Cyclic cyclohexenone

The addition of large enolate synthons to cyclohexenone derivatives via Michael addition leads to equatorial substitution. If the cyclohexenone conformation is fixed, e.g. as in decalones or steroids, the addition is highly stereoselective. This is also the case with the S-addition to conjugated dienones (Y. Abe, 1956). Large substituents at C-4 of cyclic a -synthons direct incoming carbanions to the /rans-position at C-3 (A.R. Battersby, 1960). The thermodynamically most stable products are formed in these cases, because the addition of 1,3-dioxo compounds to activated double bonds is essentially reversible. 

A comprehensive stereochemical study was carried out concerning the reactions of cyclic enones27. The additions to cyclohexenones and -heptenones containing either a 4-methyl or 5-methyl substituent were studied. Surprisingly, the same selectivity trends were found for the six-membered rings as well as for the conformationally much more complex seven-mcmbercd rings. 

Conjugated cyclohexenones [6] have also been easily prepared by combining the cycloaddition of dimethylaminobutadiene 4 and several cyclic and acyclic dienophiles followed by the elimination of the amino group from the cycloadducts under acidic conditions. Scheme 2.3 summarizes some of these results. 

A series of chiral phosphinous amides bearing pendant oxazoline rings (50, Ri=H,Tr R2=H,Tr, 51, Ri=H,Tr R2=H,Tr and 54, Ri=H,Tr R2=H,Tr in Scheme 41) have been used as ligands in the copper-catalyzed 1,4-addition of diethylzinc to enones. Two model substrates have been investigated, the cyclic 2-cyclohexenone and the acyclic trans-chalcone. The addition products are obtained quantitatively in up to 67% ee [171]. 

The only other functional group is the conjugated unsaturated ester. This functionality is remote from the stereocenters and the ketone functionality, and does not play a key role in most of the reported syntheses. Most of the syntheses use cyclic starting materials. Those in Schemes 13.4 and 13.5 lead back to a para-substituted aromatic ether. The syntheses in Schemes 13.7 and 13.8 begin with an accessible terpene intermediate. The syntheses in Schemes 13.10 and 13.11 start with cyclohexenone. Scheme 13.3 presents a retrosynthetic analysis leading to the key intermediates used for the syntheses in... 

A number of examples of this type of photorearrangement have been observed with cyclic and bicyclic molecules. Some photoreactions involving cyclohexenones are as follows ... 

In 1993, Alexakis et al. reported the first copper-catalyzed asymmetric conjugate addition of diethylzinc to 2-cyclohexenone using phosphorous ligand 28 (32% ee).36 An important breakthrough was achieved by Feringa et al. with chiral phosphoramidite (S,R,R)-29 (Figure 1), which showed excellent selectivity (over 98% ee) for the addition of 2-cyclohexenone.37 Since then, efficient protocols for the conversion of both cyclic and acyclic enones, as well as lactones and nitroalkenes, have been developed featuring excellent stereocontrol. 

OO stretch cyclohexenone carbonyl C—C stretch, aromatic and cyclic unsaturation OC stretch, aromatic C-0 stretch, aryl methoxyl... 

Ru complex and (CH3)3COK [(S, R)-34B] is also an excellent catalyst for hydrogenation of the cyclic enone [111]. The allylic alcohol product is a useful intermediate for the synthesis of carotenoid-derived odorants and other bioactive ter-penes. Hydrogenation of 2-cyclohexenone in the presence of the (S,S)-DIOP-Ir catalyst gives (R)-2-cyclohexenol in 25% ee (Fig. 32.43) [137]. 

Axial addition to cyclohexanones.1 Addition of carbanions to cyclic ketones generally favors equatorial products. This preference may result from nonbonded interactions, since Trost et al. now find that the addition of LiCH2CN to cyclohexanones is axial selective (equation I). The preference for axial addition is even higher in the case of cyclohexenones ( 20 1). The axial selectivity of LiCH2CN is... 

When the enol ring is adjacent to a cyclic moiety, then it is possible to achieve very short hydrogen bonds, as in the structure of usnic acid, a natural product found in lichens. A low-temperature X-ray diffraction analysis of this compound showed two enol moieties, one in which a carbon-carbon bond of the enol was part of a cyclohexenone ring, and this had... 

An alternative, in situ source of (Ph3P)CuH can be fashioned from CuCl/PPhs/ TBAF and PhMe2SiH (1.2 equivalents) in DMA, initially made at 0° with the reaction then being run at room temperature [25]. Unhindered acyclic enones require 20 mol% of CuCl, PPhs, and TBAF for best results (Eq. 5.15). Cyclic examples are more demanding, with substituted cyclohexenones such as carvone undergoing reduction when excess reagents are present (1.6 equivalents). Acetylcyclohexene was unreactive to the catalytic conditions above. 

Although the presence of BINOL in the ligands so far discussed has shown itself to be particular effective, modification of the diol moiety provides new classes of ligands for this addition reaction. Alexakis, screening a number of chiral phosphites in the Cu(OTf)2-catalyzed 1,4-addition, showed that an ee of 40% could be obtained for the addition of Et2Zn to 2-cyclohexenone and of 65% for addition to chalcone, by using cyclic phosphites derived from diethyl tartrate [51]. 

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