Isoxazolidines reduction

Sodium borohydride and 3-isoxazolium salts with a 3-unsubstituted position also give isoxazolines, as do the 3-substituted 5-unsubstituted derivatives. With the latter group, further reduction occurs to the isoxazolidines (74CPB70). 

The reduction of 3,5-diphenylisoxazoline with sodium cyanoborohydride produced a mixture of isomeric 3,5-diphenylisoxazolidines. The H and NMR spectra were utilized to distinguish the isomers SOLAIOI). Sodium borohydride reductions likewise reduce isoxazolines to isoxazolidines (equation 56) (80JA4265). 

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... 

The mechanism of 1,3-dipolar cycloaddition can be found in Ref. 63 and the references within. The reaction of nitrone with 1,2-disubstituted alkenes creates three contiguous asymmetric centers, in which the geometric relationship of the substituents of alkenes is retained. The synthetic utility of nitrone adducts is mainly due to their conversion into various important compounds. For instance, P-amino alcohols can be obtained from isoxazolidines by reduction with H2-Pd or Raney Ni with retention of configuration at the chiral center (Eq. 8.44). 

Typically, isoxazolidines are employed as masked (3-amino alcohols which can be released under mild reduction conditions, but other different transformations leading to a variety of useful functionalities are also available as shown by some of the following examples. The... 

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. 

The addition of nitrones (647) and (312) to 4-pentenofuranoside (648) derived from D-ribose, followed by reductive opening of the isoxazolidine ring in (649)... 

Conversion of isoxazolidines to the corresponding /V-methyl 7-aminoalcohols was achieved by methylation with Mel followed by reduction with Zn in acetic acid or hydrogenation over Pd/C (Equation 25) <1997TA293>. 

The reductive cleavage of the N-O bond in the isoxazolidine 162 unmasks the 1,3-amino alcohol moiety. Thus, isoxazolidines can be viewed as direct precursors of 7-amino alcohols. The reductive cleavage of the cycloadduct proved difficult. W2 Raney-Ni and nickel boride were both ineffective. In contrast, nickel-aliminium alloy in an alkaline medium efficiently reduced the N-O bond at room temperature in the presence of a base (Equation 27) <1997TA109>. 

Isoxazolinium salts represent potentially versatile intermediates for synthesis, even though relatively few transformations of these salts are known (347-350) and synthetic uses so far have been scarce (349,350). A notable exception involves the use of an A-methylisoxazolinium salt. Its reduction to an isoxazolidine, and... 

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. 

N—O bond of the isoxazolidine is reductively cleaved. A sequence of translacto-nization, mesylation, and homolytic reduction leads to the lactone form of the target amino acid. 

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