Isoxazolines transformations

The following examples may illustrate the potentiaHty of the isoxazoHne methodology [329] utihzing characteristic isoxazoline transformations in organic syntheses. 

Nitrones or aci-nitro esters react with alkenes to give in some cases A/-substituted isoxazolidines and in others 2-isoxazolines. When the intermediate isoxazolidines were observed, a number of procedures transformed them into the 2-isoxazolines. Acrylonitrile and phenyl rzcf-nitrone esters produced an A/-methoxyisoxazolidine. Treatment with acid generated a 2-isoxazole while treatment with base generated an oxazine (Scheme 118) (68ZOR236). When an ethoxycarbonyl nitrone ester was reacted with alkenes, no intermediate isoxazolidine was observed, only A -isoxazolines. Other aci-mtro methyl esters used are shown in Scheme 118 and these generate IV-methoxyisoxazolidines or A -isoxazolines which can be further transformed (72MI41605). 

Earlier reported syntheses have been shown to give isoxazolin-5-ones. Other isoxazolin-3-ones have been prepared by the reaction of methylacetoacetic esters and hydroxylamine. An additional synthesis was reported by the action at 0°C of hydroxylamine on ethyl -benzoylpropionate to produce an insoluble hydroxamic acid which cyclized on acid treatment. The hydroxamic acid acetal was similarly transformed into the isoxazolin-3-one (Scheme 149) (71BSF3664, 70BSF1978). 

Nitronates derived from primary nitroalkanes can be regarded as a synthetic equivalent of nitrile oxides since the elimination of an alcohol molecule from nitronates adds one higher oxidation level leading to nitrile oxides. This direct / -elimination of nitronates is known to be facilitated in the presence of a Lewis acid or a base catalyst [66, 72, 73]. On the other hand, cycloaddition reactions of nitronates to alkene dipolarophiles produce N-alkoxy-substituted isoxazolidines as cycloadducts. Under acid-catalyzed conditions, these isoxazolidines can be transformed into 2-isoxazolines through a ready / -elimination, and 2-isoxazolines correspond to the cycloadducts of nitrile oxide cycloadditions to alkenes [74]. 

The synthesis of novel heterocycle-fused furo[3,4-d]isoxazoles via ring transformation of 2-isoxazoline-2-oxides by Lewis acids was reported <96H(42)289>. A practical application of the... 

The base-catalysed reaction of a-bromo-a,P-unsaturated ketones with aliphatic nitro compounds leads to 2-isoxazoline A-oxides by tandem conjugate addition-ring closure (Scheme 5) <95JOC6624>. A -Acyl-3-isoxazolin-5-ones are transformed into oxazoles by photolysis or by flash vacuum pyrolysis (Scheme 6) <96TL675>. 

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). 

Monoalkylation of Af-tosylallylamine 10 with dibromoalkane 101 proceeded in 60-90% yield (Eq. 10 see also Scheme 3 and Eq. 2) [17]. The bromoalkyl-amines 102 were converted to nitro compounds 103. In situ transformation of 103 into nitrile oxides led to spontaneous cycloaddition with formation of isox-azolines fused to 5-, 6-, and 7-membered ring heterocycles 104 a-c. Under very high dilution conditions, 103 d was converted to 104 d, an isoxazoline fused to an 8-membered azocine, in low (10%) yield. 

As we found that furan and thiophene substituted oximes can be used as substrates for the INOC reactions (Eq. 5) [29b] similarly, furan substituted nitro alkane 134 is also a good substrate for INOC reactions (Eq. 13) [40]. The furfuryl derivative 134, prepared via Michael addition of furfuryl alcohol to 4-methoxy- -nitrostyrene, was subsequently transformed without isolation of the intermediate nitrile oxide 135 to the triheterocyclic isoxazoline 136 as a 5 1 mixture of isomers in high yield. 

