Tandem olefin metathesis/carbonyl olefination

The molybdenum-alkylidene 9 [130] promoted tandem olefin metathesis-carbonyl olefination of olefinic ketones offers an effective synthetic method for cy-cloalkenes (Scheme 4.56 Table 4.19). The complex 9 initially reacts with the ter-... 

Scheme 4.S6. Formation of cycloalkenes from olefinic ketones by the molybdenum-alkylidene promoted tandem olefin metathesis-carbonyl olefination.

Tab. 4.19. Tandem olefin metathesis-carbonyl olefination promoted by the molybdenum-alkylidene 9.

In contrast to the preparative methods described above, a functionalized allyl-boronate can be created from a simpler allylboronate by olefin cross-metathesis [81, 82]. Here, treatment of pinacol allylboronate (2) with various olefin partners, exemplified with styrene in Equation (33), in the presence of ruthenium catalyst 58 smoothly furnishes a more elaborate 3-substituted allylboronate, the cross product 38 [81]. These reactions are noteworthy for their exceptional functional group tolerance allylboronates bearing primary halides can be directly synthesized using this method. Unfortunately, the E/Z selectivity in the formation of the 3-substituted allylboronates is variable. This metathesis approach to allylboronates was employed as the beginning of a tandem cross-metathesis/carbonyl allylation process [82] (discussed in more detail in Section 6.4.1.3). 

Grubbs has reported a similar tandem olefin metathesis-carbonyl olelination process for the preparation of cyclic olefins [31]. In this case, treatment of a keto-olefin with the molybdenum alkylidene 1 at 20°C generates an intermediate alkylidene complex. Under these conditions, competing intermolecular olelination does not occur. However, intramolecular carbonyl olelination of the initially formed alkylidene complex can occur and this results in the formation of a cyclic olefin. This tandem sequence is illustrated by the transformation of keto-olefins... 

Tandem carbonyl olefmation—olefm metathesis utilizing the Tebbe reagent or dimethyl-titanocene is employed for the direct conversion of olefmic esters to six- and seven-mem-bered cyclic enol ethers. Titanocene-methylidene initially reacts with the ester carbonyl of 11 to form the vinyl ether 12. The ensuing productive olefm metathesis between titano-cene methylidene and the cis-1,2 -disubstituted double bond in the same molecule produces the alkylidene-titanocene 13. Ring-closing olefin metathesis (RCM) of the latter affords the cyclic vinyl ether 14 (Scheme 14.8) [18]. This sequence of reactions is useful for the construction of the complex cyclic polyether frameworks of maitotoxin [19]. 

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