Rearrangements ring opening

An interesting strategy for the synthesis of pyrrolizidines and indolizidines has been developed by Brandi and co-workers. Cycloaddition between nitrones or nitrile oxides with methylenecyclopropanes generates strained tricyclic spiro compounds, which are prone toward further transformations, such as rearrangement, ring opening, and new ring closure (Scheme 10.17).116... 

Reaction of a carbene, formed by the ring opening of a cyclopropene, with the cyclopropene itself, generates a vinylbicyclo[1.1.0]butane. Thus, l-methoxycarbonyl-3,3-dimethylcyclo-propene (6) dimerizes at — 10°C to l-methoxycarbonyl-2-(l-methoxycarbonyl-2-methyl-propenyl)-4,4-dimethylbicyclo[1.1.0]butane (7), formed together with its rearranged, ring-opened isomer 2,7-dimethylocta-2,4,6-triene-3,6-dicarboxylate 8. The structures of the products originate from only one of the two possible carbene intermediates.24... 

If however, the selenium was next to the oxygen, the reaction proceeded, yielding 256 in a sequence which probably involves Wolff rearrangement, ring opening and dimerization. 

Blechert et developed a multicomponent cascade reaction for the synthesis of indole derivatives as depicted in Scheme 1.8.5.17. The first step of the sequence involves formation of a nitrone derivative starting from phenylhydroxylamines and aldehydes. The resulting nitrones were not isolated but captured by a cyanoallene in a 1,3-dipolar cycloaddition reaction followed by hetero-Cope rearrangement, ring-opening and condensation to yield an indole derivative. 

The polyester polyols are conventionally made by simple polyesterification of a glycol and a dibasic acid using a 5-20% excess of glycol to ensure hydroxyl end-groups. An alternative method is provided by the rearrangement (ring-opening, addition) polymerization of e-caprolactone in the presence of an initiator ... 

The last group of reactions uses ring opening of carbonyl or 1-hydroxyalkyl substituted cyclopropanes, which operate as a -synthons. d -Synthons, e.g. hydroxide or halides, yield 1,4-disubstituted products (E. Wenkert, 1970 A). (1-Hydroxyalkyl)- and (1-haloalkyl)-cyclopropanes are rearranged to homoallylic halides, e.g. in Julia s method of terpene synthesis (M. Julia, 1961, 1974 S.F. Brady, I968 J.P. McCormick, 1975). 

Another useful route to cyciopentanes is the ring contraction of 2-bromo-cydohexanones by a Favorskii rearrangement to give csrdopcntanecarboxylic acids. If a 0 dibromoketones are used, ring opening of the intermediate cydopropanone leads selectively to, y-unsaturated carboxylic acids (S.A, Achmad, 1963, 1965 J. Wolinsky, 1965). 

The recently reported rearrangement (1581) of 2-allylamino-4-carboxamido-5-aminothiazoIes to 4-aminoimidazole-5-carboxamide in presence of sodium bicarbonate probably involves the electrophilic reactivity of C-2, which allows the ring opening. 

The reaction of amines with the 4-phenylazo derivative (228) results in their rearrangement into triazolines. Depending on the basicity of the amines and the size of the alkoxy group, three different triazolines (229. 230, and 231) are obtained (Scheme 117) (454. 459, 472). In all cases, the first step involves nucleophilic addition of the amine to the carbonyl group followed by ring opening and further ring closure. 

An unusual reaction involving s-triazine (247) and ethyl acetoacetate with sodium ethoxide leads eventually to the pyrido[4,3-ring opening and Dimroth-type rearrangement of the intermediate (248) (80JHC389>. 

In this section three main aspects will be considered. Firstly, the basic strengths of the principal heterocyclic systems under review and the effects of structural modification on this parameter will be discussed. For reference some pK values are collected in Table 3. Secondly, the position of protonation in these carbon-protonating systems will be considered. Thirdly, the reactivity aspects of protonation are mentioned. Protonation yields in most cases highly reactive electrophilic species. Under conditions in which both protonated and non-protonated base co-exist, polymerization frequently occurs. Further ipso protonation of substituted derivatives may induce rearrangement, and also the protonated heterocycles are found to be subject to ring-opening attack by nucleophilic reagents. 

Reaction of thiazoles with DMAD illustrates the overall reaction and the rearrangements which may be encountered. Thiazole or 2-methylthiazole (411 R=H and Me, respectively) in DMF reacted with DMAD to give an initial 1,4-dipolar species (412). Reaction with a second DMAD gave the 1 2 molar adduct, presumably (413). Ring opening to (414), followed by cyclization in the alternative mode, resulted in the formation of (415), the structure of which (R = Me) was established by X-ray analysis (78AHC(23)263) (see also Chapter 4.19). 

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