Intramolecular reactions endocyclic compounds

The Cu(I)-catalyzed decomposition of (alkynyloxysilyl)diazoacetates 119 furnishes the silaheterocycles 120 and/or 121 (equation 30) in modest yield63. In these cases, the photochemical extrusion of nitrogen from 119 does not lead to defined products and the thermal reaction is dominated by the 1,3-dipolar cycloaddition ability of these diazo compounds. In mechanistic terms, carbene 122 or more likely a derived copper carbene complex, is transformed into cyclopropene 123 by an intramolecular [1 + 2] cycloaddition to the triple bond. The strained cyclopropene rearranges to a vinylcarbene either with an exo-cyclic (124) or an endocyclic (125) carbene center, and typical carbene reactions then lead to the observed products. Analogous carbene-to-carbene rearrangements are involved in carbenoid transformations of other alkynylcarbenes64. 

The reaction of 1-disilagermirene 22 with ketones is similar to the benzaldehyde case. Thus, reaction with butane-2,3-dione gives a final bicyclic product 41, which also has a norbornane type skeleton (Scheme 15, Figure 13)50. Formation of this compound can be reasonably explained by the initial [2 + 2] cycloaddition of one carbonyl group across the Si=Si bond to form the three- and four-membered ring bicyclic compound 42, followed by the isomerization of disilaoxetane 42 to an enol ether derivative 43. The intramolecular insertion of the second carbonyl group into the endocyclic Si—Ge single bond in 43 completes this reaction sequence to produce the final norbornane 41. In this case, C=0 insertion occurred into the Si—Ge bond rather than the Si—Si bond, which is reasonable due to the weakness of Si—Ge bond. 

The anions generated from substituted ethyl acetylacetates 15 and related compounds reacted with (1 -ethoxycarbonylcyclopropyl)triphenylphosphonium tetrafluoroborate (14) to give diethyl cyclopent-l-ene-l,3-dicarboxylates 16 and 17 via 1,5-addition, ring opening with ylide formation, and intramolecular Wittig reaction.The reaction products were obtained in high yields. The location of the endocyclic double bond depended on the experimental conditions. 

Elimination of selenoxides takes place through an intramolecular, syn elimination pathway. The carbon—hydrogen and carbon—selenium bonds are coplanar in the transition state. The reaction is highly traws-selective when acyclic a-phenylseleno carbonyl compounds are employed. The formation of conjugated double bonds is favored. Endocyclic double bonds tend to predominate over exocyclic ones, unless there is no syn hydrogen available in the ring. Some examples of selenoxide-mediated syn eUmination reaction are given in Scheme 6.23. 

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