1,3-Thiazines reactions, with

Adducts from various quaternary salts have been isolated, in reactions with aldehydes, a-ketoaldehydes, dialkylacylphosphonates and dialkyl-phosphonates, isocyanates, isothiocyanates, and so forth (Scheme 15) (36). The ylid (11) resulting from removal of a Cj proton from 3.4-dimethyl-S-p-hydroxyethylthiazolium iodide by NEtj in DMF gives with phenylisothiocyanate the stable dipolar adduct (12) that has been identified by its NMR spectrum and reactional product, such as acid addition and thiazolidine obtention via NaBH4 reduction (Scheme 16) (35). It must be mentioned that the adduct issued from di-p-tolylcarbodiimide is separated in its halohydrogenated form. An alkaline treatment occasions an easy ring expansion into a 1,4-thiazine derivative (Scheme 17) (35). 

Conjugate addition of azide ion to dihydropyran-2,5-diones affords the 3-amino derivative <96SL341>, whilst reaction with bisnucleophiles provides a route to piperazines, thiazines and diazepines <96JHC703>. 

Reaction of the thiazine 264 with DDQ in chloroform does not give the dehydrogenated product 265 in every case instead thienoindolizines, 266, may be the observed products. A possible mechanism is shown below < 1987BCJ3713 1992BCJ1244> (Scheme 72). 

Sulfonyl imides (78) are, like sulfenes, prepared by dehydrohalogenation of the corresponding sulfonyl chlorides (79) (usually called sulfamoyl chlorides). Like sulfenes, they take part in [2 + 2] and [4 + 2] cycloaddition reactions with electron-rich alkenes or with 1,3-dienes, yielding 1,2-thia-zetidine 1,1-dioxides (80)104 or dihydro-1,2-thiazines (81),105 respectively. 

An N-debenzylation reaction with concomitant hydrogenation of a double bond in the thiazine ring was observed with 1,2-thiazine nitrogen 107 (see Equation 12) <1994TL2911>. 

The 6//-l,3-thiazin-6-iminium hydroperchlorate salts 78-81 give interesting products when treated with nucleophiles <2003H(60)2273>. Hydrolysis of 6-imino-6//-l,3-thiazine hydroperchlorate 78 affords (2Z,4Z)-2-cyano-5-hydroxy-5-phenyM-azapenta-2,4-dienethioamide 82 in excellent yield, while treatment with morpholine gives 2-(morpholinomethylene)malononitrile 83 and thiobenzamide. The 5-(ethoxycarbonyl) -(methylthio)-2-aryl-6/7-l,3-thiazin-6-iminium salts 79 and 80 react with hydroxide or morpholine to afford ethyl 4-(methylthio)-2-aryl-6-thioxo-l,6-dihydropyrimidine-5-carboxylates 84 and 85. In the case of the 4-chloro analogue 80, the (Z)-ethyl 2-(5-(4-chlorophenyl)-37/-l,2,4-dithiazol-3-ylidene)-2-cyanoacetate 87 is also formed for the reaction with sodium hydroxide. The 1,2,4-dithiazoles 86 and 87 can be obtained as the sole product when 79 and 80 are treated with sodium acetate in DMSO. Benzoxazine 88 is isolated when the iminium salt 81 is treated with morpholine or triethylamine. Nitrile 89 is formed as a ( /Z)-mixture when 6-imino-67/-l,3-thiazine hydroperchlorate 79 is reacted with triethylamine and iodomethane in methanol <2003H(60)2273>. 

The 2-substituted l,3-thiazin-6-thiones 33 and 34 and 160 and 161 are accessible by reacting 3,3-dichloroprop-2-ene iminium salts (vinylogous Viehe salts) with thiobenzamide or WA -disubstituted thioureas (Scheme 11) <1997S573>. The ring closure occurs with loss of amine as the hydrochloride salt and the thiones are generated after a reaction with another thioamide molecule. 

It is well known that l,3-thiazine-4,6-diones can exist in three tautomeric forms <1960CB671, 1976KGS1042>. Cycloaddition of chlorocarbonyl ketenes with thioamides has been reported to produce only the 4-hydroxy-l,3-thiazin-6-ones, whereas the same reaction with amides gives either 4-hydroxy-1,3-oxazin-6-ones or a mixture of tautomers depending on the substituents on the starting materials <2005ARK(xv)88>. 

