Enones applications

Coutrot, P, and Grison, C., General synthesis of a-fluoro-P-ketophosphonate precursors of a-fluoro enones. Application to the pyrethrene series. Tetrahedron Lett., 29, 2655, 1988. 

Murray LM, O Brien P, Taylor RJK (2003) Stereoselective Reactions of a (-)-Quinic Acid-Derived Enone Application to the Synthesis of the Core of Scyphostatin. Org Lett 5 1943... 

Caine, D. and Gupton, J.T., III, Photochemical rearrangements of cross-conjugated cyclohexadi-enones. Application to the synthesis of (-)-4-epiglobulol and (-i-)-4-epiaromadendrene, J. Org. Chem., 40, 809,1975. 

Acetoxy-l,7-octadiene (40) is converted into l,7-octadien-3-one (124) by hydrolysis and oxidation. The most useful application of this enone 124 is bisannulation to form two fused six-membered ketonesfl 13], The Michael addition of 2-methyl-1,3-cyclopentanedione (125) to 124 and asymmetric aldol condensation using (5)-phenylalanine afford the optically active diketone 126. The terminal alkene is oxidi2ed with PdCl2-CuCl2-02 to give the methyl ketone 127 in 77% yield. Finally, reduction of the double bond and aldol condensation produce the important intermediate 128 of steroid synthesis in optically pure form[114]. 

In principle, this approach is applicable to the formation of other enones, but superior alternatives are available. 

Besides a polymerization of the Michael acceptor, a double alkylation of the starting ketone, by reaction with a second Michael acceptor molecule, may take place as a side reaction, and thus further reduce the yield. The polymerization of the enone 2 as well as the double alkylation of the starting ketone can be avoided by application of a modern procedure for the Robinson annulation that uses an organotin triflate as catalyst." ... 

In the Michael addition of achiral enolates and achiral Michael acceptors the basic general problem of simple diastereoselection (see Section D.1.5.1.3.2.), as described in Section 1.5.2.3.2. is applicable. Thus, the intermolecular 1,4-addition of achiral metal enolates to enones, a.jS-unsat-urated esters, and thioamides, results in the formation of racemic syn-1,2 and/or anti-3,4 adducts. 

If the enone is part of a decalone system, i.e., a / - and an y-substituent are present, on reaction with lithiated areneacetonitriles in THF the exclusive formation of (Tv-substituted decalones is observedl26. The diastereoselectivity at the exocyclic stereogenic center is, however, poor. Applications in the synthesis of anthracyclines are given in the literature127,12S. 

The diastereoselective intramolecular Michael addition of /(-substituted cyclohexcnoncs results in an attractive route to ra-octahydro-6//-indcn-6-ones. The stereogenic center in the -/-position of the enone dictates the face selectivity, whereas the trans selectivity at Cl, C7a is the result of an 6-exo-trig cyclization. c7.v-Octahydro-5//-inden-5-ones are formed as the sole product regardless of which base is used, e.g., potassium carbonate in ethanol or sodium hydride in THF, under thermodynamically controlled conditions139 14°. An application is found in the synthesis of gibberellic acid141. 

Diels-Alder reaction of the furan derivative 148 with homochiral bicyclic enone 149 is the key step [56] in the total synthesis of the diterpenes jatropho-lone A and B, 151 and 152, respectively, isolated from Jatropha gossypiifolia L [57], Initial efforts to carry out the cycloaddition between 148 and 149 under thermal or Lewis-acid conditions failed due to diene instability. Application of 5kbar of pressure to a neat 1 1 mixture of diene and dienophile afforded crystalline 150 with the desired regiochemistry (Scheme 5.23). Subsequent aromatization, introduction of the methylene group, oxidation and methylation afforded (-l-)-jatropholones 151 and 152. 

Ferrocen-l,l -diylbismetallacycles are conceptually attractive for the development of bimetal-catalyzed processes for one particular reason the distance between the reactive centers in a coordinated electrophile and a coordinated nucleophile is self-adjustable for specific tasks, because the activation energy for Cp ligand rotation is very low. In 2008, Peters and Jautze reported the application of the bis-palladacycle complex 56a to the enantioselective conjugate addition of a-cyanoacetates to enones (Fig. 31) [74—76] based on the idea that a soft bimetallic complex capable of simultaneously activating both Michael donor and acceptor would not only lead to superior catalytic activity, but also to an enhanced level of stereocontrol due to a highly organized transition state [77]. An a-cyanoacetate should be activated by enolization promoted by coordination of the nitrile moiety to one Pd(II)-center, while the enone should be activated as an electrophile by coordination of the olefinic double bond to the carbophilic Lewis acid [78],... 

Tandem conjugate addition-alkylation has proven to be an efficient means of introducing groups at both a- and (3-positions at enones.307 As with simple conjugate addition, organocopper reagents are particularly important in this application, and they are discussed further in Section 8.1.2.3. 