Although nitrile oxide cycloadditions have been extensively investigated, cycloadditions of silyl nitronates, synthetic equivalent of nitrile oxides in their reactions with olefins, have not received similar attention. Since we found that the initial cycloadducts, hl-silyloxyisoxazolidines, are formed with high degree of stereoselectivity and can be easily transformed into isoxazolines upon treatment with acid or TBAF, intramolecular silylnitronate-olefin cycloadditions (ISOC) have emerged as a superior alternative to their corresponding INOC reactions [43]. Furthermore, adaptability of ISOC reactions to one-pot tandem sequences involving 1,4-addition and ISOC as the key steps has recently been demonstrated [44]. 

Isoxazolines are valuable substrates in organic synthesis as they can be transformed into useful building blocks such as y-amino alcohols, 3-hydroxy ketones,... 

Isoxazolines are good precursors of a,(3-unsaturated ketones.63,94 This transformation is useful for synthesis of polyenes. For example, nitrile oxide cycloaddition chemistry is used to prepare 4-oxo-2-alkenylphosphonates, which are useful to synthesize a long polyethylenic unit via Woodworth-Emmons olefination (Eq. 8.66).101... 

This regioselectivity is practically not influenced by the nature of subsituent R. 3,5-Disubstituted isoxazolines are the sole or main products in [3 + 2] cycloaddition reactions of nitrile oxides with various monosubstituted ethylenes such as allylbenzene (99), methyl acrylate (105), acrylonitrile (105, 168), vinyl acetate (168) and diethyl vinylphosphonate (169). This is also the case for phenyl vinyl selenide (170), though subsequent oxidation—elimination leads to 3-substituted isoxazoles in a one-pot, two-step transformation. 1,1-Disubstituted ethylenes such as 2-methylene-1 -phenyl-1,3-butanedione, 2-methylene-1,3-diphenyl- 1,3-propa-nedione, 2-methylene-3-oxo-3-phenylpropanoates (171), 2-methylene-1,3-dichlo-ropropane, 2-methylenepropane-l,3-diol (172) and l,l-bis(diethoxyphosphoryl) ethylene (173) give the corresponding 3-R-5,5-disubstituted 4,5-dihydrooxazoles. 

A rapid access to carbocyclic nucleosides, containing a fused isoxazoline ring has been proposed, starting from cyclopentadiene. The route involves a het-ero Diels-Alder cycloaddition reaction of nitrosocarbonylbenzene followed by a 1,3-dipolar cycloaddition of nitrile oxides, cleavage of the N-0 tether and transformation of the heterocyclic aminols into nucleosides via construction of purine and pyrimidine heterocycles (457). 

Several SENAs derived from primary AN were involved in the reaction with ceptem (282) (Scheme 3.177, Eq. 1) (434) to prepare the diastereomeric pure cycloadducts, which were then transformed into isoxazolines (283). However, the configurations of the new stereocenters in products (283) were not determined. 

In the former case, both antipodes of sultams were used and the initially formed cycloadducts (288a-e) were transformed into more stable isoxazolines (289a-e) and (289 a-c) with retention of configuration of the new stereocenter at C-5. For Oppolzer s sultam, (435-437) the yields of the target products were high and the ratio of diastereomers was close to 1 10. 

The 1,3-dipolar cydoaddition reactions ([3-1-2]) are often used to synthesize five member aza- or azoxaheterocycles. Depending on the nature of the 1,3-dipoles employed in the transformation, different types of heterocycles such as isoxaza-zoles [270], isoxazolines (Scheme 3.22) [110], hydantoins [271], pyrrolidines [272], indolizines [273] or pyrazoles [274] are obtained. 

Intramolecular [3+2] dipolar cycloadditions have also been employed as a post-Ugi transformation to generate heterobicyclic structures, namely fused isoxazolines [130], isoxazoles [130] and triazoles [131] (Fig. 31). Isoxazoles were obtained through intramolecular nitrile oxide cycloaddition. The precursor of the nitrile oxide (a nitro group) was introduced into the carboxylic component, while a triple bond was positioned in the starting amine. Treatment of 152 with POCl3/Et3N gave the intermediate nitrile oxide, which spontaneously cyclized to isoxazoles 153. 

