Dipolarophiles isocyanates

N-Acylimines do not yield 1,3-addition products even with the strongly dipolarophilic isocyanates [Eq. (11) ]80, but, as for 1,2-diphenylcyclo-propenone,145 the oxygen atom of the acylimino group is attacked. Whereas the isocyanate adduct is stable, the cyclopropenone adduct 101 reacts further as indicated in Eq. (17). 

The class of 1,3-dipolar cycloadditions embraces a variety of reactions that can accomplish the synthesis of a diverse array of polyfunctional and stereochemically complex five-membered rings.3 The first report of a 1,3-dipolar cycloaddition of a nitrone (a 1,3-dipole) to phenyl isocyanate (a dipolarophile) came from Beckmann s laboratory in 1890,4 and a full 70 years elapsed before several investigators simultaneously reported examples of nitrone-olefin [3+2] cycloadditions.5 The pioneering and brilliant investigations of Huisgen and his coworkers6 have deepened our under-... 

The intermolecular dimerization of nitrile oxides has been described as a procedure to prepare Fx with identical substituent both in the 3 and 4 position (Fig. 3). This procedure is a [3 -F 2] cycloaddition where one molecule of nitrile oxide acts as 1,3-dipole and the other as dipolarophile [24-26]. Yu et al. has studied this procedure in terms of theoretical calculus [27,28]. Rearrangement of isocyanates competes with the bimolecular dimerization, with the former becoming dominant at elevated temperatures. 

The 1,3-dipolar cycloaddition of a nitrone to a C=N species remains (see CHEG-II(1996) for earlier examples) a popular route to 1,2,4-oxadiazolidines. The use of isocyanates and isothiocyanates as the dipolarophile allows access to l,2,4-oxadiazolidin-5-ones and 5-thiones, as the examples in Equations (75) <1995HCO307> and (76) <2006SC997> show, giving access to l,2,4-oxadiazolidin-5-ones 373 and 374, respectively. 

These routes are dimerization to furoxans 2 proceeding at ambient and lower temperatures for all nitrile oxides excluding those, in which the fulmido group is sterically shielded, isomerization to isocyanates 3, which proceeds at elevated temperature, is practically the only reaction of sterically stabilized nitrile oxides. Dimerizations to 1,2,4-oxadiazole 4-oxides 4 in the presence of trimethylamine (4) or BF3 (1 BF3 = 2 1) (24) and to 1,4,2,5-dioxadiazines 5 in excess BF3 (1, 24) or in the presence of pyridine (4) are of lesser importance. Strong reactivity of nitrile oxides is based mainly on their ability to add nucleophiles and particularly enter 1,3-dipolar cycloaddition reactions with various dipolarophiles (see Sections 1.3 and 1.4). 

The reaction of cyclic nitrone with phenyl isothiocyanate <2003MI253>, isocyanate <1974JOC568>, or cyano-esters <1995JP11417> has been reported. The beneficial effect of activation of the dipolarophile by coordination on a platinum complex and focused microwave irradiation has been described (Scheme 15) <2003JCD2540>. 

Diazoazoles, because of charge polarization and potential bifunctional reactivity of the derived betaine, react with dipolarophiles to give cycloaddition products. Generally all the diazoazoles react with electron-rich, unsaturated derivatives. The cycloaddition reaction with isocyanates is readily observed in the case of the reactive 3-diazopyrazoles, but it is much slower with other diazoazoles. By contrast, reaction with ylides and diazoalkanes is only observed for 3-diazopyrazoles and 3-diazoindazoles. 

When acrylonitrile or ethyl acrylate was used as the dipolarophile, the azomethine adducts (134) and (135) were formed no thiocarbonyl ylide addition products were isolable in refluxing toluene or xylene, although the isoindoles (136a) and (136b) derived from them were isolated. In contrast to the reactions with fumaronitrile or AT-phenylmaleimide, the azomethine adducts (134) and (135) were still present at higher reaction temperatures — almost 50% in toluene and 4-5% in xylene. Under the same reaction conditions other electron-deficient dipolarophiles like dimethyl fumarate, norbornene, dimethyl maleate, phenyl isocyanate, phenyl isothiocyanate, benzoyl isothiocyanate, p-tosyl isocyanate and diphenylcyclopropenone failed to undergo cycloaddition to thienopyrrole (13), presumably due to steric interactions (77HC(30)317). 

Convincing evidence about the formation of the carbonyl oxide was obtained by trapping it with phenyl isocyanate as a dipolarophile (Scheme 69) <94JCS(P1)3295>. 

