Isocyanates reaction with pyrrole

H-pyran synthesis from, 3, 759 bis(trimethylsiloxy) in pyrrole synthesis, 4, 333 chromene synthesis from, 3, 750 cycloaddition reactions with isocyanates, azetidin-2-ones from, 7, 261 dihydropyran synthesis from, 3, 771 fuiyl... 

An alternative strategy for the synthesis of these tricyclic compounds involves the reaction of the azidoalkenyl-functionalized furo[3,2-A]pyrrole 30, which reacts with triphenylphosphine to give the corresponding iminophos-phoranes 31 these upon reaction with aryl isocyanates give the pyrrolo[2, 3 4,5]furo[3,2-r-]pyridines 32, via the corresponding carbodiimides which are not isolated < 1994H(37) 1695, 1992M807> (Scheme 9). 

Mesomeric betaines 451 derived fromA-heterocycUc carbenes and isocyanates undergo a [3-1-2] cycloaddition reaction with acetylenes (R = Me, COOMe, COOEt R = Me, Et) to give spiroindazole-3,3 -pyrroles 452 in high yields ... 

Transmetallation of 1-6 or treatment of 1-6 with Lewis acid further broadens the scope of its reaction chemistry. In the presence of CuCl, the reaction of 1-6 with diazo dicarboxylate affords pyridazine derivatives [27]. In the presence of CuCl or nickel complexes, the reaction of 1-6 with alkynes leads to benzene derivatives [28, 29]. Transmetallation of 1-6 with Bids allows further reaction with 2-oxo malonate to give 2/7-pyran derivatives [27]. Transmetallation of 1-6 with CrCls followed by reaction with isocyanates affords pyridine derivatives [30]. Transmetallation of 1-6 with AICI3 followed by reaction with aldehydes affords pentasubstimted cyclo-pentadiene derivatives [31]. Under the similar condition, 1-6 reacts with nitroso compounds to form pyrrole derivatives [32]. Addition of n-butyl lithium activates 1-6 and allows further reaction with carbon monoxide, which leads to carbonylation and affords 2-cyclopentenone upon hydrolysis [33]. 

Some of the physical constants of pyrrole and of a selection of its derivatives are collected in Table 4,1, The boiling point of pyrrole is higher than might have been expected, and the closer similarity in this property of 1-methylpyrrole to, say, toluene suggests that in pyrrole the imino group is responsible for some sort of association (see below). The characterization of pyrrole and simple alkylpyrroles through the formation of crystalline derivatives is not always easy. Picrates are usually unstable. In cases where picric acid causes dimerization, the dimer picrate is often a satisfactory derivatively, 233 xhe reaction with phenyl isocyanate (p. 66) is useful. 

Upon reaction of A -vinyliminophosphoranes (109) with aromatic isocyanates, vinylcarbodiimides (110) are formed, as shown in Scheme 47. Divi-nylcarbodiimides (111) can be obtained as side products (88CB271). With isonitriles the vinylcarbodiimides also afford pyrroles (112) via [4 + 1]-cycloaddition. Divinylcarbodiimide can also react via [4 -l- l]-cycloaddition with an isonitrile, whereupon an electrocyclic step of the initial diaza-1,3,5-trienes (113) follows. Finally, the pyrrolo[2,3-e]pyrazine 114 is obtained (88CB271). 

The reaction of 3,6-di-/ftt-butyl-l,4-dihydropyrrolo[3,2-. ]pyrrole 58 with chlorosulfonyl isocyanate (CSI) giving 59 was investigated (Scheme 1) <1996H(43)2361>. The higher reactivity for electrophilic reaction demonstrated the remarkably electron excessive nature of the system when compared with indole and pyrrole derivatives. 

The mesoionic imidazole 166 on refluxing with DMAD in benzene gave the pyrrole 168 almost quantitatively143 the postulated intermediate 167 is expected to lose phenyl isocyanate readily. A number of similar reactions involving both EP143 and DMAD144 have been described. 

Cycloaddition reactions have been carried out with corresponding bases of Vilsmeier salts of pyrroles. Thus reaction of 153 with dimethyl acetylenedicar-boxylate gave pyrrolizines 154 and 3a-azaazulenes 155 in a nonsynchronous reaction. The structure of 3H-pyrrolizine 154a was proved by X-ray analysis.96 In a closely related reaction, pyrrolizinones 156 and 157 were obtained from the corresponding Vilsmeier salts with phenyl isocyanate.97 Reaction of 2-p-nitrobenzoylindolin-3-one (158) with methyl acetoacetate gave the benzopyrrolizinone (159).5 7... 

An enantioselective Friedel-Crafts alkylation of pyrroles with /V-acylimincs has been reported <070L4065>. The reactions were run in the presence of chiral phosphoric acids. A novel C-H bond activation procedure was developed for the preparation of heteroarylamides including pyrrole-3-carboxamides <07CL872>. The reactions involved imine-substituted pyrroles, isocyanate electrophiles, and a rhenium catalyst. 

In a similar context Amdtsen developed a new pyrrole synthesis from alkynes, acid chlorides either imines or isoquinolines, based on the reactivity of isocyanides (Scheme 35a) [197]. Although all atoms from the isocyanide are excluded from the final structure, its role in the reaction mechanism is crucial. The process takes place through the activation of the imine (isoquinoline) by the acid chloride to generate the reactive M-acyliminium salt, which is then attacked by the isocyanide to furnish a nitrilium ion. This cationic intermediate coordinates with the neighboring carbonyl group to form a miinchnone derivative, which undergoes a [3+2] cycloaddition followed by subsequent cycloelimination of the isocyanate unit, to afford the pentasubstituted pyrrole adducts 243 and 244 (Scheme 35a, b). 

Cycloaddition reactions have been carried out with Vilsmeier bases of pyrroles. Thus reaction of (180) with dimethylacetylene dicarboxylate gave pyrrolizines (181) and 3a-azaazulenes (182) in a non-concerted reaction <74JHC811>. In a closely related reaction, (183) was obtained from the Vilsmeier base with phenyl isocyanate <76H(4)i28i>. 

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