Cycloaddition reactions oxazolones

The 3-acyl-2(3F/)-oxazolones function as good dienophiles in cycloaddition reactions with cyclic 2,4-dienes such as cyclopentadienes and anthracenes. Thus, the thermal reaction of 3-acetyl-2(37/)-oxazolone with cyclopentadiene and the hexachloro and hexamethyl derivatives gives endo-cycloadducts exclusively. In particular, the chiral cycloadducts 221 and 223 derived from the diastereoselective Diels-Alder reactions of 3-(2-exo-alkoxy-l-apocamphanecarbonyl)-2(3/7)-oxazo-lones with hexamethylcyclopentadiene and 9,10-dimethylanthracene, respectively, are highly useful as chiral 2-oxazolidinone auxiliaries. The conformationally rigid roofed structures play a crucial role in affording excellent chiral induction (Fig. 5.54). 

Phosphites and 2,2-bis(trifluoromethyl)-5(2//)-oxazolone 71 react with elimination of carbon dioxide to give 2-aza-4-phospha-l,l-bis(trifluoromethyl)-l,3-butadiene 72 that can be used as a synthon for the previously unknown hydrogen-substituted nitrile ylide 72a in [3 + 2]-cycloaddition reactions. Examples of cycloadditions of 72a with dipolarophiles to give heterocyclic compounds 12t-ll are shown in Scheme 7.18. 

A new and completely different methodology involving a cycloaddition reaction has been described. The reaction between diphenylketene, ferf-butylcyanoketene or dimethylketene with 2,4,6-trimethylbenzonitrile A-oxide gave the corresponding 5(4//)-oxazolones 107 in moderate yields (Scheme 7.30). 

One strategy to prepare saturated 5(4//)-oxazolones from unsaturated oxazo-lones takes advantage of the reactivity of the exocyclic double bond. In this context, numerous reactions have been explored including reductions, Michael reactions, cycloaddition reactions, and many others. These reactions will be discussed in the context of the reactivity of the exocyclic double bond of the unsaturated oxazolones and will be described in Section 7.4.3. 

Mesoionic oxazolones (munchnones) 297 can be generated by cyclodehydration of N-substituted a-amino acids 295 or by alkylation of oxazolones 296 (Scheme 7.98). These compounds are reactive and versatile 1,3-dipoles that undergo cycloaddition reactions with dipolarophiles to generate a variety of heterocyclic systems. In particular, this is an extremely versatile methodology to prepare pyrroles that result from elimination of carbon dioxide from the initial cycloadduct. Numerous examples have appeared in the literature in recent years and several have been selected for discussion. The reader should consult Part A, Chapter 4 for an extensive discussion and additional examples. 

Cycloaddition reactions of A -(phenylmethylene)benzenesulfonamide with meso-ionic oxazolones 311 produces 2,5-disubstituted imidazoles 313 in a highly regio-selective process via cycloreversion of cycloadduct 312 and subsequent loss of benzenesulhnic acid. 

TABLE 7.29. PYRIMIDIN-6-ONES EROM CYCLOADDITION REACTIONS OF SATURATED 5(4i7)-OXAZOLONES WITH 1,3-DIAZADIENES ... 

The exocyclic double bond of 4-arylidene-5(47/)oxazolones 383 reacts with diazomethane in a 1,3-dipolar cycloaddition reaction to give the corresponding... 

TABLE 7.47. OXAZOLONE SPIROCYCLOPROPANES FROM 1,3-DIPOLAR CYCLOADDITION REACTION OF UNSATURATED 5(4/7)-OXAZOLONES WITH DIAZOMETHANE... 

The reaction of nitrile oxides with 4-arylmethylene-5(4//)-oxazolones 675 to give the corresponding spiroisoxazoline oxazolones 676 is also well known.The regiochemistry of this cycloaddition reaction was initially incorrectly assigned but a careful study of the reaction showed that the regiochemistry of the 1,3-dipolar cycloaddition of nitrile oxides is the same as that observed with nitrile imines (Scheme 7.213). Examples of spiroisoxazoline oxazolones are shown in Table 7.49 (Fig. 7.60). 

Both reactions have been utilized to prepare heterocyclic compounds such as pyrazoles 681 (X = A -Ph) and isoxazoles 681 (X = O) as shown in Scheme 7.214. " Starting from an unsaturated 5(4//)-oxazolone 677, either a cycloaddition-ring-opening reaction sequence (677 678 680) or a ringopening-cycloaddition reaction sequence (677 679 680) affords the same product. 

Diels-Alder reactions of 4-heteromethylene-5(4/7)-oxazolones have been described. ( )-4-(Chloromethylene)-5(4//)-oxazolone 737 reacts with 2,3-dunethyl-butadiene in the presence of ethylaluminum dichloride to afford the cycloadduct 738. The cycloaddition reaction is characterized by high diastereoselectivity and occurs without appreciable isomerization of the dienophile. Further synthetic transformations of 738 yield 1-amino-3,4-dimethyl-6-hydroxy-cyclohex-3-enecar-boxylic acid 739 (Scheme 1.121) Examples of Diels-Alder reactions of acyclic dienes and unsaturated 5(4//)-oxazolones are shown in Table 7.50 (Fig. 7.61). 

TABLE 7.28 2-PYRIDONES FROM CYCLOADDITION REACTIONS OF SATURATED 5(4//)-OXAZOLONES WITH I-AZADIENES, 199... 

