Subject reactions with enones

Scheme 52) [91], The (3-indolylacrylate 240 was thus subjected to a Diels-Alder reaction with enone 239 (prepared via a Diels-Alder cycloaddition of the diene 237 and cyclopentenone 238), thereby providing the endo product 241 in 72% yield and... 

Fig (14) Olefin (107) has been converted to cyclic ether (114) by standard reactions. Its transformation to enone (115) is accomplished by annelation with methyl vinyl ketone and heating the resulting diketone with sodium hydride in dimethoxyethane. The ketoester (116) is subjected to Grignard reaction with methyllithium, aromatization and methylation to obtain the cyclic ether (117). Its transformation to phenolic ester (119) has been achieved by reduction, oxidation and esterification and deoxygenation. 

By derivatizing an a,p-unsaturated acid into the mono ester of chiral 1,1 -bi-8,8 -naphthol the reaction with lithium dialkylcuprates leads to saturated ketones containing chirality centers at the p-carbon atoms." Consecutive 1,4-addition and 1,2-addition account for this result. The alkyl transfer to enones from Grignard reagents under copper catalysis is subject to chiral modification, e.g., by the introduction of 56" or 57." ... 

Conjugated ketones (enones) fonn more stable complexes with Lewis acids compared to saturated ketones (alkanones). This leads to preferential functionalization of enones when Eu(fod)3 [52] and Bu2Sn(OTf)T [35] are subjected to chemical transformations (Schemes 2-22 and 2-23). The exposure of the thiolamine (Scheme 2-23) to a mixture of enone and alkanone units in the steroid also shows similar preference for the reaction with the enone [53]. 

The reaction of an olefin with a 1,3-diketone enol, known as the de Mayo reaction [116], is an important member of the [23-2] photocycloaddition reaction family. This and related processes were discussed by Sato et al. [117]. 1,3-Dioxi-nones (62) react with ethylene to give cyclobutane products. (Kaneko et al. [118] and Demuth et al. [119] have written reviews on this subject.) The intermolecular reactions of olefins with enones, carried out by Organ et al. [120], are complementary to the work on spirodioxinone derivatives (e.g., 63) by Sato et al. [121]. Reaction of enone 64 with cyclohexene led to a mixture of seven products, with the all-cis isomer formed in 32% yield. However, higher selectivity was seen for the reaction with a protected cyclohexenone (65), which afforded the all-cis isomer (66) in 54% yield, and reaction with cyclopentene (67), which gave 68 as a single product in 90% yield, as shown in Scheme 17 (also see Fig. 8). 

An improved synthesis of glutinosone (1) was also accomplished by Masamune and coworkers6 and this was based on procedure developed by Dastur7,8 for the synthesis of sesquiterpenes nootkatone. (Scheme 2) Diels-Alder reaction of 3,6-dihydro-3,5-dimethyl anisole with methyl acrylate in absence of Lewis acids afforded a 1 3 mixture of esters (17) and (18) which were converted to a,(3-unsaturated aldehydes (19) in 77% yield by oxidation with selenium (IV) oxide in dioxane. Wittig reaction of aldehydes under the usual condition yielded the dienes (20) in 63% yield which on being subjected to Grignard reaction with an excess of methyllithium produced tettiary alcohols (21) in quantitative yield. This on treatment with formic acid at room temperature gave bicyclic enone (22) and its formate (23) in 45% and 41% yield respectively. Formates (23) were hydrolyzed to enone (22) in 88% yield. 

A study of the intramolecular (2+2)-addition in the enones (77) has been reported. The outcome of the addition is both temperature and substituent dependent. Thus irradiation of the enone (77a) at 0°C in acetonitrile with benzophenone as the sensitizer yields a single adduct (78) in 90% yield after only 35 min. irradiation. The photocycloaddition of the enone (77b) at lower temperatures yields a mixture of (78) and (79) in a ratio of 1.8 1. The other derivatives (77c,d) afford only one product identified as (79). The products obtained from the cycioaddition can be cleaved to spiroacetals. The synthetic potential of the intramolecular (2+2)-cycloaddition reaction of enones continues to be exploited. In a recent example example the cycioaddition of the enone (80) affords the product (81) which is then subjected to ring-opening and further transformation to provide a path to the natural product (+)-ligudentatol (82). " ... 

Several reviews have been devoted to the subject of, among other cycloaddition reactions, (2 + 2)-cycloaddition reactions to enones. Within these articles the additions of alkynes has been dealt with. Specifically, a short review has discussed the cycloaddition reactions of enones with alkynes. ... 

Fig. (10). The conversion of the Wieland-Miescher ketone (1) to the cyclopropane (113) is described. This on heating afforded tricyclic anone (114). Hydroxylation of the enone (114) gave the diol (115), which was protected as acetonide (116), on subjection to reaction with methyllithium, dehydration followed by acid treatment the acetonide (116) yielded the cis-sativenediol (118).

A hydrophobic polymer-supported scandium(III) catalyst was also successfully used in the Michael reaction of unsaturated ketones with silyl enol ethers. Recently, an amphiphilic resin-supported rhodium/phosphine complex was used as catalyst in the 1,4-addition of various boronic acids to enones in water at 25°C. High yields were obtained and the catalyst was easily separated and subjected to a second and third round of reactions with no decrease in activity. ... 

