Heterocycles cycloaddition

Among six-membered unsaturated nitrogen heterocycles, cycloaddition reactions of nitrile oxides at the C=N bond have been described for individual... 

Formation of heterocycles in heterocyclization, cycloaddition, and 1,3-dipolar cycloaddition reactions of alkenynamines 03ZOR169. 

A selenium linker has been used in the preparation of various nitrogen-containing heterocycles. Cycloaddition of nitrile oxides to resin-bound alkynes gave resin-bound isoxazoles (Scheme 11.41). a-AIkylation of the resin-bound cycloadducts with halides under basic conditions gave additional diversity for the products. Traceless oxidative cleavage of the isoxazoles was achieved via the elimination of the resin with hydrogen peroxide. The diversity of the products was still expanded with a second cascade of 1,3-dipolar cycloadditions to alkenes attached to the resin. 

Type G Syntheses [C—N—S + C—N]. Nitrile sulphides R—C N->S have recently become available as reactive intermediates in the thermolysis (at ca. 190 °C) of 5-substituted l,3,4-oxathiazol-2-ones they may be trapped by 1,3-dipolar cycloadditions, e.g. with acetylenes, resulting in S,N-heterocycles. Cycloaddition of nitrile sulphides R CNS to nitriles R CN provides a new general synthesis of 3,5-disubstituted 1,2,4-thiadiazoles (62). Yields are moderate, but are satisfactory when electrophilic nitriles are used in conjunction with aromatic nitrile sulphides. Minor amounts of (63) are formed as by-products. 

A few typical examples indicate the large variety of five-membered heterocycles, which can be synthesized efficiently by [2 + 3]-cycloadditions. [2 + 2]-Cycloadditions are useful in the synthesis of certain four-membered heterocycles (H. Ulrich, 1967), e.g. of 8-lactams (J.R. 

In the presence of a double bond at a suitable position, the CO insertion is followed by alkene insertion. In the intramolecular reaction of 552, different products, 553 and 554, are obtained by the use of diflerent catalytic spe-cies[408,409]. Pd(dba)2 in the absence of Ph,P affords 554. PdCl2(Ph3P)3 affords the spiro p-keto ester 553. The carbonylation of o-methallylbenzyl chloride (555) produced the benzoannulated enol lactone 556 by CO, alkene. and CO insertions. In addition, the cyclobutanone derivative 558 was obtained as a byproduct via the cycloaddition of the ketene intermediate 557[4I0]. Another type of intramolecular enone formation is used for the formation of the heterocyclic compounds 559[4l I]. The carbonylation of the I-iodo-1,4-diene 560 produces the cyclopentenone 561 by CO. alkene. and CO insertions[409,4l2]. 

The success of the cycloaddition reaction of maleic anhydride varies gready depending on which heterocyclic diene is used. The cycloaddition of maleic anhydride to furan [110-00-9] occurs ia a few seconds under ambient conditions (42,43). Although the endo adduct (14) is favored kiaeticaHy, the exo adduct (13) is isolated. 

Metal-Induced Cycloadditions. The effect of coordination on the metal-iaduced cyclo additions of maleic anhydride and the isostmctural heterocycles furan, pyrrole, and thiophene has been investigated (47). Each heterocycle is bound to an Os(II) center in the complex... 

Dipolar cycloaddition reactions with azides, imines, and nitrile oxides afford synthetic routes to nitrogen-containing heterocycles (25—30). 

Since diazaquinones are among the most powerful dienophiles, they undergo [4+2] cycloaddition (Diels-Alder) reactions with a great variety of dienes to give various heterocyclic systems accessible with difficulty by other methods. Diazaquinone reacts with butadiene and substituted butadienes, carbocyclic and heterocyclic dienes, 1-vinylcycloalkenes, polyaromatic compounds and vinylaromatic compounds to afford bicyclic and polycyclic bridgehead diaza systems, including diazasteroids (Scheme 56). 

Furan has the greater reactivity in cycloaddition reactions compared with pyrrole and thiophene the latter is the least reactive diene. However, A -substituted pyrroles show enhanced dienic character compared with the parent heterocycle. 

Benzo[Z)]furans and indoles do not take part in Diels-Alder reactions but 2-vinyl-benzo[Z)]furan and 2- and 3-vinylindoles give adducts involving the exocyclic double bond. In contrast, the benzo[c]-fused heterocycles function as highly reactive dienes in [4 + 2] cycloaddition reactions. Thus benzo[c]furan, isoindole (benzo[c]pyrrole) and benzo[c]thiophene all yield Diels-Alder adducts (137) with maleic anhydride. Adducts of this type are used to characterize these unstable molecules and in a similar way benzo[c]selenophene, which polymerizes on attempted isolation, was characterized by formation of an adduct with tetracyanoethylene (76JA867). 

There are several useful syntheses which effectively commence with the cycloaddition of oxygen, a nitroso compound, an azo compound or a sulfinylamine to a 1,3-diene leading to the corresponding 1,2-dioxins, 1,2-oxazines, pyridazines or 1,2-thiazines. Examples of the transformation of these adducts into five-membered heterocycles are shown in Scheme 114 together with leading references. 

