Thiazole cycloaddition

In contrast to oxazole, thiazole does not undergo the Diels-Alder cycloaddition reaction (331). This behavior can be correlated with the more dienic character of oxazole, relative to thiazole, as shown by quantochemical calculations (184). 

Thieno[2,3 -h]selenophenes lithiation, 4, 950 Thienospirans synthesis, 4, 760 Thieno[3,4-c][l,2,5]thiadiazoles cycloaddition reactions, 6, 534 reactions, 6, 1036 synthesis, 6, 1042, 1044 Thieno[2,3-d]thiazole, 2-acylamino-synthesis, 6, 1010 Thieno[2,3-d]thiazoles synthesis, 5, 116 6, 988, 994 Thieno[3,2-d]thiazoles synthesis, 5, 135 6, 1015 Thieno[3,4-d]thiazolidine-2-thione, perhydro-... 

An example of 1,3-dipolar cycloaddition involving a thiazole dioxide derivative was described (99T(55)201). A-Benzoyl-(R)-thiazolidin-4-carboxylic acid 5,5-dioxide 120 was cyclized to the bicylic mesoionic thiazolo-oxazolium 5,5-dioxide with Ac O and reacted with the imine 121 in DMF... 

Other interesting three-component cycloadditions are the following Sulfur dioxide and diazo compounds lead to episulfones (equation 75)436—in a special case to 4,5-dihydrothiepine S,S-dioxides437 sulfur dioxide, ketene, and arylimine lead to thiazole derivatives438 (equation 76) sulfur dioxide, quinone, and alkenes lead to benzoxathiane derivatives439 (equation 77). 

The reaction of troponephenylhydrazone with carbon disulphide afforded the bicyclic thiazole (37) in quantitative yield. iV-methoxytroponimine when treated with phenylisothiocyanate afforded a mixture of cycloheptatriene derivatives (38a) and (38b). Both of these reactions proceed via an [8+2] cycloaddition <95H1675>. 

The cycloaddition of alkynes with the tributylphosphine-carbondisulfide adduct 131 results in the in situ formation of the ylides 132 which react with aldehydes to give the novel 2-arylidene or 2-alkylidene-l,3-dithioles 133 (Scheme 36) [132]. Concerning ylides C-substituted by sulfur we can also mention a publication on the behavior of various keto-stabilized ylides towards acyclic and cyclic a s-disulfides allowing the synthesis of substituted thiazoles, thiols, and dithiols [133]. 

After the cycloaddition, the thiazole ring was introduced via a Wadsworth-Emmons reaction at Step D, forming the C(17)-C(18) bond. 

There is an enormous literature on thiocarbonyl compounds, due in part to the technical and industrial importance of many of them, including thioamides, thioureas, xanthates, dithiocarbamates and so forth. An excellent, and recent, general review is available.107 There are also specialized reviews germane to the present chapter Griffin, Woods, and Klayman2 discussed the use of thioureas in the synthesis of heterocycles the preparation of thiazoles from thioamides is included in a three-part volume on Thiazoles 108 the use of carbon disulfide in the synthesis of trithiones and related heterocycles has been reviewed by Mayer109 and Huisgen110 has reported numerous examples of 1,3-dipolar cycloadditions in which carbon disulfide was used. 

Analogously, the mesoionic jV-methyl thiazol-5-ones and l,3-dithiol-4-ones afforded A-methyl-4-pyridones and thiapyran-4-ones when reacting with diphenyl cyclopropenone and its thione261. Benzonitrile oxide apparently gives a 1,3-dipolar cycloaddition to the C=0 group of diphenyl cyclopropenone rationalizing the formation of triphenyl-l,3-oxazin-6-one 41626i ... 

Imino-1,2,4-thiadiazoles such as 27 react with electron-deficient alkynes to afford arylimino thiazoles such as 28. There has been some speculation as to the mechanism of this reaction, which may involve a 1,3-dipolar cycloaddition or a stepwise nucleophilic addition (Equation 6) <1996CHEC-II(4)307>. 

Dimethyl-3,5-dimethyl-l//,3//-pyrrolo[l,2-r ][l,3]thiazole-6,7-dicarboxylate 399 (R = H) was prepared from cysteine 396 using the method developed of Padwa et al. <1989JOC644>. The thiazolidine carboxylic acid 397 (R = H), obtained by reaction of the cysteine with formaldehyde, was heated in the presence of acetic anhydride and DMAD to give the sulfide 399 by dipolar cycloaddition of the acetylene to the intermediate dipole 398 (Scheme 59) <2002J(P1)1795>. 

Meso-ionic l,3-diazole-4-thiones (103, R = Ph) have been prepared by 1,3-dipolar cycloaddition of phenylisothiocyanate to meso-ionic 1,3-oxazol-5-ones (66) and l,3-thiazol-5-ones (105). Another route to l,3-diazole-4-thiones is exemplified by the formation of the derivative (103, R = R = Me, R = R = Ph) from the methiodide (104) and methylamine. ... 

A full account of the preparation and 1,3-dipolar cycloadditions of the meso-ionic l,3-thiazol-4-ones (114) has now been published. A detailed chemical and spectroscopic study of the stereochemistry of the 1 1 adducts of the l,3-thiazol-4-ones (114) with olefinic 1,3-dipolarophiles has been reported. ... 

Reactions of thiocarbonyl ylides with nitriles are scarce. Simple nitriles do not undergo bimolecular cycloaddition (171). There is, however, a single example of an intramolecular case that was reported by Potts and Dery (24c,62). By analogy to the intramolecular cycloaddition with acetylenic dipolarophiles (Scheme 5.40), the primary product derived from the reaction of a thiocarbonyl ylide with a nitrile group undergoes a subsequent elimination of phenylisocyanate to give the fused 1,3-thiazole (131). 

Pinho e Melo et al. (89) employed an intramolecular miinchnone cycloaddition to constmct several l/7-pyrrolo[l,2-c]thiazole derivatives from N-acylthiazolidines and acetic anhydride. Martinelli and co-workers (90,91) employed an intramolecular miinchnone cycloaddition to craft a series of 4-keto, 5,6,7-tetrahydroindoles (168-171) in two steps. The requisite acetylenic precursors were prepared from glutaric anhydride (or 3-methylglutaric anhydride). The overall sequence is illustrated for the synthesis of 168. An electrophilic acetylenic unit appears to be necessary for successful intramolecular 1,3-dipolar cycloaddition. 

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