Nitrile oxides synthesis from

Highly efficient modifications of Mukaiyama s procedure, convenient for combinatorial syntheses, were reported recently, namely the polymer-supported synthesis of isoxazolines via nitrile oxides, starting from primary nitroalkanes, in a one-pot process (75) and by microwave activation of the process (73). 

Intramolecular Cycloaddition Intramolecular nitrile oxide cycloaddition (INOC) is widely used in the synthesis of various compounds, particularly, natural products. This field is reviewed in detail in Chapter 6 of the mono-graph/Reference 5 and also in Reference 400 limited to nitrile oxides generated from nitroalkenes. Some features of INOC are illustrated in this subsection by new data and those omitted in Reference 5. 

The synthesis of new 11-deoxyprostaglandin analogs with a cyclopentane fragment in the oo-chain, prostanoid 418, has been accomplished by a reaction sequence involving nitrile oxide generation from the nitromethyl derivative of 2-(oo-carbomethoxyhexyl)-2-cyclopenten-l-one, its 1,3-cycloaddition to cyclopenten-l-one and reductive transformations of these cycloadducts (459). Diastereoisomers of a new prostanoid precursor 419 with a 4,5,6,6a-tetrahydro-3aH-cyclopent[d isoxazole fragment in the oo-chain have been synthesized. Reduction of 419 gives novel 11-deoxyprostanoids with modified a- and oo-chains (460). 

The formal total synthesis of the novel /3-lactam antibiotic thienamycin has been accomplished from an isoxazoline derivative generated by [3 + 2] dipolar cycloaddition <79H(l2)l 183). Reaction of the nitrile oxide derived from 3-nitropropanal dimethyl acetal with methyl crotonate gave the isoxazoline (477) regio- and stereo-selectively. The isoxazoline was converted to amino ester (478) by hydrogenation and then to /3-lactam (479) by ester saponification and ring closure with DCC. Treatment of (479) with p-nitrobenzyl chloroformate and reaction of the derived acetal (480) with excess N-p-nitrobenzyloxycar-bonylcysteamine gave thioacetal (481), a compound which has previously been converted into ( )-(8S )-thienamycin (Scheme 106). 

Solid-phase synthesis of 3-hydroxymethyl isoxazoles 17 was accomplished in acceptable yields and purity through 1,3-DC of different alkynes 15 to resin bound nitrile oxides, generated from nitro compounds 14 under Mukaiyama conditions. This method is robust enough to be carried out by an automated synthesiser <01TL4951>. 

As part of their solid- and solution-phase synthesis of novel hydantoin-isoxazoline containing hetero cycles, Kurth and co-workers reacted solid supported urea intermediates 48, possessing an alkene moiety with nitrile oxides derived from nitroalkanes 13a and 13d to afford isoxazolines 49 as a 1 1 mixture of diastereomers (Scheme 15) [109]. The urea fimctionality in 49 was then cyclized to obtain hydantoin 50. 

In a synthesis of flavanones [330], saUcylaldoxime (21) is converted to the hydrox-amic add chloride 22 by reaction with NCS. The nitrile oxide, formed from 22 on treatment with KHCO3, undergoes regioselective cycloaddition to styrene to afford the 3,5-diaryhsoxazohne 23. Catalytic hydrogenation of 23 leads to the fS-hydroxyketone 25, which after acid-catalyzed dehydration cydizes to the flavanone 24. 

Finally, the condensation of unsaturated compounds with fulminates known as the fulminic synthesis represents the simplest case of synthesis from nitrile oxides. Barnes has reviewed in detail the work carried out up to 1953 thus we shall be concerned here only wdth more recent publications or those of general interest. 

The first synthesis of a 3,5-diarylisoxazole from aryl hydroxamic acid chlorides and sodium phenyl acetylides was that effected by Weygand and Bauer in 1927. Beginning in 1946, when Quilico and Speroni showed that acid chlorides of hydroxamic acids on treatment with alkalies readily yielded nitrile oxides,numerous isoxazole and especially A -isoxazoline derivatives have been prepared. 

