Isomerism regioisomers

Cyclic alkenes give different regioisomers depending on the reaction conditions owing to double bond isomerization caused by syii elimination of Pd—H species and its readdition. The following three reaction conditions were tested for the reaction of cycloheptene (35)[18,38] ... 

The decarboxylation-allylation of allyl enol carbonates proceeds smoothly[450]. The isomeric enol carbonates 699 and 701 of the enone 698 undergo regiospecific allylation, giving the regioisomers 700 and 702 selectively. 

Curran s synthesis of ( )-A9(l2)-capnellene [( )-2] is detailed in Schemes 30 and 31. This synthesis commences with the preparation of racemic bicyclic vinyl lactone 147 from ( )-norbomenone [( )-145] by a well-known route.61 Thus, Baeyer-Villiger oxidation of (+)-145 provides unsaturated bicyclic lactone 146, a compound that can be converted to the isomeric fused bicyclic lactone 147 by acid-catalyzed rearrangement. Reaction of 147 with methylmagne-sium bromide/CuBr SMe2 in THF at -20 °C takes the desired course and affords unsaturated carboxylic acid 148 in nearly quantitative yield. Iodolactonization of 148 to 149, followed by base-induced elimination, then provides the methyl-substituted bicyclic vinyl lactone 150 as a single regioisomer in 66% overall yield from 147. 

Cocyclizations of internal alkynes and carbene complexes 57 with larger substituents R1 (e.g., R z Pr) not only lead to formation of an increased proportion of the regioisomers 60b, but also to that of the isomeric cyclopentadi-enes 61, which would result from 60a by 1,2-migration of the dimethylamino... 

In this context, the second-stage nitration of 1-mononitronaphthalene was investigated. The isomeric ratio of the two regioisomers, 1,5-dinitro- to 1,8-dinitro-naphthalene, was constant at 1 3.5 for macroscopic batch reactors, whereas it changes to 1 2.8 in micro reactors [166]. 

Regioisomers Isomeric compounds related to each other by the juxtaposition of functional groups. 

From the copper-catalyzed reaction of methyl 2-diazo-3-oxobutyrate 57 a with Z-3-methoxystyrene, dihydrofuran 59 (formed with retention of olefin configuration) and butadienol 60 result130). Such an acyclic by-product also occurs when benzofuran is the cycloaddition partner. In that case, however, regioisomers 61 and 62, arising from the connection of the former diazo carbon with either the 2- or 3-position of the heterocycle, are obtained similarly, two isomeric dihydrofurans 63 and 64 are formed under Cu(hfacac)2 catalysis130). 

McCleland has reported that 3-phenylpropan-l-ol [125] and 3-(p-methyl-phenyl)propan-l-ol 99 [126] cyclize to chromans when oxidized by the radical anion SO4, generated by redox decomposition of S20 with Fe. The intermediate arene radical cation 100 is attacked by the nucleophilic hydroxy group. Whereas 1,6-cyclization yields 7-methylchroman 102, 1,5-cyclization with subsequent C-migration leads to the regioisomer 6-methylchroman 105. A dependence of the isomeric ratio and the combined yields to the pH value is determined. While 7-methylchroman 102 is the main product over a wide pH range, 6-methylchroman 105 is only formed at low pH. When the pH is lowered, the combined yields decrease due to the formation of an a-oxidized non-cyclized product. 

Reaction of the regioisomers of tetrahydrophosphinine oxide (51) with Na0H-H20-CHCl3 under phase-transfer conditions was found to afford tetrahydrophosphepine oxides (52) through an unexpected path involving isomerization of (51) and cyclopropanation via Michael addition of CCls. (Scheme 21). 

The orientation on addition of asymmetric electron-rich olefins has also been studied by Padwa et al. (83JOC2330). Only one regioisomer could be isolated from such reactions. These reactions were assumed to be products resulting from the attachment of the olefinic electron-rich moiety to the exocyclic nitrogen. This assignment was based on H-NMR, which revealed the triazine H-4 in 96 at 88.5. This, however, does not rule out isomeric 97, as Ege and Gilbert (81JHC675) reported a shift of 8.7 for H-3 in a system believed to be a 3-unsubstituted-4-arylpyrazolo[5,l-c]-l,2,4-triazine (Scheme 13). 

In addition, we should note that data of H, NMR spectroscopy, mass-spectra, and elemental analysis given in [138] did not contradict the structure of compound 98, being regioisomer of 97. The similar situation had already been shown in the synthesis of 3-aminoimidazo[l,2-a]pyrimidines [139]. Mandair et al. carried out the model MCRs of 2-aminopyrimidine with several aldehydes and isonitrile components in the methanol under the ambient temperamre with the various catalysts. As a result, 3-aminoimidazo[l,2-a]pyrimidine and position isomeric 2-aminoimidazo[l,2-a]pyrimidines were isolated from the reaction mixture in different ratio (Scheme 45). The stmctures of the isomers obtained in this case were confirmed by the X-ray diffraction analysis, as well as the structures of the side-products isolated. 

Normally, isomeric mixtures are obtained with monosubstituted dienophiles, but in the case of phenyl vinyl sulfone 912, 2-phenyl-6-(phenylsulfonyl)-5,6,7,8-tetrahydro-4(3//)-quinazolinone 913 was isolated in 84% yield as a single regioisomer <2006EJO2753>. 

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