Nitrile ylides dipolarophiles

A novel pyrolytic method of generating nitrile ylides in situ was reported by Burger [44] (equation 45) Such nitrile ylides react with various dipolarophiles alkynes [44] (equation 46), nitriles [45] (equation 47), dimethyl azodicarboxylate [45], aldehydes [45], and nitroso compounds [46]... 

Tnfluoromethyl-substUuted 1,3-dipoles of the propargyl-allenyl type and trifluoromethyl-substituted nitrilium betaines. Tnfluoromethyl- [164, 765] and bis(trifluoromethy])-substituted [166, 167] nitrile ylides have been generated by different methods and trapped with various dipolarophiles to yield [3+2] [768] and [3+1] cycloadducts [769], respectively... 

Reaction of iV-[(benzotriazol-l-yl)methyl]amide 707 with PCI5 gives chloroimine 708, which upon treatment with Bu OK is converted to nitrile ylide 709. Benzyl esters of ot,(3-unsaturated acids used as dipolarophiles trap species 709 to generate pyrroles 712 (Scheme 110) <2002JHC759>. When no trapping agent is added, the N-2 atom of benzotriazole act as a nucleophile, and tricyclic system 711 is formed <2001TL9109>. Addition of benzyl bromide... 

The irradiation of 2//-aryl azirines yields nitrile ylides which can be trapped by various dipolarophiles to form five-membered ring heterocycles116,140-142 (equations 80-82). 

The 1,3-dipolar cycloadditions of benzonitrile oxides with tertiary cinnamides yield the 5-phenyl and 4-phenyl regioisomers in a reversal of the expected regioselectiv-ities shown with methyl cinnamate. Calculations have shown that steric factors are responsible for this reversal of regioselectivity." The 1,3-dipolar cycloadditions of benzonitrile oxide with electron-rich and electron-poor dipolarophiles are accelerated by sodium dodecyl sulfate micelles. Phenyl nitrile ylides react with electron-deficient alkenes to produce five-membered -heterocycles where measured rate constants are between 4 x 10 and 7 x 10 lmoP ... 

The use of thiirene dioxide 292 as a dipolarophile in the synthesis of thiazine 1,1-dioxides was already mentioned in CHEC(1984) <1975CL1153>. The same compound also reacts with nitrile ylide 293 to afford 294 <1984JOC1300> (Equation 97). 

The highly effective desilylation routes to nonstabihzed azomethine ylides have provided the basis for much of this chemistry. Thus, the reaction of A-(silylmethyl)-thioimidates (30) with AgF in the presence of a range of dipolarophiles (electron-deficient alkenes and alkynes, and aldehydes) led to the isolation of nitrile ylide adducts in generally high yields (20,21). Differences in reactivity and regioselectivity... 

Confirmation was provided by the observation that the species produced by the photolysis of two different carbene sources (88 and 89) in acetonitrile and by photolysis of the azirine 92 all had the same strong absorption band at 390 nm and all reacted with acrylonitrile at the same rate (fc=4.6 x 10 Af s" ). Rate constants were also measured for its reaction with a range of substituted alkenes, methanol and ferf-butanol. Laser flash photolysis work on the photolysis of 9-diazothioxan-threne in acetonitrile also produced a new band attributed the nitrile ylide 87 (47). The first alkyl-substituted example, acetonitrilio methylide (95), was produced in a similar way by the photolysis of diazomethane or diazirine in acetonitrile (20,21). This species showed a strong absorption at 280 nm and was trapped with a variety of electron-deficient olefinic and acetylenic dipolarophiles to give the expected cycloadducts (e.g., 96 and 97) in high yields. When diazomethane was used as the precursor, the reaction was carried out at —40 °C to minimize the rate of its cycloaddition to the dipolarophile. In the reactions with unsymmetrical dipolarophiles such as acrylonitrile, methyl acrylate, or methyl propiolate, the ratio of regioisomers was found to be 1 1. 

Phosphoryl substituted nitrile ylides have also been generated via the imidoyl chloride-base route using precursors 118 (R=Et, c-CeHn, f-Bu) prepared by the addition of an acid chloride to diethyl isocyanomethylphosphonate (120) (65). Treatment of the imidoyl chloride with triethylamine at —10 to 0 °C in the presence of dipolarophiles gave adducts in yields of up to 55% (e.g., 119 and 121) in ratios 1 4, 1 3 for R=Et and c = CgHn, respectively. 

