Dipolarophiles isomiinchnones

Padwa and co-workers employed a rhodium-catalyzed [3+2] cycloaddition reaction to generate a number of 3-hydroxy-2-pyridones, including the tricyclic 146, obtained using fV-phenylmaleimide 145 as the dipolarophile. The rhodium-catalyzed cyclization of 143 generates an isomiinchnone intermediate 144, which undergoes the cycloaddition (Scheme 11) <1997JOC438>. 

Mathias and Moore (30-33) described a new synthesis of isomiinchnones 55 via the thermal cyclization of A-(chloroacetyl)lactams (54) (Scheme 10.7). These isomiinchnones can be captured by NPM to give fused 2-pyridones in moderate yields. Cycloadducts from the reaction with DMAD are produced in much lower yields (<17%), and other olefinic dipolarophiles (fumarate, maleate, acrylate, and dicyanocyclobutene) are unreactive. Reaction of 7/-(chloroacetyl)benzamide (57) in the presence of NPM gave 58 in low yield. 

Maier and Schoffling (37) extended this intramolecular isomiinchnone cycloaddition to a synthesis of fused furans by employing an alkyne dipolarophile (Scheme 10.9). Thus, the diazo acetylenes (66) are smoothly converted to furans (69) via isomtinchnones (67) with catalytic rhodium acetate. 

Doyle et al. (39) expanded the rhodium-catalyzed generation of isomiinchnones from diazoacetacetamides and subsequent trapping with dipolarophiles (38). As shown in Scheme 10.12, in the case of diazoacetoacetyl urea (79) the derived isomtinchnone 80 reacts with methyl propiolate to give a 2 1 mixture of cycloadducts 81. The resulting regiochemistry is successfully rationalized using frontier molecular orbital (FMO) theory as being isomiinchnone-HOMO controlled. This result represents one of the few reactions in which the cycloadducts from isomiinchnones and alkynes are stable. 

Whereas 260 does not react with electron-rich dipolarophiles, the more delocalized isomiinchnone 261 does react with both electron-rich and -deficient dipolarophiles (154). A detailed FMO analysis is consistent with these observations and with the regiochemistry exhibited by diethyl ketene acetal and methyl vinyl ketone as shown in Scheme 10.36. The reaction of 261 with the ketene acetal to give 262 is LUMO-dipole HOMO-dipolarophile controlled (so-called lype III process). In contrast, the reaction of 261 with methyl vinyl ketone to give 263 is HOMO-dipole LUMO-dipolarophile controlled (so-called lype I process). In competition experiments using a mixture of A-phenylmaleimide and ketene acetal only a cycloadduct from the former was isolated. This result is consistent with a smaller energy gap for... 

Padwa and Prein (162) generated several chiral isomiinchnones, using the rhodium catalyzed deamination of chiral ot-diazo unides, and trapped them with various dipolarophiles. 

Ibata was the first to show that the masked carbonyl ylide embedded within the isomiinchnone framework would readily undergo 1,3-dipolar cycloaddition with various dipolarophiles [34], The isolable isomiinchnone 4 was observed to react with dimethyl fumarate to produce cycloadduct 7 which possesses the 7-oxa-2-azabicyclo[2.2.1]heptane skeleton. When the reaction of 1 was carried out using catalytic amounts of Cu(acac)2 in the presence of various dipolarophiles, smooth dipolar cycloaddition was observed to occur giving mixtures of endo and exo isomers. In most cases, the exo isomers were favored. All of Ibata s isomiinchnone cycloadditions contain aromatic substituent groups, presumably selected to facilitate dipole formation. The synthetic utility of the cycloaddition reaction is diminished, however, because of the low reactivity of the aromatic substituents toward further manipulation. 

Unsymmetrical dipolarophiles were found to undergo intermolecular cycloaddition with isomiinchnones with high regioselectivity [27]. For example, the decomposition of diazoimide 9 with Rh2(OAc)4 in the presence of methyl vinyl ketone resulted in the formation of two products identified as 27 and 28 in 27 %... 

The cycloaddition of isomiinchnones with acetylenic dipolarophiles followed by the extrusion of an alkyl or aryl isocyanate (RNCO) has proven to be an effective method for the synthesis of substituted furans. The Ibata group investigated the bimolecular 1,3-dipolar-cycloaddition of aryl-substituted isomiinchnones with a number of acetylenic dipolarophiles [50]. Aryl diazoimides of type 1 were heated in the presence of a catalytic amount of Cu(acac)2 and the appropriate acetylenic dipolarophile. Formation of the substituted furan was found to be temperature-dependent higher temperatures (ca. 120°C) were needed for complete conversion to the furan. It was reasoned that the extrusion of methyl isocyanate was not as facile as the loss of carbon dioxide from sydnones and miinchnones [50]. 

An interesting feature of isomiinchnones is their ability to undergo 1,3-dipo-lar cycloaddition with carbonyl compounds, a reaction which is unprecedented with miinchnones [56]. This is illustrated by the reaction of diazoimide 106 with Cu(acac)2 in the presence of several different aldehydes and ketones which resulted in the formation of cycloadducts of type 107 -109. When benzil was used as the dipolarophile, the regioselectivity was reversed giving rise to cycloadduct 110 as the only regioisomer. 

A Pummerer-initiated cascade reaction has also been used as a method for generating isomiinchnones for further use in cycloaddition chemistry. For example, treatment of sulfoxide 23 with acetic anhydride first resulted in the formation of a reactive thionium ion that reacted with the distal amide carbonyl group to produce isomunchnone 24 (Scheme 6) (99JOC2038). Exposure of 24 to a dipolarophile, such as iV-phenylmaleimide, resulted in 1,3-dipolar cycloaddition to give 25 as a single diastereomer in 85% yield. 

The decomposition of suitably crafted diazoimides 181, in the presence of a transition metal catalyst, affords the metallo-carbenoids 182 that undergo intramolecular cycUzation onto the neighboring amide carbonyl oxygen to form the five-membered ring carbonyl yUdes (isomiinchnones) 183 (Scheme 58). Early examples of inter- and intramolecular 1,3-dipolar cycloaddition of the mesoionic ylides 183 have mainly emanated from the research groups of Ibata [149], Maier [150] and Padwa [151]. These reactive species (isomimchnones) can be trapped by various electron-rich and electron-deficient dipolarophiles [152] to furnish the cycloadducts in high yield. Much work has been reported in this area and for clarity of presentation is described here under various subheadings. 

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