The chemistry of oxazolones, particularly that of 5(AH)-oxazolones (104), is full of interest. These compounds are attacked by some nucleophiles at C(2) (c/. 105), but fission of the carbonyl-oxygen bond (c/. 106), leading to ar-amino acids or their derivatives, is more usual. 5(4H)-Oxazolones react with electrophiles at C(4) or, less commonly, at C(2) by way of the resonance-stabilized anions (107), and they can function as tautomeric 1,3-dipoles (108) in cycloaddition reactions. 

Anhydro-4-hydroxyoxazoIium hydroxides, such as compound (231), behave as carbonyl ylides (232) in cycloaddition reactions, yielding bicyclic adducts with alkenes and carbonyl compounds (Scheme 24). The adducts produced by combination with alkynes fragment spontaneously in a retro-Diels-Alder reaction, giving furans (equation 57). The formation of a furan by the action of DMAD on the 4(5//)-oxazolone (233) shows that the latter exists in equilibrium with the mesoionic tautomer (234 equation 58) (79JOC626). 

The 4,5-double bond of 2(3//)-oxazolones participates in thermal [4 + 2] cycloaddition reactions. With dialkyl azodicarboxylates the addition occurs at 80 C to give the cycloadducts 430 (Scheme 97). With a chiral substituent attached to N(3), diastereoselectivities as high as 72% can be obtained. Cycloadditions with cyclopentadiene or benzofuran require higher temperatures and longer reaction times, but can yield highly efficient chiral oxazolidin-2-one auxiliaries. 

The exo double bond of 4-alkylidene and 4-arylidene-5(4//)-oxazolones undergoes cycloaddition reactions with 1,3-dipolar reagents. For example, nitrile oxides add to 2-phenyl-4-ethoxymethylene-5(4//)-oxazolone (88) to give spirocyclic products that may be hydrolyzed to 4-aminoisooxazoles... 

There are general reviews on heterocyclic syntheses by cycloaddition reactions of isocyanates and on the use of heterocyclic cations in preparative organic chemistry. More specific topics are 5-hydroxymethylfuran-2-carb-aldehyde, isobenzofurans and related ort/io-quinonoid systems, the conversion of 2//-cyclohepta[Zj] furan-2-one (1) into derivatives of azulene, the synthesis of indoles from o-alkylphenyl isocyanides, and abnormal Fischer indolization reactions of o-methoxyphenylhydrazones. Two reviews on isoindoles have appeared and a lecture on highly conducting charge-transfer complexes that are based on heterocyclic selenium and tellurium donors has been reprinted.Recent advances in the chemistry of imidazole and in the use of nitro-imidazoles as radiosensitizers have been summarized. There have been reviews on benzimidazole A -oxides and on dihydrobenzimidazoles, benzimidazolones, benzimidazolethiones, and related compounds. Other topics are synthetic applications of 1,3-dithiolium and 1,3-oxathiolium salts and of isoxazoles, the chemistry of benzisoxazoles, 2-amino-oxazoles, 5-oxazolones (2), furoxans, benzofuroxans, and related systems, the synthesis of five-membered meso-ionic compounds, and tetrazoles. ... 

In a more recent variant by Gelmi et al. [80], 5(4H)-oxazolones 143 and munchnones 144 were used as sources for 1,3-dipoles in thermal cycloaddition reactions with phosphonium salt 128. 3-Methylpyrroles and 3-pyrrole carboxylic acids were obtained likewise from substituted vinylphos-phonium salts. The cycloaddition reactions proceed with high regioselectivity (Scheme 30). 

Diethylamino-4-(4-methoxyphenyl)-isothiazole 5,5-dioxide 6 is (95T(51)2455) a highly reactive partner in 1,3-dipolar cycloadditions with several dipoles. Azomethine yhdes, such as oxazolones 7 and miinchnones 8, afforded with 6 bicychc pyrrolo[3,4-d]isothiazole 5,5-dioxides 9, 10, 11 in satisfactory yield. The regioselectivity of the reaction was excellent. The thermal behavior of these new bicychc systems was investigated. When heated at their melting point or shghtly above, triarylpyrroles 12, 13 were obtained through SOj and AtiV-diethylcyanamide ehmination. 

The reaction of 5(4H)-oxazolones (32) and miinchnones with triphenylvinylphos-phonium bromide (33) provides a mild synthesis of substituted pyrroles (34) (Scheme 11). The cycloaddition-elimination reactions of 5-imino-l,2,4-thiadiazolidin-3-ones with enamines and ester enolates produce 2-iminothiazolidines. " Chiral isomtinchnone dipoles show jr-facial diastereoselectivity with IV-phenyl- or A -methyl-maleimide in refluxing benzene. ... 

An extensive review of the use of chiral Lewis acid catalysts in Diels-Alder cycloadditions has been presented. Brpnsted acid-assisted chiral Lewis acids have been shown to be highly efficient catalysts for the enantioselective Diels-Alder reactions of a- and /3-substituted-Q, /i-enals with numerous dienes. The chiral Lewis acid-catalysed Diels-Alder reaction between cyclopentadiene and alkenoyloxazolidi-nones can be catalysed by bis(oxazolone)magnesium catalysts. ... 

Cycloadditions have been carried out to 37/-indoles (222, 223) (125,126), N-arylmaleimides (224) (127,128), l,2), -azaphospholes (225) (129), 5(47/)-oxazo-lones (226) (130), and 4,5-dihydrooxazoles (230) (131). The primary cycloadducts from the reaction of oxazolones (e.g., 226 with diaryl nitrile imines), derived from tetrazoles in refluxing anisole, do not survive. They appear to lose carbon dioxide and undergo a dimerization-fragmentation sequence to give the triazole 228 and the diarylethene 229 as the isolated products (130). In cases where the two aryl substituents on the oxazole are not the same, then, due to tautomerism, isomeric mixtures of products are obtained. 

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