Intermolecular cycloadditions nitrone isoxazolidines

The intermolecular cycloaddition route to spirocyclopropyl isoxazolidines and their subsequent rearrangement, used so widely by Brandi and co-workers (372-375) (Schemes 1.16 and 1.17, Section 1.5), has also been achieved in an intramolecular sense (Scheme 1.72). Cycloaddition of the alkenyl nitrone reagents (333a-c) afforded bicyclic isoxazolidinyl adducts 334, which rearranged under thermolysis in analogous fashion to the earlier work to give piperidinones (335) via... 

A. Isoxazolidines from Intermolecular Cycloaddition between Nitrones... 

Dipolar cycloaddition reactions occurreadily even with non-activated dipo-larophiles, such as isolated alkenes. This contrasts with the Diels-Alder reaction, particularly for intermolecular reactions, in which an activated alkene as the dienophile is required. Like the Diels-Alder reaction, [3+2] cycloaddition reactions of 1,3-dipoles are reversible, although in most cases it is the kinetic product that is isolated. For the intermolecular cycloaddition of nitrile oxides or nitrones, two of the most frequently used 1,3-dipoles, to monosubstituted or 1,1-disubstituted alkenes (except highly electron-deficient alkenes), the oxygen atom of the 1,3-dipole becomes attached to the more highly substituted carbon atom of the alkene double bond. Hence the 5-substituted isoxazolidine 206 is generated from the cycloaddition of the cyclic nitrone 205 with propene (3.136). Reductive... 

In a manner different from Zhu s, Rueping and coworkers [17] utilized -substituted hydroxylamines 32 as starting materials for the generation of the key intermediate nitrones 35 under visible-light-induced aerobic oxidation conditions (Scheme 13.6). Following intermolecular cycloaddition with 33, intermediate 35 was transformed into a range of isoxazolidines. Three possible pathways for the formation of the nitrone intermediate were proposed, and none could be ruled out. 

Recently, dipolarophile 1)13 (fumaronitrile) (777) has been used in the synthesis of indolizine lactone (677). Both, intermolecular and intramolecular cycloadditions were studied. Intermolecular 1,3-cycloaddition of nitrone (671) to D13 led to the formation of isoxazolidine (672). Subsequent deprotection and esterification of the obtained alcohol (673) with (674) gave isoxazolidine (675) in 65% yield. Ester (675), when refluxed in xylene for 10 min, after elimination of fumaronitrile by cyclo-reversion, underwent spontaneously intramolecular cycloaddition to give the tricyclic cycloadduct (676) in 84% yield (Scheme 2.291). 

Isoxazolidines from Intermolecular Nitrone Cycloaddition Reactions. 59... 

Elsewhere, Heaney et al. (313-315) found that alkenyloximes (e.g., 285), may react in a number of ways including formation of cyclic nitrones by the 1,3-APT reaction (Scheme 1.60). The benzodiazepinone nitrones (286) formed by the intramolecular 1,3-APT will undergo an intermolecular dipolar cycloaddition reaction with an external dipolarophile to afford five,seven,six-membered tricyclic adducts (287). Alternatively, the oximes may equilibrate to the corresponding N—H nitrones (288) and undergo intramolecular cycloaddition with the alkenyl function to afford five,six,six-membered tricyclic isoxazolidine adducts (289, R = H see also Section 1.11.2). In the presence of an electron-deficient alkene such as methyl vinyl ketone, the nitrogen of oxime 285 may be alkylated via the acyclic version of the 1,3-APT reaction and thus afford the N-alkylated nitrone 290 and the corresponding adduct 291. In more recent work, they prepared the related pyrimidodiazepine N-oxides by oxime-alkene cyclization for subsequent cycloaddition reactions (316). Related nitrones have been prepared by a number of workers by the more familiar route of condensation with alkylhydroxylamines (Scheme 1.67, Section 1.11.3). 

Cyclopentyl isoxazolidine cycloadduct 324 was prepared by intramolecular nitrone cycloaddition by Baldwin et al. (280,281,352,353) as part of studies toward a total synthesis of pretazettine (Scheme 1.69). Related adducts have been prepared elsewhere (354—356) including fluorine-substituted carbocycles (357) and the adducts prepared by lOAC by Shipman and co-workers (333,334) who demonstrated their potential as a route to aminocyclopentitols (Scheme 1.66, Section 1.11.2). Such bicyclic structures have been prepared in rather unique intermolecular fashion by Chandrasekhar and co-workers (357a) from the cycloaddition of C,N-diphenyl nitrone to fulvene (325). 

In constrast with intermolecular nitrone cycloadditions to alkynes and allenes, very little work has been done on the corresponding intramolecular cycloadditions. The bicyclic isoxazolidines (65a-b) were reported as products from reaction of an alkynone with methylhydroxylamine in ethanol.26b Presumably the initial strained bridgehead C—C double bond of the AMsoxazoline added ethanol under the reaction conditions. Cyclization of an allenyl ketone with methylhydroxylamine in ethanol solution also led to isoxazolidines (65a-b) as the major products and isoxazolidine (66) as a minor product.266 Thus, preferential cyclization to the internal C—-C double bond of the allene occurred followed by addition of ethanol to the exocyclic C—C double bond of the methyleneisoxazolidine intermediate. 

Discussion on synthesis of selected examples in this section is arranged as follows most common methods for monocyclic, bi/tri/tetracyclic, spiral isoxazolidines and less common methods for all known isoxazolidines. Monocyclic isoxazolidine with a variety of substituents (273)-(281) are synthesized mostly from C,A-diphenyl nitrone (265) with the corresponding alkenes (266)-(272) via intermolecular 1,3-dipolar cycloaddition (Equations (47)-(53)). Monocyclic isoxazolidines are also... 

Abstract This review is devoted to the stereoselectivity of intermolecular (intramolecular cycloadditions are not included) 1,3-dipolar cycloadditions of sugar-derived nitrones. Stereoselective cycloaddition (transformation of isoxazolidine followed by reduction of the N O bond to produce both an amino and a hydroxy function) allows the synthesis of tailor-made products of possible biological interest such as pol>4iydroxylated pyrrolidines, pyrrolizidines, indolizidines, fi-aminocarbonyl compounds, and disaccharides. Attention is focused on the preparation of isoxazolidinyl nucleosides and to the catalysis of the cycloaddition by Lewis acids. This review has concentrated on the new developments achieved from 1999 to February 2007. 

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