Isoxazolidines, reaction with

Isoxazolidine, 3-benzoyl-2-phenyl-reactions with bases, 6, 47 Isoxazolidine, 2-t-butyl-conformation, 6, 10 Isoxazolidine, 2-carbamoyl-3-hydroxy-... 

Isoxazolidine, 2-(trimethyIsiIyloxy)-5-methoxycarbonyl-reactions with acids, 6, 47... 

IsoxazoIidine-3,3-dicarboxylic acid, 2-methoxy-dimethyl ester reaction with bases, 6, 47 Isoxazolidine-3,5-diones synthesis, 6, 112, 113 Isoxazoli dines conformation, 6, 10 3,5-disubstituted synthesis, 6, 109 oxidation, 6, 45-46 PE spectra, 6, 5 photolysis, 6, 46 pyrolysis, 6, 46 reactions, 6, 45-47 with acetone, 6, 47 with bases, 6, 47 reduction, 6, 45 ring fission, S, 80 spectroscopy, 6, 6 synthesis, 6, 3, 108-112 thermochemistry, 6, 10 Isoxazolidin-3-ol synthesis, 6, 111 Isoxazolidin-5-oI synthesis, 6, 111... 

Reaction of porphyrins with nitrones has also been studied and the results obtained showed that this is a versatile approach leading to the synthesis of isoxazolidine fused-chlorins (Scheme 26). For instance, chlorin 74 was successfully prepared from the reaction of the jV-methylnitrone, generated in situ from JV-methyl hydroxylamine and paraformaldehyde, with porphyrin Id . It is important to note that bis-addition also took place, yielding exclusively bacteriochlorin type derivatives 76 and 77 (Figure 6). This result contrasts with those obtained in 1,3-DC reactions with azomethinic ylides where isobacteriochlorins were obtained preferentially. 

A-Unsubstituted isoxazolidines such as 65 undergo facile decarboxylative peptide couplings with a-keto acids <06JA1452>. The use of water as solvent or cosolvent was particularly beneficial for the formation of amides in high yields. The methyl a-keto esters obtained could be saponified to the corresponding a-keto acids, and the (i-peptide chain could then be extended by reaction with another isoxazolidine. 

Related to the nitrile oxide cycloadditions presented in Scheme 6.206 are 1,3-dipolar cycloaddition reactions of nitrones with alkenes leading to isoxazolidines. The group of Comes-Franchini has described cycloadditions of (Z)-a-phenyl-N-methylnitrone with allylic fluorides leading to enantiopure fluorine-containing isoxazolidines, and ultimately to amino polyols (Scheme 6.207) [374]. The reactions were carried out under solvent-free conditions in the presence of 5 mol% of either scandium(III) or indium(III) triflate. In the racemic series, an optimized 74% yield of an exo/endo mixture of cycloadducts was obtained within 15 min at 100 °C. In the case of the enantiopure allyl fluoride, a similar product distribution was achieved after 25 min at 100 °C. Reduction of the isoxazolidine cycloadducts with lithium aluminum hydride provided fluorinated enantiopure polyols of pharmaceutical interest possessing four stereocenters. 

Dipolar cycloaddition reactions between three A-benzyl-C-glycosyl nitrones and methyl acrylate afforded key intermediates for the synthesis of glyco-syl pyrrolidines. It was found that furanosyl nitrones (574) and (575) reacted with methyl acrylate to give mixtures of all possible 3,5-disubstituted isoxazolidines (577) and (578). On the other hand, the reaction with pyranosyl nitrone (576) was much more selective and cycloaddition at ambient temperatures afforded only one of the possible Re-endo adducts (579a). The obtained isoxazolidines were transformed into the corresponding (V-benzyl-3-hydroxy-2-pyrrolidinones (580—582) on treatment with Zn in acetic acid (Scheme 2.264) (773). 

Also, the effectiveness of 1,3-dipolar cycloadditions to a,p-unsaturated 8-lactones D7a, D7c, D7 d (784) and D7f, (785) in controlling the configuration of the stereogenic centers around the formed isoxazolidine ring, was demonstrated in reactions with nitrones (595). 

Both C-alkylation products and the corresponding O-alkyl nitronates were detected in the reaction mixture prepared by the reactions of above mentioned salt with primary alkyl halides (Scheme 3.9, Eq. 1). However, isoxazolidines (1) are the main identified products of the reactions with secondary or tertiary alkyl halides. The possible pathway of their formation is shown in Scheme 3.9. Here, the key event is generation of the corresponding olefins from alkyl halides. These olefins can be trapped with O-nitronates that are simultaneously formed in [3 + 2]-cycloaddition reactions. Presumably, these olefins are generated through deprotonation of stabilized cationic intermediates (see Scheme 3.9). 

The reactions of isoxazolidines (229) with nucleophiles are more complex. Generally, these processes have a pronounced induction period (174, 204). They can be described by the following formal scheme (Scheme 3.156). 

At the same time, the reactions of isoxazolidines (239) with soft acids and retain LA (157, 341, 398, 399) resemble an analogous process considered above for iV-siloxynitroso acetals, which also affords isoxazolines (240). Methanol can be eliminated from nitroso acetals (239) also upon heating (341). 

