Ethylenic compounds, cycloadditions

Another route from five-membered 0-heterocycles to oxepines uses 2,3-dihydrofurans as starting materials and involves their [2 -I- 2] cycloaddition reaction with ethyne or ethylene compounds, followed by cleavage of bicyclic compounds formed by thermolysis or Lewis acid catalysis <83CB1691, 87TL1501,92JOC5102). These transformations are presented in Scheme 29 by starting from dimethyl acetylenedicarboxylate and 2,3-dihydrofuran or its 5-substituted derivatives <87TL1501>. 

No generalizations can be made at this time regarding the mechanism of photochemical cycloadditions of ethylenic compounds. Many such reactions occur either under the influence of direct excitation of the reactant or upon its excitation by means of triplet energy transfer. Often different products... 

The simplest of all Diels-Alder reactions cycloaddition of ethylene to 1 3 butadi ene does not proceed readily It has a high activation energy and a low reaction rate Substituents such as C=0 or C=N however when directly attached to the double bond of the dienophile increase its reactivity and compounds of this type give high yields of Diels-Alder adducts at modest temperatures... 

A large number of pyridazines are synthetically available from [44-2] cycloaddition reactions. In one general method, azo or diazo compounds are used as dienophiles, and a second approach is based on the reaction between 1,2,4,5-tetrazines and various unsaturated compounds. The most useful azo dienophile is a dialkyl azodicarboxylate which reacts with appropriate dienes to give reduced pyridazines and cinnolines (Scheme 89). With highly substituted dienes the normal cycloaddition reaction is prevented, and, if the ethylenic group in styrenes is substituted with aryl groups, indoles are formed preferentially. The cycloadduct with 2,3-pentadienal acetal is a tetrahydropyridazine derivative which has been used for the preparation of 2,5-diamino-2,5-dideoxyribose (80LA1307). 

In the Diels-Alder reaction a double bond adds 1,4 to a conjugated diene (a 2 + 4 cycloaddition), so the product is always a six-membered ring. The double-bond compound is called a dienophile. The reaction is easy and rapid and of very broad scope and reactivity of dienes and dienophiles can be predicted based on analysis of the HOMOs and LUMOs of these species. Ethylene and simple alkenes make poor dienophiles, although the reaction has been carried out with these compounds. 

Cycloadditions of germa-substituted ethylenes and acetylenes to dienes provide cyclic germa compounds (Scheme 6)44. 

Diastereoselective intramolecular 1,3-dipolar cycloadditions of alkylidene-cyclopropyl nitrones provide spirocyclopropylisoxazolidines. These compounds have been shown to undergo either thermally induced ring expansion to octahydro[l]pyrindin-4-ones or to acid induced ring contraction into fS-lactams with concomitant loss of ethylene (Scheme 2.218) (710-716). Use of chiral auxiliaries, that is (L)-2-acetoxylactate can lead to enantiomerically enriched heterocycles (715). 

If ROM-RCM of cycloalkene-yne 123, which has a substituent at the 2-position of cycloalkene, is carried out under ethylene gas, what compound is formed In this reaction, ruthenium carbene XIX would be formed via [2-1-2] cycloaddition of ruthenium methylidene carbene and alkyne as shown in Eq. (6.91). If XIX reacts with an olefin intramolecularly or ethylene, bicyclic compound 124 or triene 125... 

For the synthesis of carazostatin (247), the required arylamine 708 was synthesized starting from 1-methoxycyclohexa-l, 3-diene (710) and methyl 2-decynoate (711). The key step in this route is the Diels-Alder cycloaddition of 710 and 711, followed by retro-Diels-Alder reaction with extrusion of ethylene to give 2-heptyl-6-methoxybenzoate (712). Using a three-step sequence, the methoxy-carbonyl group of compound 712 was transformed to the methyl group present in the natural product. 3-Heptyl-3-methylanisole (713) was obtained in 85% overall yield. Finally, the anisole 713 was transformed to the arylamine 708 by nitration and subsequent catalytic hydrogenation. This simple sequence provides the arylamine 708 in six steps and with 26% overall yield (597,598) (Scheme 5.66). 

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