Dipolarophiles oxygen

Heterocycles Both non-aromatic unsaturated heterocycles and heteroaromatic compounds are able to play the role of ethene dipolarophiles in reactions with nitrile oxides. 1,3-Dipolar cycloadditions of various unsaturated oxygen heterocycles are well documented. Thus, 2-furonitrile oxide and its 5-substituted derivatives give isoxazoline adducts, for example, 90, with 2,3- and 2,5-dihydro-furan, 2,3-dihydropyran, l,3-dioxep-5-ene, its 2-methyl- and 2-phenyl-substituted derivatives, 5,6-bis(methoxycarbonyl)-7-oxabicyclo[2.2.1]hept-2-ene, and 1,4-epoxy-l,4-dihydronaphthalene. Regio- and endo-exo stereoselectivities have also been determined (259). 

Besides the bond-pair cheletropic disconnection of oxiranes and aziridines to an alkene and "atomic oxygen" (from a carboxylic peracid) or a nitrene, respectively, and the hetero-Diels-Alder cycloreversion, of special interest are the 1,3-dipolar cycloeliminations of five-membered rings [-(34-2)] leading to 1,3-dipoles and an unsaturated acceptor or dipolarophile. So large is the number of different five-membered heterocyclic systems resulting from 1,3-dipolar... 

In 2008, Gong and coworkers introduced a new chiral bisphosphoric acid 19 (Fig. 4) that consists of two BINOL phosphates linked by an oxygen atom for a three-component 1,3-dipolar cycloaddition (Scheme 42) [66]. Aldehydes 40 reacted with a-amino esters 105 and maleates 106 in the presence of Brpnsted acid 19 (10 mol%) to afford pyrrolidines 107 as endo-diastereomers in high yields (67-97%) and enantioselectivities (76-99% ee). This protocol tolerated aromatic, a,P-unsaturated, and aliphatic aldehydes. Aminomalonates as well as phenylglycine esters could be employed as dipolarophiles. 

The oxygen atom has also been used to generate other functionalities, such as the aldehyde moiety in Kibayashi s syntheses of (—)-coniine (197) and its enantiomer (Scheme 1.43) (253). Here, reaction of tetrahydropyridine N-oxide 93 with a silylated chiral allyl ether dipolarophile 198 delivered the adduct 199 with the desired bridgehead stereochemistry via the inside alkoxy effect . Desilylation and hydrogenolytic N—O bond rupture with palladium(II) chloride provided the diol 200... 

Reactions of nitrile oxides with 1,1-disubstituted alkenes afford products in which the oxygen atom of the nitrile oxide gets attached to the most crowded carbon atom of the dipolarophile. This high regioselectivity does not seem to depend on the type of substituent present on the alkene (142-152). Some of the results cannot be satisfactorily interpreted on the basis of FMO theory (149,151). Both steric and electrostatic effects often counteract each other and contribute to the regioselectivity actually observed. With trisubstituted alkenes, the orientation of cycloaddition is apparently dominated by this phenomenon. The preference is for the more substituted carbon atom to end up at the 5-position of the heterocyclic product (153,154). However, cases of opposite regiodifferentiation are also found, in particular with donor-substituted alkenes (42,155-157) (Scheme 6.21). 

The regioselectivity of nitrone cycloadditions is usually effected by both steric and electronic factors. In nitrone cycloadditions of monosubstituted electron-deficient alkenes under thermal conditions, electronic control steers the nitrone oxygen to the (3-carbon of acceptor, whereas steric factors direct it to the a-carbon. Accordingly, a mixture of two regioisomers is produced under thermal conditions, as shown in Scheme 11.44 for dimethyl 2-oxo-3-butenylphosphonate. With Ti(0 i-Pr)2Cl2, which coordinates in a bidentate chelated fashion with this dipolarophile, only the 4-acyl regioisomer is produced (158). 

An alternative approach in the asymmetric catalysis in 1,3-dipole cycloaddition has been developed by Suga and coworkers. The achiral 1,3-dipole 106 was generated by intramolecular reaction of an Rh(ii) carbene complex with an ester carbonyl oxygen in the Rh2(OAc)4-catalyzed diazo decomposition of <9-methoxycarbonyl-o -diazoacetophenone 105 (Scheme 12). The asymmetric induction in the subsequent cycloaddition to G=G and G=N bond was achieved by chiral Lewis acid Sc(iii)-Pybox-/-Pr or Yb(iii)-Pybox-Ph, which can activate the dipolarophile through complexation. With this approach, up to 95% ee for G=0 bond addition and 96% ee for G=G bond addition have been obtained, respectively. ... 

When the diphenyl betaine 310 (R = Ph) is generated in acetic anhydride at 120°C in the absence of dipolarophile, a quantitative yield of 1,2-diphenylacenaphthylene (318 R = Ph) is obtained. This desulfurization occurs by initial valence tautomerism to the episulfide (317 R = Ph) which can be isolated in 40% yield if the reaction is performed at 100°C.2 The episulfide 317 (R = Ph) and the hydrocarbon 318 (R = Ph) are also produced by treating the sulfoxide 312 (R = Ph) with phenyllithium. In the presence of oxygen, 1,8-dibenzoylnaphthalene is also a major product, and these observations suggest that the mesomeric betaine 310 (R = Ph) is a common intermediate in these reactions. ... 

Phenylisatogen (108d) reacts with the dipolarophiles 121 regio-specifically to give isoxazolidines 122.73 The orientation of the cycloadducts is unexpected and provides an example of electron donation from oxygen, back polarization, directing the course of a... 

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