Heterocycles isoxazole

Similarly to derivatives phenylhydrazone, 1,4-dilithio oximes also react with an achiral ester to give a heterocyclic isoxazole ring102 (equation 33). When two of the a-carbons on an oxime of a ketone are able to undergo deprotonation, the question of the deprotonation site arises. It was found that the regioselectivity in the electrophilic reaction of 1,4-dilithioketoxime salts is especially high and the electrophile reacts with the carbon syn to the oximic oxygen. Kofron and Yeh proved that this is the case by... 

HETEROCYCLES - Isoxazoles can be formed regiospeclfIcally in good yields from oximes by first acylatlng the dillthlo salt with dialkylamldes, followed by quenching of the adduct with H2SO4. Stereochemistry of the ox-... 

Another early example that followed the discovery of CuAAC, the copper-catalyzed reaction of nitrile oxides, is shown in Scheme 10.9. Similarly to azides, the uncatalyzed 1,3-dipolar cycloaddition of nitrile oxides and acetylenes has long been known, but its applications to the synthesis of the corresponding heterocycle (isoxazoles) are scarce. Yields of isoxazole products are often quite low, side reactions are common, and both regioisomers may be formed (although the selectivity of nitrile oxide cycloadditions is usually higher than in reactions of azides, favoring the 3,5-isomer) [127]. Furthermore, nitrile oxides are not very stable and readily dimerize. 

The use of oximes as nucleophiles can be quite perplexing in view of the fact that nitrogen or oxygen may react. Alkylation of hydroxylamines can therefore be a very complex process which is largely dependent on the steric factors associated with the educts. Reproducible and predictable results are obtained in intramolecular reactions between oximes and electrophilic carbon atoms. Amides, halides, nitriles, and ketones have been used as electrophiles, and various heterocycles such as quinazoline N-oxide, benzodiayepines, and isoxazoles have been obtained in excellent yields under appropriate reaction conditions. 

There are several examples of the formation of pyridazines from other heterocycles, such as azirines, furans, pyrroles, isoxazoles, pyrazoles or pyrans and by ring contraction of 1,2-diazepines. Their formation is mentioned in Section 2.12.6.3.2. 

Details of bond lengths and bond angles for all the X-ray structures of heterocyclic compounds through 1970 are listed in Physical Methods in Heterocyclic Chemistry , volume 5. This compilation contains many examples for five-membered rings containing two heteroatoms, particularly pyrazoles, imidazoles, Isoxazoles, oxazoles, isothlazoles, thlazoles, 1,2-dlthloles and 1,3-dlthloles. Further examples of more recent measurements on these heterocyclic compounds can be found in the monograph chapters. 

In general, the solubility of heterocyclic compounds in water (Table 33) is enhanced by the possibility of hydrogen bonding. Pyridine-like nitrogen atoms facilitate this (compare benzene and pyridine). In the same way, oxazole is miscible with water, and isoxazole is very soluble, more so than furan. 

Oxygen-containing rings can be opened by amines frequently this is followed by reclosure of the intermediate to form a new heterocycle. Thus isoxazoles containing electron-with-drawing substituents give pyrazoles with hydrazine, e.g. (183 Z = O) (183 Z = NH), and... 

In theory, three isoxazolines are capable of existence 2-isoxazoline (2), 3-isoxazoline and 4-isoxazoline. The position of the double bond may also be designated by the use of the prefix A with an appropriate numerical superscript. Of these only the 2-isoxazolines have been investigated in any detail. The preparation of the first isoxazoline, 3,5-diphenyl-2-isoxazoline, from the reaction of )3-chloro-)3-phenylpropiophenone with hydroxylamine was reported in 1895 (1895CB957). Two major syntheses of 2-isoxazolines are the cycloaddition of nitrile A-oxides to alkenes and the reaction of a,/3-unsaturated ketones with hydroxylamine. Since 2-isoxazolines are readily oxidized to isoxazoles and possess some of the unique properties of isoxazoles, they also serve as key intermediates for the synthesis of other heterocycles and natural products. 

Theoretical and structural studies have been briefly reviewed as late as 1979 (79AHC(25)147) (discussed were the aromaticity, basicity, thermodynamic properties, molecular dimensions and tautomeric properties ) and also in the early 1960s (63ahC(2)365, 62hC(17)1, p. 117). Significant new data have not been added but refinements in the data have been recorded. Tables on electron density, density, refractive indexes, molar refractivity, surface data and dissociation constants of isoxazole and its derivatives have been compiled (62HC(17)l,p. 177). Short reviews on all aspects of the physical properties as applied to isoxazoles have appeared in the series Physical Methods in Heterocyclic Chemistry (1963-1976, vols. 1-6). 

A Hiickel model used for calculating aromaticity indicated that the isoxazole nucleus is considerably less aromatic than other five-membered heterocycles, including oxazole and furan. SCF calculations predicted that isoxazole is similar to oxazole. Experimental findings are somewhat difficult to correlate with calculations (79AHC(25)147). PRDDO calculations were compared with ab initio values and good agreement for the MO values was reported... 

Prototropic tautomerism of isoxazole derivatives has been well studied over a number of years and has recently been reviewed in context with similar behavior in other five-membered heterocycles (70C134, 76AHC(Sl)l, 79AHC(25)147, p. 202). Several generalizations are summarized below. 

