Nitrile oxides with allylic ethers

Using a stoichiometric amount of (i ,i )-DIPT as the chiral auxiliary, optically active 2-isoxazolines can be obtained via asymmetric 1,3-dipolar addition of achiral allylic alcohols with nitrile oxides or nitrones bearing an electron-withdrawing group (Scheme 5-53).86a Furthermore, the catalytic 1,3-dipolar cycloaddition of nitrile oxide has been achieved by adding a small amount of 1,4-dioxane (Scheme 5-53, Eq. 3).86b The presence of ethereal compounds such as 1,4-dioxane is crucial for the reproducibly higher stereoselectivity. 

Nitrile oxides react with the methyl enol ethers of (Rs)-l -fluoro-alkyl-2-(p-tolylsulfinyl)ethanones to produce (45,5/f,/fs)-4,5-dihydroisoxazoles with high regio-and diastereo-selectivity.87 In the 1,3-dipolar cycloaddition of benzonitrile oxide with adamantane-2-thiones and 2-methyleneadamantanes, the favoured approach is syn, as predicted by the Cieplak s transition-state hyperconjugation model.88 The 1,3-dipolar cycloaddition reaction of acetonitrile oxide with bicyclo[2.2.l]hepta-2,5-diene yields two 1 1 adducts and four of six possible 2 1 adducts.89 Moderate catalytic efficiency, ligand acceleration effect, and concentration effect have been observed in the magnesium ion-mediated 1,3-dipolar cycloadditions of stable mesitonitrile oxide to allylic alcohols.90 The cycloaddition reactions of acryloyl derivatives of the Rebek imide benzoxazole with nitrile oxides are very stereoselective but show reaction rates and regioselectivities comparable to simple achiral models.91. 

A chiral zinc(II) complex derived from Et2Zn and diisopropyl (/ ,/ )-tartrate as a chiral auxiliary is applied to the asymmetric 1,3-dipolar cycloaddition of nitrile oxides to an achiral allylic alcohol, giving the corresponding (R)-2-isoxazolines with high enantioselectivity. Addition of a small amount of ethereal compounds such as DME and 1,4-dioxane is crucial for achieving the high asymmetric induction in a reproducible manner [71] (Eq. 8A.47). 

The cycloaddition of a nitrile oxide with a chiral allylic ether affords an isoxazoline with selectivity for the pre/-isomer. This selectivity increases with the size of the alkyl substituent and is insensitive to the size of the allyl oxygen substituent. However, allyl alcohols tend to form the / ar/ isomcr preferentially, although the selectivity is often low.427"434 The product of dipolar cycloadditions based on nitrile oxides, the isoxazoline moiety, can be converted into a large variety of functional groups under relatively mild conditions.3 Among other products, the addition can be used to prepare P-hydroxy ketones (Scheme 26.17).435 The isoxazoline moiety can be used to control the relative stereochemistry through chelation control.436,437... 

Fig. 3. Houk s "inside alkoxy model for the reaction of nitrile oxides with chiral allylic alcohols and ethers.

On the other hand, the ratio varies little with changes in electronic or steric demands of either the nitrile oxide substituent or the alkyl group attached to the oxygen of the allyl ether (Table 16).6S,66,68,69 Similar observations have been made when = Me, THP, OAc and SiRs. ... 

The inside alkoxy effect is useful for predicting the stereoselectivity of nitrile oxide cycloaddition reactions with chiral lylic ethers. The hypothesis states that allylic ethers adopt the inside position and alkyl substituents prefer the sterically less-crowded anti conformation in transition states for these electrophilic cycloadditions . The terms inside and outside are defined in (17) for a hypothetical nitrile oxide cycloaddition transition state. Both ab initio (Gaussian 80 with 3-2IG basis set) and molecular mechanics calculations agree, each predicting the lowest-energy transition state to be the one described, i.e. (18 H outside) just above it lies one where the alkyl group is anti, OR outside and H inside (19 ). As illustrated, the former leads to a product wherein OR and the nitrile oxide oxygen are anti, the latter to one with them syn (Scheme 19). 

The reaction of nitrile oxides prepared in situ by dehydration of aliphatic nitro compounds with triethylamine and phenyl isocyanate with allylic alcohols proceeds with low stereocontrol to give a predominance of the /-product. Allyl ethers as the dipolarophiles can lead to high excesses of the y-cycloadducts, with the stereoselection increasing with increasing bulkiness of the alkyl residue at the stereocenter. 

The selected examples by Studer et al. [97-99] reported the synthesis of two small, discrete libraries of isoxazolines (eight compounds) and of amides derived from a Ugi 4CC reaction (10 compounds). The synthesis of the tagging silicon derivative and the scheme for isoxazoline synthesis are reported in Figure 16. A known silane [100] was coupled quantitatively with bromine in the fluorinated solvent FC-72 [101] and the tagging reagent was used to protect and label the allyl alcohols in THF. After the cycloaddition of the fluorinated dipolarophiles with the nitrile oxides, the protected isoxazolines were finally cleaved with HF/pyridine complex in ethyl ether. The scheme of the purification for each synthetic step is depicted in Figure 17. 

The tricycle 139 (Scheme 28) has been previously prepared by intramolecular cyclization of a nitrile oxide with an allyl ether, and this compound has now been converted to 140, and hence, by intramolecular nitrone cyclization, into the tetracycle 141, containng an oxepinopyran ring system. A related cyclization of a nitrile oxide derived from 140 was also described, as were similar transformations from previously-reported cycloadducts with seven-membered rings (Vol. 28, p. 363), to give oxepinooxepanes. ... 

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