Oxazoles preparation

Oxazoles, prepared from carboxylic acids (benzoin, DCC NH4OAC, AcOH, BOSS % yield), have been used as carboxylic acid protective groups in a variety of synthetic applications. They are readily cleaved by singlet oxygen followed by hydrolysis (ROH, TsOH, benzene or K2CO3, MeOH ). 

Fig. 14. Oxazoles prepared using flow reaction conditions...

Other examples of more stmcturally complex oxazoles prepared using this methodology are shown in Scheme 1.71. It is noteworthy that cyclization of the... 

Cyclization of 275 to a 5-[(phenylsulfonyl)methyl]oxazole 276 could be accomplished in good to excellent yield by treatment with base. Examples of oxazoles prepared using this methodology are shown in Table 1.21. 

Brunner and co-workers and Bami and co-workers described examples of fused or heterocyclic oxazoles prepared using PPA (Scheme 1.127). Heating picolinic acid and 3-amino-2-naphthol in PPA afforded 2-(2-pyridyl)naphtho[2,3-d] oxazole 466 directly. Similarly, 2-(nitrophenyl)oxazolo[5,4-fe]pyridines 468, precursors to heterocyclic azo dyes, were prepared from 467. These authors... 

Nucleophilic addition of 1005 to an 7V-acyliminium ion, e.g., a Reissert salt, and oxidation of the resulting adduct affords a 2-(heteroaryl)oxazole 1019. Acylation of a nitrogen heterocycle 1016 with ethyl chloroformate generated the intermediate Reissert salts 1017 in situ (Scheme 1.272). Addition of 1005 to 1017 gave adducts 1018, which produced 1019 after oxidative deacylation with o-chloranil. Examples of 2-(heteroaryl)oxazoles prepared from thiazole, benzothia-zole, pyridine, quinoline, and isoquinoUne are shown in Table 1.77. Donodni and co-workers summarized their early work on preparation and reaction of 2-(trimethylstannyl)oxazoles and 2-(trimethylsilyl)oxazoles. 

Scheme 8.71 2,5-Disubstituted oxazole preparation from enamides.

This chapter is an attempt to present the important results of studies of the synthesis, reactivity, and physicochemical properties of this series of compounds. The subject was surveyed by Bulka (3) in 1963 and by Klayman and Gunther (4) in 1973. Unlike the oxazoles and thiazoles. there are few convenient preparative routes to the selenazoles. Furthermore, the selenium intermediates are difficult to synthesize and are often extremely toxic selenoamides tend to decompose rapidly depositing metallic selenium. This inconvenience can be alleviated by choice of suitable reaction conditions. Finally, the use of selenium compounds in preparative reactions is often complicated by the fragility of the cycle and the deposition of metallic selenium. 

Selenium heterocycles receive far less mention in the literature than do such homologs as oxazole, thiazole, or imidazole. In fact, preparative methods of selenium heterocycles are much more limited than for the other series, mainly because of manipulatory difficulties arising from the toxicity of selenium (hydrogen selenide is even more toxic) that can produce severe damage to the skin, lungs, kidneys, and eyes. Another source of difficulty is the reactivity of the heterocycle itself, which can easily undergo fission, depending on the reaction medium and the nature of the substituents. 

Pyrazoles and imidazoles carrying a substituent on nitrogen, as well as oxazoles, thiazoles, etc., are converted by alkyl halides into quaternary salts. This is Illustrated by the preparation of thiamine (89) from components (87) and (88). 

Similar alkylations may be effected on oxygen. l-(2-Chloroethyl)imidazolidin-2-one (312) when treated with potassium hydroxide or sodium hydride underwent ring closure to the tetrahydroimidazo[2,l-6]oxazole (313) (57JA5276). This approach can be used for the preparation of bicyclic hydantoins and the corresponding dihydro derivatives of (313) using the mesylate of (312) and NaH (77JHC5U, 79JMC1030). 

Acyloins are useful starting materials for the preparation of a wide variety of heterocycles (e.g., oxazoles and imidazoles ) and carbocyclic compounds (e.g., phenols ). Acyloins lead to 1,2-diols by reduction, and to 1,2-diketones by mild oxidation. 