The cycloadducts formed from the Diels-Alder reaction of 3-amino-5-chloro-2(17/)-pyrazinones with methyl acrylate in toluene are subject to two alternative modes of ring transformation yielding either methyl 6-cyano-l,2-dihydro-2-oxo-4-pyridinecarboxylates or the corresponding 3-amino-6-cyano-l,2,5,6-tetrahydro-2-oxo-4-pyridinecarboxylates. From the latter compounds, 3-amino-2-pyridones can be generated through subsequent loss of HCN <96 JOC(61)304>. Synthesis of 3-spirocyclopropane-4-pyridone and furo[2,3-c]pyridine derivatives can be achieved by the thermal rearrangement of nitrone and nitrile oxide cycloadducts of bicyclopropylidene <96JCX (61)1665>. 

The versatility of the INOC reaction is evident from the synthesis of tetrahy-drofurans fused to an isoxazoline 22a-f (Eq. 3) [181. a-Allyloxyaldoximes 21, formed by the reduction of jS-nitrostyrenes 19 with SnCl2 2H2O in the presence of an unsaturated alcohol 20, are transformed to isoxazolines 22 in high yield on treatment with NaOCl via stereoselective ring closure of a nitrile oxide intermediate (Table 2). 

In the seven-step stereoselective total synthesis of ptilocaulin 44 [21 ], a potent antileukemic and antimicrobial agent isolated [22] from marine sponges, the oxime 36 was treated with NaOCl providing the tricyclic isoxazoline 38 in 89% yield without isolation of the nitrile oxide intermediate 37 (Scheme 5) [23]. Isoxazoline 38 was obtained as a mixture of four diastereomers and their ratio was... 

Although the unsaturated nitrile oxides 124 can be prepared via the aldoxime route (see Scheme 8), the older procedure suffers from the disadvantage that a tenfold excess of allyl alcohol and two additional steps are required when compared to Scheme 15. Therefore, unsaturated nitro ether 123 that can be prepared by condensation of an aldehyde 120 and a nitro alkane followed by Michael addition of alcohol 122, was a useful precursor to nitrile oxide 124 [381. The nitrile oxide 124 spontaneously cyclized to ether 125. This procedure is particularly suitable for the synthesis of tetrahydrofurans (125a-h) and tetrahydropyrans (125i-k) possessing Ar substituents in 72-95% yield (Table 12). The seven-membered ether 1251 was obtained only in 30% yield on high dilution. The acetylenic nitro ether 126 underwent INOC reaction to provide the isoxazole 127. 

The product of the reaction in Entry 8 was used in the synthesis of the alkaloid pseudotropine. The proper stereochemical orientation of the hydroxy group is determined by the structure of the oxazoline ring formed in the cycloaddition. Entry 9 portrays the early stages of synthesis of the biologically important molecule biotin. The reaction in Entry 10 was used to establish the carbocyclic skeleton and stereochemistry of a group of toxic indolizidine alkaloids found in dart poisons from frogs. Entry 11 involves generation of a nitrile oxide. Three other stereoisomers are possible. The observed isomer corresponds to approach from the less hindered convex face of the molecule. 

As discussed in Section 6.2, nitro compounds are good precursors of nitrile oxides, which are important dipoles in cycloadditions. The 1,3-dipolar cycloaddition of nitrile oxides with alkenes or alkynes provides a straightforward access to 2-isoxazolines or isoxazoles, respectively. A number of ring-cleaving procedures are applicable, such that various types of compounds may be obtained from the primary adducts (Scheme 8.18). There are many reports on synthetic applications of this reaction. The methods for generation of nitrile oxides and their reactions are discussed in Section 6.2. Recent synthetic applications and asymmetric synthesis using 1,3-dipolar cycloaddition of nitrile oxides are summarized in this section. 

Catalytic enantioselective crossed aldehyde-ketone benzoin cyclizations of ketoaldehydes, such as 13, readily obtained from an aryl nitrile oxide and a 1,3-diketone, were studied in order to perform the synthesis of complex molecules. Significant asymmetric induction was observed with chiral triazolium salts such as 14, in the presence of DBU as base, leading to compound 15 in high yield and with 99% ee in favor of the R enantiomer <06AG(E)3492>. 

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