1.3- Dipoles nitrile ylids

Similar cycloadditions between thiirene dioxides and 1,3-dipoles generated in situ give heterocycles which result from either loss of sulfur dioxide or from the three-membered ring opening of the initially formed adduct (e.g. 174). Such cycloadditions with nitrilium imides (173a) and nitrile ylids (173b) are illustrated in equation 69175. 

From a secondary amide, formation of a nitrile ylid because of plausible elimination of trimethylsilanol prior to cyclization might be expected. However, it is possible that this elimination occurs after cyclization. Thus, the true 1,3-dipole would be the imidate methylide. In any case, the final product will be a A -pyrroline.458... 

There are many types of 1,3-dipoles in addition to ozone (see Table 11.22).348 synthetically useful examples are diazoalkanes (427, secs. 13.9.B.ii, 13.9.C), nitrile ylids (428), nitrile oxides (429), azides (430),... 

Figure D.7 illustrates the application of the rules to delocalized systems A8a-1, A8b-1, A8c-1, A9a-1, A9b-1, and A9c-1. In particular, 1,3-dipoles are prominent members of the tricentric cases. Azomethine ylids, azomethine imines, nitrones, carbonyl ylids (e.g. A8c), carbonyl imines, carbonyl oxides fit prototype A8 bent nitrile ylids, may also be treated as A8. The linear 1,3-dipoles are treated as a triply-bonded systems with two mutually orthogonal sets of paired faces.

Fig. 2.3 shows the core structures of the most important 1,3-dipoles, and what they are all called. As with dienes, they can have electron-donating or withdrawing substituents attached at any of the atoms with a hydrogen atom in the core structure, and these modify the reactivity and selectivity that the dipoles show for different dipolarophiles. Some of the dipoles are stable compounds like ozone and diazomethane, or, suitably substituted, like azides, nitrones, and nitrile oxides. Others, like the ylids, imines, and carbonyl oxides, are reactive intermediates that have to be made in situ. Fig. 2.4 shows some examples of some common 1,3-dipolar cycloadditions, and Fig. 2.5 illustrates two of the many ways in which unstable dipoles can be prepared. 

Similarly, nitrile oxides react with methyl acrylate 2.42 to give the adduct 2.43 with the substituent on C-5 and terminal alkenes also react in this way to place the alkyl group on C-5. Many dipoles react well with electron-rich dipolarophiles, but not with electron-poor dipolarophiles. Other dipoles are the other way round. To make matters even more complex, the presence of substituents on the dipole can change these patterns and impart their own regioselectivity. Thus the carbonyl ylid reaction 2.45 has a well defined regiochemistry determined only by the substituents, since the core dipole is symmetrical. This reaction also illustrates the point that dipolarophiles do not have to be alkenes or alkynes—they can also have heteroatoms. 

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