxo synthons (Scheme 5.38) that are useful intermediates in organic synthesis.The catalyst was recycled for several runs the presence of solvent retards the reactions. 

The Knoevenagel condensation is the method of choice for the preparation of a,p-unsaturated dicarbonyl compounds and related compounds and only a few alternative methods have been developed. However, with the traditional Knoevenagel condensation there are problems with the reactivity of ketones, with the competitive Michael addition occuring in the reaction of some active methylene compounds. There is also a problem with steieocontrol in the synthesis of Knoevenagel products from unsymmetrical 1,3-dicarbonyl compounds. An alternative method is the addition of Grignard reagents to vinylogous carbamates (see Section 11.2.6). Another possibility is the reaction of a metal ketimate with malonodini-trile to yield ylidenemalonodinitriles (see Section 11.3.1.7). ... 

The 3-component condensation for synthesis of 3-acy 1-4-ary 1-1,4-dihydropyridines from amines, (3-dicarbonyl compounds and enals proceeds from enamine formation, Michael reaction and cyclodehydration is amenable to asymmetric induction, such as using ent-octahydro-lB. ... 

Michael and aldol reaction tandet dicarbonyl compounds that contain one (aldol reaction) if the second carbonyl j synthesis of 2-hydroxycyclohexanecarbox step from 7-keto-2-alkenamides. The land... 

A great variety of methods is available for the ring synthesis of pyridines the most obvious approach is to construct a 1,5-dicarbonyl compound, preferably also having further unsaturation and allow it to react with ammonia, addition of which at each carbonyl group, with losses of water, producing the pyridine. 1,4-Dihydropyridines, which can easily be dehydrogenated to the fully aromatic system, result from the interaction of aldehydes with two mol equivalents of 1,3-diketones (or 1,3-keto-esters, etc.) and ammonia aldol and Michael reactions and addition of ammonia at the termini, produces the heterocycle. 

The Michael addition reaction is one of the most important carbon-carbon bond forming reactions in organic synthesis, and several examples using polymer-supported reagents have been reported. For example, Bensa et al found that the Michael addition reaction of 1,3-dicarbonyl compounds with activated olefins as a Michael acceptor could be efficiently catalysed by PS-BEMP [35] (Scheme 6.6). The procedure does not require dry solvents or an inert atmosphere, and filtration of the catalyst gives substantially pure products. It is also... 

This reaction was first reported by Krohnke et al. in 1961. It is the synthesis of 2,4,6-trisubstituted pyridine derivatives involving the formation of pyridinium ylide from pyridine and a-bromoketone, which undergoes the 1,4-Michael addition to an a, -unsaturaled compound to form 1,5-dicarbonyl compounds and cyclizes with ammonium acetate. Therefore, it is generally known as the Krohnke pyridine synthesis or Krohnke reaction. In this reaction, the intermediate 1,5-dicarbonyl compounds do not need to be isolated from reaction mixture. Because three different substituents can be introduced into pyridine ring, this reaction becomes the ideal model for combinatorial synthesis, and a library pool containing pyridine from 9 to over 200 has been generated by this reaction. 

Nucleophilic additions to the carbon-carbon double bond of ketene dithioacetal monoxides have been reported [84-86]. These substrates are efficient Michael acceptors in the reaction with enamines, sodium enolates derived from P-dicarbonyl compounds, and lithium enolates from simple ester systems. Hydrolysis of the initiEil products then led to substituted 1,4-dicarbonyl systems [84]. Alternatively, the initial product carbanion could be quenched with electrophiles [85]. For example, the anion derived from dimethyl malonate (86) was added to the ketene dithioacetal monoxide (87). Regioselective electrophilic addition led to the product (88) in 97% overall yield (Scheme 5.28). The application of this methodology to the synthesis of rethrolones [87] and prostaglandin precursors [88] has been demonstrated. Recently, Walkup and Boatman noted the resistance of endocyclic ketene dithioacetals to nucleophilic attack [89]. 

A highly enantioselective organocatalytic Michael addition of 4-hydroxycouma-rines and related compounds to a,p-unsaturated ketones has been also achieved using imidazolidine catalyst 137 [213]. The reaction, which gives high yields and enantioselectivities for a wide range of cyclic 1,3-dicarbonyl compounds and enones, has been successfully employed for the asymmetric synthesis of the anticoagulant warfarin (Scheme 2.78) and derivatives [213], With respect to the reaction mechanism, very recent studies have demonstrated that the truly active catalyst in the process was the chiral diamine 138, which is formed in catalytic amounts under the reaction conditions by reaction with the hydroxycoumarine (Schane 2.79)... 

Another asymmetric domino Michael/alkylation methodology was independently developed by Xie et al. [149] and Rueping et al. [150] for the synthesis of a range of chiral 2,3-dihydrofurans from reaction of a-bromonitroalkenes with 1,3-dicarbonyl compounds. In both cases, the catalysts were chiral bifunctional thioureas (30mol%) associated to a base, such as diisopropylethylamine (DIPEA) or tetramethylethylenediamine (TMEDA). For example, the reaction of bicyclic 1,3-dicarbonyl compounds, such as 4-hydroxyl(thio)coumarins, led to the corresponding tricyclic 2,3-dihydrofurans in yields of 89-98%, general... 

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