Benzisoxazoles undergo electrophilic substitution in the benzo ring, but with nucleophiles the reaction occurs in the isoxazole moiety, often leading to salicylonitriles with 3-unsubstituted systems. The isomeric 2,1-benzisoxazoles are characterized by the ease with which they may be converted into other heterocyclic systems. 

The reactivities of the isoxazoles are compared with those of benzene and some five-membered ring heterocycles in Table 7. Isoxazole is more reactive than benzene (by 4.3 log units) and isothiazole (0.8) and is less reactive than 1-methylpyrazole, furan, thiophene and 1-methylpyrrole. A 5-methyl substituent activates the nucleus more than does a... 

The stability of various heterocycles can be also compared using oxidation procedures. Thus, the oxidation of the heterocycles in Scheme 29 with potassium permanganate showed that under these reaction conditions the isoxazole ring is more stable than the furan ring but less stable than the pyrazole and furazan rings. 

The importance of this group of reactions to the chemistry of isoxazoles is shown by the considerable amount of effort expended on this topic (63AHC(2)365,79AHC(25)147). The lability of the isoxazole nucleus towards nucleophiles and bases distinguishes this heterocycle from other azoles. The conditions which lead to ring cleavage are quite varied and depend on the position and the nature of the substituents. 

Isoxazoles are readily cleaved under reducing conditions, and many examples have been reported (79AHC(25)147,63AHC(2)365). In the last three decades the potential of these reactions in synthesis has finally been realized, and the isoxazole ring has become a major tool as a masked enaminone (137) or 1,3-diketone, particularly for the synthesis of heterocycles. 

Applications of the isoxazole ring as a masked enaminone for the synthesis of various heterocycles are shown in Scheme 38. 

Ring transformations of heterocycles leading to isoxazoles have been briefly reviewed (79AHC(25)147). The heterocycles undergoing such transformations may be divided into three classes. 

Heterocycles which provide the NOC or CNO component synthon Isoxazoles can be prepared by the thermal or photolytic cleavage of a number of heterocycles, such as 1,3,5-dioxazolidone, furazans, furoxans and 1,3,2,4-dioxathiazole 2-oxides, in the presence of a reactive alkene or alkyne. 

Other heterocycles which rearrange to isoxazoles are pyridazine 1,2-dioxides (77CC856) and pyridinium salts (80CPB2083), although these transformations are of little synthetic importance. 

Oxidation and reduction can initiate changes leading to heterocycle-heterocycle conversions. The reaction of tetraphenylfuran with singlet oxygen (Scheme 34) (B-73MI50303) and that of isoxazoles with LAH (Scheme 35) are examples. 

Cyclopent-2-en-l-one, 2-hydroxy-3-methyl-synthesis, 3, 693 Cyclopentenone, 4-methoxy-formation, 1, 423 Cyclopenthiazide as diuretic, 1, 174 Cyclopent[2,3-d]isoxazol-4-one structure, 6, 975 Cyclophane conformation, 2, 115 photoelectron spectroscopy, 2, 140 [2,2]Cyclophane conformation, 2, 115 Cyclophanes nomenclature, 1, 27 Cyclophosphamide as pharmaceutical, 1, 157 reviews, 1, 496 Cyclopiloselloidin synthesis, 3, 743 Cyclopolymerization heterocycle-forming, 1, 292-293 6H-Cyclopropa[5a,6a]pyrazolo[l,5-a]pyrimidine pyrazoles from, 5, 285 Cydopropabenzopyran synthesis, 3, 700 Cyclopropachromenes synthesis, 3, 671 Cyclopropa[c]dnnolines synthesis, 7, 597 Cyclopropanation by carbenes... 

Furazano[3,4-/]quinoxaline, 7,8-diphenyl-synthesis, 6, 412 Furazanothiophene synthesis, 6, 417 Furazans, 6, 393-426 biological activity, 6, 425 bond angles, 6, 396 bond lengths, 6, 396 coordination compounds, 6, 403 diamagnetic susceptibilities, 6, 395 dipole moments, 6, 395, 400 heats of combustion, 6, 400 heterocyclic ring reactions, 6, 400-403 IR spectra, 6, 398 isoxazoles from, 6, 81 mass spectra, 6, 399 microwave spectroscopy, 6, 395, 396 MO calculations, 6, 395 monosubstituted... 

For such purposes as locating substituents, monocyclic heterocycles having only one non-carbon atom are numbered starting with the hetero atom as 1. If there is more than one hetero atom of the same kind, the more saturated hetero atom takes precedence (cf. imidazole in Table 1). In isoxazole and isothiazole, the divalent atom takes precedence, in conformity with the pnaciples of the Hantzsch-Widman system (Section 1.02.2.2). 

The mononuclear heterocyclic rearrangement (MHR) of isoxazole-3-amidoxime 108 in the presence of a base and hydroxylamine with concomitant removal of the amide moiety affords furazan acetaldoxime 109 (Scheme 56) (91CHE651, 91KGS827). 

First we consider diacetylene transformations leading to fundamental heterocycles (pyrroles, thiophene, selenophene, tellurophenes, pyrazoles, isoxazoles, pyridines, pyrimidines). Then cyclization reactions involving 1-heterobut-l-en-3-ynes, 4-heterobut-3-en-2-ones, and 4-heterobut-3-yn-2-ones (91UK103 92KGS867 00UK642) as diacetylene equivalents are discussed. 

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