There have been many applications of conjugate additions in synthesis. Some representative reactions are shown in Scheme 8.2. Entries 1 and 2 are examples of addition of lithium dimethylcuprate to cyclic enones. The stereoselectivity exhibited in Entry 2 is the result of both steric and stereoelectronic effects that favor the approach syn to the methyl substituent. In particular, the axial hydrogen at C(6) hinders the a approach. 

Elegant application of the Michael addition of nitroalkanes to enones followed by denitration is demonstrated in the synthesis of (+) dihydromevinol, (see Scheme 7.9).75... 

Polycyclic oxetanes are obtained in good yields in intramolecular carbonyl-olefin cycloadditions, in an analogous way as the corresponding alicyclic systems are formed in intramolecular enone-olefin additions. Two applications are given in (4.78)492) and in (4.79)493). 

The alkylation of olefinic G-H bonds proceeds when conjugated enones are employed in the ruthenium-catalyzed reaction with alkenes, as shown in Equation (16).1 7 Among the acylcyclohexenes, 1-pivaloyl-l-cyclohexene exhibits a high reactivity and the presence of an oxygen atom at the allylic position in the six-membered ring increases the reactivity of the enones. Some terminal olefins, for example, triethoxyvinylsilane, allyltrimethylsilane, methyl methacrylate, and vinylcyclohexane, are applicable for the alkylation of the olefinic C-H bonds. Acyclic enones also undergo this alkylation. 

The application of organostannanes in rhodium-catalyzed 1,4-addition reactions was first studied by Oi and co-workers.137,137a The treatment of enones or enolates with a slight excess of aryltrimethylstannane and catalytic amounts of [Rh(COD)(MeCN)2]BF4 generates the conjugate addition products in good yields. The use of protic additives enhanced the yield of the reaction (Scheme 48).138... 

Though several intermolecular catalytic reductive aldol additions are reported, corresponding reductive cyclizations have received less attention. The first reported reductive aldol cyclization involves use of a (diketonato)cobalt(ll) precatalyst in conjunction with PhSiHj as terminal reductant.48,486 The reductive cyclization is applicable to aromatic and heteroaromatic enone partners to form five- and six-membered rings. As demonstrated by the reductive cyclization of mono-enone mono-aldehyde 65a to afford aldol 65b, exceptionally high levels of ty -diastereoselectivity are observed. Interestingly, exposure of the substrate 65a to low-valent nickel in the presence of excess Et2Zn provides the isomeric homoaldol cyclization product 65c via reductive coupling to the enone /3-position (Scheme 43).47a... 

In the case of 3-substituted cyclopentanones or cycloheptanones, derivatization with diamine is slower, and the reaction time ranges from a few minutes to several hours. This method is not applicable to acyclic ketones and enones. 

Phosphite compounds, which have been discussed in the context of their application in asymmetric hydrogenation reactions (see Section 6.1.2.6), can also be used to effect the copper salt-mediated asymmetric conjugate addition of diethylzinc to enones.74 As shown in Scheme 8-33, in the presence of diphosphite 92 and copper salt [Cu(OTf)2], the asymmetric conjugate addition proceeds smoothly, giving the corresponding addition product with high conversion and ee. In contrast, the monophosphite 93 gave substantially lower ee. 

The method is applicable to a wide range of substrates. Table 4.4 gives various a, (3-enones that can be epoxidized with the La-(R)-BINOL-Ph3PO/ROOH system. The substituents (R1 and R2) can be either aryl or alkyl. Cumene hydroperoxide can be a superior oxidant for the substrates with R2 = aryl group whereas t-butyl hydroperoxide (TBHP) gives a better result for the substrates with R1 = R2 = alkyl group. 

Coupling of vinyl iodides with aldehydes (12, 137). Further study1 of this 1,2-addition of alkenylchromium compounds to aldehydes to form allylic alcohols indicates that the reaction is applicable to a-alkoxy and a,(i-bisalkoxy aldehydes by use of a solvent other than DMF, which can promote elimination to an enal. A wide number of other functional groups can also be accommodated. Both vinyl iodides and p-iodo enones can be used as precursors to the alkenylchromium reagent. The reaction is only modestly diastereoselective, but the stereochemistry of a disubstituted vinyl iodide is retained. 

Conjugate hydrogenation. The combination of zinc and NiCl2 (9 1) effects conjugate reduction of a,(3-enones in an aqueous alcohol in which both the enone and product are completely soluble. Ultrasound increases the rate and the yields. Presumably the salt is reduced to a low-valent form that is absorbed on the zinc. No reduction takes place with a 1 1 Zn-NiCl2 couple. The method is not applicable to a,(3-unsaturated enals. Isolated double bonds are also reduced by this method, but this hydrogenation can be inhibited by addition of ammonia or triethylamine. 

---