At the same time, nitrones can be trapped by external dipolarophiles to form isoxazolidines (325). In the reactions with N,0-bis(trimethylsilyl)acetamide... 

When N-phenyl-C-phenylnitrone was used as the 1,3-dipole in the reaction with activated allenes, benzazepin-4-ones 74 were obtained as the major product [74]. The isoxazolidine initially formed undergoes N-O bond cleavage and the resulting diradical recydizes by attack at the ortho-position of the N-phenyl group. 

Starting material which, upon oxidation with PSP, gave aldehydes. These were in turn condensed with primary hydroxylamines, promoted by polymer-bound acetate, to produce nitrones. The nitrones assembled using either method then underwent 1,3-dipolar cyclo-addition reactions with various alkenes to give the corresponding isoxazolidines (Scheme 2.46 and 2.47). 

It has been shown that phenylselenyl halides easily reacted with 0-allyl oximes 221 to give cyclic iminium salts 222, which by reaction with water afforded isoxazolidines 223 in moderate to good yields (equation 96) . Compounds 222 can be reduced in situ by sodium borohydride to produce Ai-alkyl-substituted isoxazolidines 224 in 50-95% yields . ... 

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). 

As part of an extensive study of the 1,3-dipolar cycloadditions of cyclic nitrones, Ali et al. (392-397) found that the reaction of the 1,4-oxazine 349 with various dipolarophiles afforded the expected isoxazolidinyloxazine adducts (Scheme 1.78) (398). In line with earlier results (399,400), oxidation of styrene-derived adduct 350 with m-CPBA facilitated N—O cleavage and further oxidation as above to afford a mixture of three compounds, an inseparable mixture of ketonitrone 351 and bicyclic hydroxylamine 352, along with aldonitrone 353 with a solvent-dependent ratio (401). These workers have prepared the analogous nitrones based on the 1,3-oxazine ring by oxidative cleavage of isoxazolidines to afford the hydroxylamine followed by a second oxidation with benzoquinone or Hg(ll) oxide (402-404). These dipoles, along with a more recently reported pyrazine nitrone (405), were aU used in successful cycloaddition reactions with alkenes. Elsewhere, the synthesis and cycloaddition reactions of related pyrazine-3-one nitrone 354 (406,407) or a benzoxazine-3-one dipolarophile 355 (408) have been reported. These workers have also reported the use of isoxazoles with an exocychc alkene in the preparation of spiro[isoxazolidine-5,4 -isoxazolines] (409). 

This chapter deals mainly with the 1,3-dipolar cycloaddition reactions of three 1,3-dipoles azomethine ylides, nitrile oxides, and nitrones. These three have been relatively well investigated, and examples of external reagent-mediated stereocontrolled cycloadditions of other 1,3-dipoles are quite limited. Both nitrile oxides and nitrones are 1,3-dipoles whose cycloaddition reactions with alkene dipolarophiles produce 2-isoxazolines and isoxazolidines, their dihydro derivatives. These two heterocycles have long been used as intermediates in a variety of synthetic applications because their rich functionality. When subjected to reductive cleavage of the N—O bonds of these heterocycles, for example, important building blocks such as p-hydroxy ketones (aldols), a,p-unsaturated ketones, y-amino alcohols, and so on are produced (7-12). Stereocontrolled and/or enantiocontrolled cycloadditions of nitrones are the most widely developed (6,13). Examples of enantioselective Lewis acid catalyzed 1,3-dipolar cycloadditions are summarized by J0rgensen in Chapter 12 of this book, and will not be discussed further here. 

Brandi and co-workers (271) applied the familiar a,p-unsaturated esters 158 and 159 in reactions with cychc nitrones. In these reactions, the isoxazolidine products were formed as intermediates, which immediately underwent N-alkylation to give tricyclic compounds. The reactions proceeded in both cases with moderate selectivities of 39% de for 158 and 57% de for 159. Most remarkably, the reactions proceeded with opposite face selectivity. 

The reactions of nitrones with 165 have been described (277-279). In the approach described by Koskinen and co-workers (279), the bulky nitrone 166 was used in a reaction with 165 to give a 20 1 mixture of 167 and an unidentified diastereomer (Note Opposite enantiomers are shown here). Reactions of less bulky nitrones gave lower selectivities (277,278). Kim et al. (280,281) described reactions of 165 with silyl nitronates (Scheme 12.52). The configuration of the direct isoxazolidine products was not determined. Instead, diastereoselectivities of 66-88% de of 169 were found after elimination of the silyloxy group. The reaction of various nitrile oxides proceeded to give the same isoxazoline products 169 as obtained for nitronates (Scheme 12.52). For the reactions of 165 with various alkyl and aryl nitrile oxides 170, the products 169 were obtained with diastereoselectivities of 62-90% de (282-286). In a theoretical study, it was proposed that the... 

Katagiri et al. (48,322,323) applied L-menthone and an in situ generated nitroso ketene for the synthesis of nitrone 212, as shown in Scheme 12.61. The nitrone showed high selectivities in reactions with various allyl silanes. High pressure or the presence of BF3 Et20 was required for the reaction to proceed. In the reaction of 212 with allyltrimethylsilane in the presence of BF3 -Et20, isoxazolidine (213) was obtained as the sole product. After hydrolysis and hydrogenolysis. 

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