In an attempt to investigate this theory further, the analogous alkoxy-substituted nitrile ylides 171 were investigated. Species of this type were previously unknown but were successfully generated for this work by the thermolysis of the 4-alkoxy substituted l,3-oxazol-5-ones 170 (89). In the absence of a dipolarophile, the nitrile ylides reacted via 1,5-electrocyclization to give the isoindoles 173 [see also... 

Extensive work has been done to determine and understand the factors controlling diastereoselectivity in the cycloaddition of nitrile oxides to alkenes but very little is known about nitrile ylides in this regard. Work on their reactions with alkenes that are geminally disubstituted with electron-withdrawing groups (e.g., 187) has illustrated some of the difficulties in such studies. When the imidoyl chloride-base route was used to generate the nitrile ylides it was found that the products 188 epimerized under the reaction conditions. When the azirine route was used, the reaction was complicated by the photochemical isomerization of the dipolarophiles (96,97). Thus, in both cases, it proved impossible to determine the kinetic product ratio. 

Intramolecular cycloaddition of nitrile ylides to olefinic dipolarophiles linked to the dipole by a three-atom chain leads to pyrazoles fused to five-membered rings. Work on stereoselectivity in such reactions has been carried out using the reactant 266 in which the alkene moiety is linked to the C-terminus via a tether that incorporates an enantiomerically pure (R) stereogenic group (165). Both diastereo-isomers 267 and 268 were isolated and it was found that the reaction showed moderate stereoselectivity favoring 267. 

These results are rationalized on the basis of the intermediate formation of thio-substituted nitrile ylides 58 that undergo regioselective 1,3-dipolar cycloadditions with the dipolarophiles. Some examples are shown in Scheme 7.15. If a dipolaro-phile is not present in the reaction mixture the nitrile ylides 58 (R2 = Me) isomerize to give the 2-aza-1,3-butadienes 59 that can be trapped in a Diels-Alder reac-... 

On heating, 4-(isopropoxy)-2-phenyl-2-(trifluoromethyl)-5(2/i/)-oxazolone 65 underwent decarboxylation to the alkoxy-substituted nitrile ylide 66 that was trapped in a 1,3-dipolar cycloaddition by trifluoroacetophenone to generate 68." Other dipolarophiles reacted similarly. In the absence of a dipolarophile, cyclization of 66 yielded the isoindole 67 (Scheme 7.16 Table 7.11, Fig. 7.12). 

Phosphites and 2,2-bis(trifluoromethyl)-5(2//)-oxazolone 71 react with elimination of carbon dioxide to give 2-aza-4-phospha-l,l-bis(trifluoromethyl)-l,3-butadiene 72 that can be used as a synthon for the previously unknown hydrogen-substituted nitrile ylide 72a in [3 + 2]-cycloaddition reactions. Examples of cycloadditions of 72a with dipolarophiles to give heterocyclic compounds 12t-ll are shown in Scheme 7.18. 

The 4-phospha-1,3-butadiene 77/80 serves as an effective synthon for the unknown H-substituted nitrile ylide 79 in [3 + 2]-cycloaddition reactions with a range of electron-poor dipolarophiles (e.g., reaction with DMAD gave 78 in 80% yield). Similar yields were also obtained using methyl propiolate, azodicaboxylic esters, ethyl acrylate, and acrylonitrile (39). The reactant was generated under very mild conditions from 75 as shown below. 

Felhammer and co-workers (68-71) (and references cited therein) has shown that metal coordinated a-deprotonated isocyanides (e.g., 127 and 128) are genuine 1,3-dipoles of the nitrile ylide type that react with various dipolarophiles by [3 + 2]... 

Over the last 25 years both nitrile ylides and nitrile imines have continued to provide fascinating and synthetically useful chemistry. In both cases, the exploitation of [3 + 2]-cycloaddition chemistry with an increasing range of dipolarophiles has continued as a key route to five-membered heterocycles. The major development of new chemistry, however, has been in the extensive exploration of intramolecular reactions both in cycloaddition chemistry and in the electrocycliza-tion of 1,3-dipoles with extended conjugation. Such chemistry harnesses the unique reactivity of 1,3-dipoles in the synthesis of relatively elaborate structures but does require the design and preparation of quite complex reactants containing both the 1,3-dipole precursor and the dipolarophilic component. However, access to this chemistry is becoming much easier via the application of new synthetic procedures... 

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