A versatile method for the synthesis of a variety of five-membered heterocycles and their ring-fused analogs involves the reaction of a neutral 47r-electron-3-atom system with a 27T-electron system, the dipolarophile, which is usually electron deficient in nature. Available evidence, e.g. retention of dipolarophile stereochemistry in the product and solvent polarity exerting only a moderate influence on the reaction, indicates that the cycloaddition proceeds via a concerted mechanism 63AG(E)565, 63AG(E)633, 68JOC2291) and may be represented in general terms by the expression in Scheme 8. 

Dipolarophiles utilized in these cycloadditions leading to five-membered heterocycles contain either double or triple bonds between two carbon atoms, a carbon atom and a heteroatom, or two heteroatoms. These are shown in Scheme 9 listed in approximate order of decreasing activity from left to right. Small rings containing a double bond (either C=C or C=N) are also effective dipolarophiles, but these result in six- and seven-membered ring systems. 

As the sp nitrogen atom in many heterocycles can be alkylated and aminated, the construction of an azomethine ylide or azomethine imine dipole is readily attainable as shown in Scheme 13. These ylides are very reactive and undergo cycloaddition with a... 

Just as in the Diels-Alder reaction, 1,4-dipolar cycloadditions lead to six-membered rings. Their principal use in five-membered heterocycles is for ring annulations giving [5,6] ring-fused systems. 

Small unsaturated rings are usually very reactive undergoing ring opening in a number of ways, and this characteristic has been utilized in heterocyclic synthesis. In their role as dienophiles or dipolarophiles, the initial cycloaddition is usually followed by a valence tautomerism resulting in a six-membered or larger ring system. Several examples exist, however, where this does not occur, and these are described below. 

In theory, three isoxazolines are capable of existence 2-isoxazoline (2), 3-isoxazoline and 4-isoxazoline. The position of the double bond may also be designated by the use of the prefix A with an appropriate numerical superscript. Of these only the 2-isoxazolines have been investigated in any detail. The preparation of the first isoxazoline, 3,5-diphenyl-2-isoxazoline, from the reaction of )3-chloro-)3-phenylpropiophenone with hydroxylamine was reported in 1895 (1895CB957). Two major syntheses of 2-isoxazolines are the cycloaddition of nitrile A-oxides to alkenes and the reaction of a,/3-unsaturated ketones with hydroxylamine. Since 2-isoxazolines are readily oxidized to isoxazoles and possess some of the unique properties of isoxazoles, they also serve as key intermediates for the synthesis of other heterocycles and natural products. 

The preparation of isoxazolidine derivatives was first reported by Bodforss in 1918 (18CB192). The major synthesis of isoxazolidines involves the cycloaddition of nitrones with alkenes, and isoxazolidines have also enjoyed an increasing use as key intermediates in the synthesis of natural products and other heterocycles (79ACR396, 1892CB1498, 1892CB3291, 1882CB2105). 

Concerted cycloadditions are observed with heterocyclics of all ring sizes. The heterocycles can react directly, or via a valence tautomer, and they can utilize all or just a part of unsaturated moieties in their rings. With three-membered rings, ylides are common reactive valence tautomers. Open chain 47T-systems are observed as intermediates with four-membered rings, and bicyclic valence tautomers are commonly reactive species in additions by large rings. Very often these reactive valence tautomers are formed under orbital symmetry control, both by thermal and by photochemical routes. 

Heterocyclics of all sizes, as long as they are unsaturated, can serve as dipolarophiles and add to external 1,3-dipoles. Examples involving small rings are not numerous. Thiirene oxides add 1,3-dipoles, such as di azomethane, with subsequent loss of the sulfur moiety (Section 5.06.3.8). As one would expect, unsaturated large heterocyclics readily provide the two-atom component for 1,3-dipolar cycloadditions. Examples are found in the monograph chapters, such as those on azepines and thiepines (Sections 5.16.3.8.1 and 5.17.2.4.4). 

A large fraction of the chemical reactions known are used to form heterocyclic compounds. Displacement reactions and cycloadditions are particularly important, and their rates are therefore of great practical interest. The same is true for the rates of reverse reactions — ring opening by displacements or retrocycloadditions. It was realized over the last 40 years that... 

Lately a third type of transition state has been favored for [2 + 2] cycloadditions forming carbocyclic and heterocyclic four-membered rings. The experimental data on the addition of diarylketenes to arylethylenes are well accommodated by the [ 2s + 2s + 2s] process proposed by Baldwin (70JA4874). The steric effects on the cycloaddition of allenes to ketenes also favor this mechanism (76JA7698). 

Vapor phase pyrolysis of 2-dimethylaminoazirine (168), on the other hand, proceeds in a similar manner at 340 °C to give substituted azadiene (169) in high yield (7SJA4409). Azadiene (169) has been employed in the construction of heterocyclic rings such as pyridines via a [4-1-2] cycloaddition-elimination sequence. 

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