Acetylenic oximes undergo in a similar manner conversion to 3,5-disubstituted isoxazoles. Thus, oximes 195 in the system K2C03/Me0H at room temperature afforded isoxazoles 196 in excellent yields (equation 85). a, S-Unsaturated ketoximes 197 can be also easily transformed to the corresponding 5-arylisoxazoles 198 (yield up to 95%) by treatment with iodine and potassium iodide. The presence of isoxazoline was detected in the reaction mixture (equation 86) . a, S-Unsaturated ketoximes in the presence of palladium catalyst afforded isoxazolines . 

The [3 + 2] cycloaddition of silyl nitronates has been extensively investigated since the first pioneering studies by Ioffe et al. (16). This transformation is attractive because of the resulting isoxazolidine can be easily converted to the corresponding isoxazoline for which a myriad of transformations are known. Moreover, this procedure provides yields and selectivities different from those of the nitrile oxide [3 + 2] cycloaddition, which affords the isoxazoline directly. The reaction of silyl nitronates has been briefly reviewed in the context of the chemistry of nitronic acid derivatives (27,30). 

The A-silyloxy-isoxazolidine (XIX) provides several opportunities for further elaboration. One of the more common transformations is the elimination of silanol from the isoxazolidine (Scheme 2.9), which results in the formation of isoxazolines (XX), which are also prepared from the [3 + 2] cycloaddition of nitrile oxides... 

Talaromycin B is a spiro-acetal produced by the fungus Talaromyces stipitatus, the toxicity of which may be due to its ability to block outward potassium fluxes. In an elegant synthesis, the requisite open-chain polyol with hydroxy groups in the y-and y -positions was assembled from nitrile oxide and olefin building blocks 50 and 51, both of which carry a f>w(hydroxyethyl) moiety protected as a cyclohexanone acetal (284). Hydrogenolysis of the N O bond of isoxazoline 52 using Raney nickel, followed by treatment with aqueous acid, gave the spiroketal 53, which was further transformed into racemic talaromycin B (54) (Scheme 6.54) (284). 

Isoxazolines can be transformed into a,p-enones by several methods from the initial aldol product. This strategy was applied by Barco et al. (285) toward the synthesis of ( )-pyrenophorin (98), a macrocychc fow(enone-lactone) with antifungal properties. The hydroxy group was introduced from the nitrile oxide component (95), while the carboxy function was derived from the acrylate dipo-larophile. Thus, cycloaddition of the optically active nitropentyl acetate 94 to methyl acrylate 95 afforded isoxazoline 96 as a mixture of optically active diastereomers. Reductive hydrolysis using Raney nickel/acetic acid gave p-hydro-xyketone (97), which was subsequently utilized for the synthesis of (—)-pyreno-phorin (98) (Scheme 6.63) (285). 

In the great major tiy of applications that use the intramolecular nitrile oxide-alkene cycloaddition, the intention is to prepare intermediates for the synthesis of natural products or related compounds. The most popular transformations of these isoxazolines are the following ring cleavage modes ... 

Kozikowski and Stein (281) used the INOC strategy to prepare the 2-methyle-necyclopentanone derivative 172, which in turn was converted to sarkomycin (173), an antitumor agent (Scheme 6.81). The key step involved the treatment of nitroalkene 169 (obtained from bromide 168) with p-chlorophenyl isocyanate-triethylamine, which furnished a single diastereomeric isoxazoline 170 in 55% yield. This compound was transformed to the aldol product 171 by Raney nickel hydrogenation using wet acetic or boric acid, followed by dehydration to the a,p-enone 172 (281), a precursor of 173. 

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