The aldehyde functionality present in 3-phenyl-2H-azirine-2-carbox-aldehyde reacts selectively with amines and with Qrignard and Wittig reagents to give a variety of substituted azirines. These azirines have been used, in turn, to prepare a wide assortment of heterocyclic rings such as oxazoles, imidazoles, pyrazoles, pyrroles, and benzazepins. ... 

In 1949, Comforth showed that preparation of 2,5-disubstituted oxazoles was not limited to diaryloxazoles through condensation of aldehydes (benzaldehyde, n-hept-aldehyde) with a-hydroxy-amides (lactamide). The intermediate oxazolidone 13 were converted into oxazoles 14 on warming with phosphoryl chloride. ... 

In 1909, Robinson demonstrated the utility of acylamidoketones as intermediates to aryl-and benzyl-substituted 1,3-oxazoles through cyclization with sulfuric acid. Extension of sulfuric acid cyclization conditions to alkyl-substituted oxazoles can give low yields, for example 10-15% for 2,5-dimethyl-l,3-oxazole. Wiegand and Rathbum found that polyphosphoric acid can provide alkyl-substituted oxazoles 4 in yields equal to or greater than those obtained with sulfuric acid. Significantly better yields are seen in the preparation of aryl- and heteroaryl-substituted oxazoles. For example, reaction of ketoamides 5 with 98% phosphoric acid in acetic anhydride gives oxazoles 6 in 90-95% yield. ... 

Wipf and Miller have reported side-chain oxidation of 3-hydroxy amides with the Dess-Martin periodinane, followed by immediate cyclodehydration with triphenylphosphine-iodine, which provides a versatile extension of the Robinson-Gabriel method to substituted oxazoles. Application of this method was used to prepare the oxazole fragment 10 in 55% overall yield from 3-hydroxy amide 8. 

Pulici and coworkers have reported a solid-phase variation of the Robinson-Gabriel for the production of parallel libraries of ox azole-containing molecules." The preparation is based on a solid supported 2-acylamino ketone 16 that can be cleaved by means of a volatile anhydride and cyclized in solution to obtain a substituted oxazole ring (17) that does not contain traces of the linker moiety. 

Workers at Lilly prepared the oxazole-containing, dual PPAR ot/y agonist 23, through Robinson-Gabriel cyclodehydration of ketone 22 with acetic anhydride and sulfuric acid in refluxing ethyl acetate. ... 

The van Leusen reaction forms 5-substituted oxazoles through the reaction of p-tolylsulfonylmethyl isocyanide (1, TosMIC) with aldehydes in protic solvents at refluxing temperatures. Thus 5-phenyloxazole (2) is prepared in 91% yield by reacting equimolar quantities of TosMIC and benzaldehyde with potassium carbonate in refluxing methanol for 2 hrs. ... 

Van Leusen and Possel described the use of mono-substituted tosylmethyl isocyanides (TosCHRN=C R = alkyl, benzyl, allyl) in the synthesis of 4,5-substituted oxazoles. For example, 4-ethyl-5-phenyloxazole (8) was prepared in 82% yield by refluxing a-tosylpropyl isocyanide (7) and benzaldehyde for 1 hr with 1.5 equivalent of K2CO3 in MeOH. 

The development of the key intermediate, 5-(2-methoxy-4-nitrophenyl)oxazole (25), in the preparation of the hepatitis C drug candidate, VX-497, utilizes a van Leusen reaction of aldehyde 24 with TosMIC. ... 

Workers at Lilly prepared the oxazole-containing partial ergot alkaloid, 27, a 5-HTl A agonist, through van Leusen reaction of aldehyde 26. ... 

An example of this methodology was its use in the synthesis of vitamin Be, pyridoxine 12. Cycloaddition of oxazole 9, prepared from ethyl A-acetylalanate and P2O5, with maleic anhydride initially gave 10. Upon exposure to acidic ethanol, the oxabicyclooctane system fragments to afford pyridine 11. Reduction of the ester substituents with LiAlIU generated the desired product 12. 

A constant interest in the development of new rapid methodologies for the preparation of oxazole hbraries is motivated by their presence in numerous biologically active natural products. Janda and coworkers were hrst to show that oxazoles can be obtained by microwave-assisted treatment of polymer-bound a-acylamino-/f-ketoesters with Burgess reagent [68]. Hydroxybutyl-functionalized /anda/el resin was used for this investigation, with key steps being monitored by on-bead FT-IR. First, a resin-bound acetoacetate was pre-... 

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