Alkyl azides readily undergo 1,3-dipolar cycloaddition to arylsulfonyl isothiocyanates (375) to yield thiatriazolines (376). Thermolysis of (376) in the presence of isocyanates or carbodiimides produces 1,2,4-thiadiazole derivatives (378) and (379), respectively. The intermediate formation of a thiaziridinimine (377) has been postulated as indicated in Scheme 137 (75JOC1728, 75S52). The use of isothiocyanates as dipolarophiles produces dithiazolidines (380) instead of the thiadiazole derivatives. In these reactions the intermediate thiazirine (377) functions as a 1,3-dipole with the positive charge primarily localized on sulfur. It was recently proposed that the reaction of oxaziridines (381) with isothiocyanates produces a similar thiazirine intermediate (382) which reacts in a different regiospecific manner with isothiocyanates to produce 1,2,4-thiadiazole derivatives (383) and (384 Scheme 138) (74JOC957). 

In the absence of dipolarophiles the intermediate loses sulfur to give the carbodiimide however, the intermediate may be trapped with a number of alkenes, heterocumulenes and other reagents such as ynamines, ketenes, isocyanates, isothiocyanates, carbodiimides, ketenimines, sulfonylimines, imines, nitriles, thiocarbonyl compounds, Wittig reagents and the already mentioned enamines (80AG277). Contemporary knowledge of the chemistry of these sulfonyliminothiatriazolines is mainly due to the meticulous work of L abbe and his coworkers (80AG277). 

Both of the known oxathiolium systems have been trapped in situ by dipolarophiles. Compound (88) reacts with dimethyl acetylenedicarboxylate (DMAD), but not phenyl isocyanate or isothiocyanate, to yield thiophene (89), following loss of carbon dioxide as shown in Scheme 10 (77CPB1471). Similarly, oxathioliums (90) may be trapped by a variety of alkynic dipolarophiles to give furans (91) as shown in Scheme 11. The reaction, which appears to be regiospecific when unsymmetrical alkynes are used, is a useful way of preparing furans containing amine or thioether functionality (75AG(E)422). 

Similar reactions have been carried out with variously substituted pyrroline 1-oxides, imidazole 1-oxides, isoxazoline N-oxides (nitronic esters) and 3,4-diazacyclopentadienone AT-oxides in combination with a large variety of alkenic and alkynic dipolarophiles, aryl isocyanates, aryl isothiocyanates and N- sulfinylamines, leading to pyrrolidinoisoxazoles, pyrrolo[l,2-6][l,2,4]oxadiazoles, pyrrolo[2,l-d][l,2,3,5]oxathiadiazoles, isoxazolo[2,3-b ]isoxazoles and isoxazolo[l, 2-6 ]pyrazoles. 

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]. 

Sydnones can be regarded as cyclic azomethine imines and as such they undergo thermal cycloaddition reactions with a range of dipolarophiles. Thus, reaction with phenyl isocyanate converts 401 into 1,2,4-triazole 402. On photolysis, 3,4-diarylsydnones lose carbon dioxide and give nitrile imines, which can also be intercepted by dipolarophiles. Thermal reactions with acetylenic dipolarophiles lead to the formation of pyrazoles (Scheme 88) however, these reactions are rarely completely regioselective with unsymmetrical alkynes, e.g., <2000BKC761, 2000TL1687>. 

The photochemical addition of 2H-azirines to the carbonyl group of aldehydes, ketones and esters is completely regiospecific (77H143). Besides the formation of the isomeric oxazolines 18 from 3 and ethyl cyanoformate, there is also formed the imidazole 19 from addition to the C = N in the expected regioselective manner. Thioesters lead to thiazolines 20, while isocyanates and ketenes produce heterocycles 21 (Scheme 4). The photocycloaddition of arylazirines with a variety of multiple bonds proceeds in high yield and provides a convenient route for the synthesis of five-membered heterocyclic rings. Some of the dipolarophiles include azodicarboxylates, acid chlorides, vinylphospho-nium salts and p-quinones. 

A representative 1,3-dipolar cycloaddition process occurs with yV-aryl-C-(trifiuoromethyl)-nitrilimines, generated from the corresponding hydrazonoyl bromides, c.g. 4. under basic conditions. which can react with dimethyl fumarate and maleate,bicyclic olefins. and dipolarophiles containing cumulative double bonds. With sodium isocyanates as the dipolarophilc the cycloaddition reaction occurs across the C = N bond, while with potassium isothiocyanate it occurs through the C = S bond. ... 

From the parent nitro compound -PrN02 (68), formal elimination of one water molecule with phenyl isocyanate gives the desired nitrile oxide 69 (the 1,3-dipole), aniline and CO2. Then, an isoxazoline is made by cycloaddition of 69 with the terminal olefin of the substrate (dipolarophile). ... 

Cyclic carbonyl ylides, formed from diazo amides or diazo anhydrides through intramolecular carbene addition to the carbonyl group, react with the triple bond of a dipolarophile to produce bicyclic adducts. The latter undergo a retrodiene reaction, splitting off an alkyl isocyanate or carbon dioxide to give furan derivatives. 

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