Most workers have preferred to prepare stable derivatives prior to analysis. For example, cyclopropene fatty acids can be subjected to hydrogenation, or reaction with silver nitrate [449] or methanethiol [746]. Silver nitrate in anhydrous methanol reacts with cyclopropene rings in about 2 hours at 30 C to form predominantly methoxy ether but with some enonic derivatives, which appear as twin peaks (because of reaction on either side of the ring) on analysis by GC [99,241,281]. An application of this procedure to the analysis of kapok seed oil is illustrated in Figure 5.14. Alternatively, a brief reaction with hydrazine will selectively reduce the cyclopropene compounds to the more stable cyclopropanes by examination by GC before and after the reaction, the small amounts of natural cyclopropane components can also be identified [194]. 

More practically, 2-pyridyl-substituted vinylsilanes themselves can be directly subjected to the reactions with various electrophiles. For example, treatment of 2-pyridyl-substituted vinylsilanes with acid chlorides in the presence of aluminum chloride affords the corresponding a, 0-unsaturated enones (eq 5). The reaction of 2-pyridyl-substituted vinylsilanes with bromine and subsequent treatment with sodium methoxide affords the corresponding vinyl bromides (eq 6). ... 

The resultant alkenyl(2-pyridyl)silanes can be subjected to further transformations. For example, the treatment of alkenyl (2-pyridyl)silanes with aryl iodides in the presence of tetrabutyl-ammonium fluoride and palladium catalyst affords substituted oleflns in good yields (eq 3). This cross-coupling reaction is suggested to proceed through the intermediacy of a highly reactive alkenylsilanol. The treatment of alkenyl(2-pyridyl)silanes with tetrabutylammonium fluoride effects simple protodesilyl-ation (eq The reaction with acetyl chloride in the presence of aluminum chloride affords the corresponding Q ,/3-unsaturated enones (eq 5). ... 

In the third sequence, the diastereomer with a /i-epoxide at the C2-C3 site was targeted (compound 1, Scheme 6). As we have seen, intermediate 11 is not a viable starting substrate to achieve this objective because it rests comfortably in a conformation that enforces a peripheral attack by an oxidant to give the undesired C2-C3 epoxide (Scheme 4). If, on the other hand, the exocyclic methylene at C-5 was to be introduced before the oxidation reaction, then given the known preference for an s-trans diene conformation, conformer 18a (Scheme 6) would be more populated at equilibrium. The A2 3 olefin diastereoface that is interior and hindered in the context of 18b is exterior and accessible in 18a. Subjection of intermediate 11 to the established three-step olefination sequence gives intermediate 18 in 54% overall yield. On the basis of the rationale put forth above, 18 should exist mainly in conformation 18a. Selective epoxidation of the C2-C3 enone double bond with potassium tm-butylperoxide furnishes a 4 1 mixture of diastereomeric epoxides favoring the desired isomer 19 19 arises from a peripheral attack on the enone double bond by er/-butylper-oxide, and it is easily purified by crystallization. A second peripheral attack on the ketone function of 19 by dimethylsulfonium methylide gives intermediate 20 exclusively, in a yield of 69%. 

Under similar conditions, employing a cationic Rh complex (10mol%) and hydrogen (1 atm), the aldehyde-enone 17 was subjected to the cycli-zation to give the cyclic aldol product 18 in 89% with czs-selectivity up to 10 1 (Scheme 19) [31]. Use of (p-CF3Ph)3P as ligand accelerated the reaction... 

Palladium-catalyzed bis-silylation of methyl vinyl ketone proceeds in a 1,4-fashion, leading to the formation of a silyl enol ether (Equation (47)).121 1,4-Bis-silylation of a wide variety of enones bearing /3-substituents has become possible by the use of unsymmetrical disilanes, such as 1,1-dichloro-l-phenyltrimethyldisilane and 1,1,1-trichloro-trimethyldisilane (Scheme 28).129 The trimethylsilyl enol ethers obtained by the 1,4-bis-silylation are treated with methyllithium, generating lithium enolates, which in turn are reacted with electrophiles. The a-substituted-/3-silyl ketones, thus obtained, are subjected to Tamao oxidation conditions, leading to the formation of /3-hydroxy ketones. This 1,4-bis-silylation reaction has been extended to the asymmetric synthesis of optically active /3-hydroxy ketones (Scheme 29).130 The key to the success of the asymmetric bis-silylation is to use BINAP as the chiral ligand on palladium. Enantiomeric excesses ranging from 74% to 92% have been attained in the 1,4-bis-silylation. 

In order to gain further insight into the reaction mechanism, the indicated oxygen-tethered keto-enone was subjected to basic hydrogenation conditions under 1 atmos. elemental deuterium. Deuterium incorporation is observed at the former enone / -position exclusively. In addition to mono-deuterated material (81% composition), doubly-deuterated (8% composition) and non-deuterated materials (11% composition) are observed. These data suggest reversible hydro-metallation in the case of keto-enone substrates. Consistent with the mechanism depicted in Scheme 22.4, deuterium is not incorporated at the a-position of the aldol product [24b] (Scheme 22.5). 

Rate and equilibrium constants have been determined for the aldol condensation of a, a ,a -trifluoroacetophenone (34) and acetone, and the subsequent dehydration of the ketol (35) to the cis- and fraw -isomeric enones (36a) and (36b)." Hydration of the acetophenone, and the hydrate acting as an acid, were allowed for. Both steps of the aldol reaction had previously been subjected to Marcus analyses," and a prediction that the rate constant for the aldol addition step would be 10" times faster than that for acetophenone itself is borne out. The isomeric enones are found to equilibrate in base more rapidly than they hydrate back to the ketol, consistent with interconversion via the enolate of the ketol (37), which loses hydroxide faster than it can protonate at carbon. 

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