A series of 4-heteroaryl-5,6-di(2,5-dimethyl-3-thienyl)-2-phenyM//-l,6-thiazines 54 with photochromic properties was prepared by reacting 3-(2-(2,5-dimethylthiophen-3-yl)ethynyl)-2,5-di ethylthiophene with thiobenzamide and aldehydes <2005CHE86, 2005PS1503>. The acid-catalyzed cyclocondensation of cyclopentanone, aromatic aldehydes, ArCHO, and thiourea affords the cyclopenta[t ]l,3-thiazines 37 <2006PS1655>. Two equivalents of the aldehyde are required. The same products are isolated when 2,5-dibenzylidenecyclopentanones are treated with thiourea under the same conditions. 2-Amino-4i/-l,3-thiazines 184 are easily synthesized in one pot by the reaction of aromatic alkynes, R feCH, aromatic aldehydes, R CHO, and thiourea in the presence of TFA/acetic acid <2005OL3797>. 

The diastereoselective cycloaddition of 2-phenyl-4-dimethylamino-l-thia-3-azabuta-l,3-diene with a choice of dienophiles and in the presence of a Lewis acid provides a convenient route to 5,6-dihydro-4//-l,3-thiazines <2002TL6067, 2004T1827>. The more stable /ra r-adducts are produced exclusively. The approach using (4A)-3-acryloyl-4-benzyloxazolidin-2-one 198 provides access to the chiral 5,6-dihydro-4//-l,3-thiazine 199 <2004T1827>. The exceptional level of selectivity is only achieved when magnesium bromide is used. The chiral auxiliary was removed by reaction with lithium benzoxide to give the benzyl ester 200, and reaction with catalytic amount of samarium triflate and methanol provides the methyl ester 201 (Scheme 21). 2-Substituted-5,6-dihydro-l,3-thiazines are conveniently synthesized from nitriles or thiocyanates and 4-mercapto-2-methylbutan-2-ol to produce... 

Dihydro-4//-l,3-thiazines 231 are conveniently prepared by the iodocyclization of A -homoallyl thioamides 230 in the presence of triethylamine (Scheme 28) <2004CL508>. The selectivity of the reaction was dependent on the groups attached to the thioamide, and high diastereoselectivities are achieved with the 1-naphthyl or the 2-methoxyphenyl groups giving the major product 233 with the aryl group in the equatorial position rather than 234. Treatment of thiazines 231 with pyrrolidine resulted in the formation of 6-alkylidene-5,6-dihydro-4//-l,3-thiazines 232. 

In some reactions with thiocarbonyl ylides, 1,3-thiazine derivatives are formed by a series of consecutive reactions. For example, the interception of 3-thioxocy-clobutanone (5)-methylide (69) with thiobenzamide results in the formation of the bicyclic 1,3-thiazine (176) (100a) (Scheme 5.50). A conceivable intermediate is the 1,3-adduct 175 as shown in Scheme 5.50. 

Oxazin-4-ones and -thiazin-4-ones are well represented in the chemical literature. Thiazin-4-ones can be synthesized from 1,3-oxazinium salts by the action of hydrogen sulfide and potassium carbonate (81H(15)85l) and oxazin-4-ones are obtained by cycloadditions between isocyanates and ketenes (Scheme 73), or alkynes (Scheme 74), or between nitriles and acylketenes (Scheme 75). Similarly diketene is often used and affords oxazin-4-ones by its reactions with imidates and cyanamides (Scheme 76) (80H(14)1333>. 

Diones are normally synthesized from /3-hydroxy acids in two steps first, conversion into carbamates by reaction with sodium cyanate, and then cyclization with thionyl chloride (Scheme 103) (54JCS839). Alternative preparations utilize oxetanes, which may be combined either with isocyanates in the presence of boron trifluoride (68JAP6808278) or with S-alkylthioureas (Scheme 104) (69ZOR1844). In the last example the initial products are imines (224) which may readily be hydrolyzed to the required diones. Similar methods can be applied to the synthesis of tetrahydro-l,3-thiazine-2,4-diones, and, for instance, the 4-oxo-2-thioxo derivative (225) is obtained from /3-propiolactone and dithiocarbamic acid (Scheme 105) (48JA1001). 

TL4649). The [2 + 2] cyclocondensation of thiazines (241) with ketenes has been studied. The reversibility of the reaction is a function of the nature of the substituents on positions 4 and/or 5 (Scheme 98) (86CJC597). As we have noted at the beginning of this review, this aspect of thiazine chemistry will not be discussed further here. 

The amine 196 upon reaction with hydrogen sulfide in dimethylsulfoxide (DMSO) in the presence of base at 25-50 °C afforded the thiazine 197, allyl(2-mercaptopropyl)amine 198, and 3,7-dimethylperhydro[l,2,5]dithiazepine 199 in 10-17%, 2-31%, and 1-50% yields, respectively (Scheme 43) <2000RJC1243>. The formation of 199 is assumed via thiol 198, which reacted with a second hydrogen sulfide molecule to give dithiol 200. Subsequent oxidation of200 resulted in 199. In an alternative mechanistic pathway, the amine 196 can form the intermediate 201, which could cyclize to give 199. 

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