Iodination thiazole

The electron donor-acceptor molecular complexes between iodine and thiazole, benzothiazole, and some derivatives have been studied in several organic solvents by UV spectroscopy <87CJC468>. In all cases, the presence of the thiazole ring produces a displacement of the Amax iodine band at 512 nm towards shorter wavelengths and a decrease of its absorbance. Moreover, a sharp isosbestic point near 470 nm was observed for all iodine-thiazole complexes. 2-Aryl and 2-hetarylbenzothiazoles showed fluorescence, the maxima of emission being between 350 nm and 395 nm. Both substituent and solvent effects on the spectra were observed <93MI 306-02>. The photophysical properties of bis(benzothiazolylidene)squaraine dyes have also been studied <93JPC13625>. 

Because of their use in the rubber industry various sulfenamido thiazoles (131) have been prepared. They are obtained in good yields through the oxidation of A-4-thiazoline-2-thiones (130) in aqueous alkaline solution in the presence of an amine or ammonia (Scheme 66) <123, 166, 255, 286, 308, 309). Other oxidizing agents have been proposed (54, 148. 310-313) such as iodine (152), chlorine, or hydrogen peroxide. Disulfides can also be used as starting materials (3141. 

As in the case of the thiazoles, a variation on the Hantzsch s method has been used. This consists of using a nonhalogenated carbonyl derivative directly in the presence of iodine in the reaction with selenourea (Scheme 7) (20). However, in this case the reaction with selenourea is slower than with thiourea, and normally an excess of carbonyl compound is used. 

On the other hand, 2-arylthiazoles are easily isomerized to 3-aryliso-thiazoles in 407o yield upon irradiation with a high-pressure mercury lamp, in benzene solution in the presence of iodine (738). A valence bond isomerization was proposed among several alternatives to account for these results. 

Most of the thiazoles studied absorb in the ultraviolet above 254 nm, and the best detection for these compounds is an ultraviolet lamp (with plates containing a fluorescent indicator). Other indicator systems also exist, among which 5% phosphomolybdic acid in ethanol, diazotized sulfanilic acid or Pauly s reagent (Dragendorff s reagent for arylthiazoles), sulfuric anisaldehyde, and vanillin sulfuric acid followed by Dragendorff s reagent develop alkylthiazoles. Iodine vapor is also a useful wide-spectrum indicator. 

Thiophenealdehyde has been used in the reductive alkylation of 2-aminopyridine and 2-aminopyrimidine. 2-Arylamino-4- (2-thienyl )thiazoles have been prepared by the reaction of 2-acetylthio-phene with A-arylthioureas in the presence of iodine, ... 

A variation of the general method for the synthesis of 2-amino-selenazoles is to avoid the use of the free a-halogenocarbonyl compound and in its place react the corresponding ketone and iodine with selenourea.This procedure is also taken from thiazole chemistry. By contrast with thiourea, the reaction with selenourea needs a longer reaction time and the work up of the reaction mixture is somewhat more difficult. Usually an excess of the ketone is used. In the preparation of 2-amino-4-( n-nitrophenyl)selenazole, a very high yield, calculated on the amount of iodine used, was obtained. To explain this peculiar result, the oxidative action of the nitro group was invoked. This liberates free iodine from some of the hydrogen iodide eliminated in the condensation reaction, and the free iodine then re-enters into the reaction. 

This reaction is catalyzed by the presence of divalent sulfur — e.g. sulfur ions, substances with S-S links, thioethers, thiazoles. If such substances are present in a chromatogram zone then the iodine applied with the reagent is consumed by reaction with sodium azide according to the above reaction. It is no longer available for the for-... 

One Au-C bond in bis(thiazol-2-ylidene)gold cations is cleaved in the reaction with elemental iodine to give the corresponding (carbene)AuI complex and a 2-iodo-thiazolium salt, while chlorine and bromine oxidize the gold center to the gold(m) state.267... 

Davies et al. describe the preparation of both oxazole- and thiazole-containing derivatives of combretastatin. By formation of the ketoamide intermediate 60, in a 54% yield (Scheme 14), both classes of compounds may be obtained by altering the last step of the reaction [58]. To produce the oxazole 61 a cyclo-dehydration reaction was performed using triphenylphosphine-iodine-triethylamine, and the thiazole compound 62 was formed by thiona-tion using Lawesson s reagent, with an excellent yield (94%). 

A related reaction is the bromine-induced oxidative cyclization of l-acyI-3-(3-thienyl)-thioureas to 2-acylaminothieno[3,2-d]thiazoles the reaction probably proceeds through the formation of the sulfenyl bromide (Scheme 23) (78JHC81). The corresponding 2-thienyl derivatives, however, gave only bromo substituted products (Scheme 23). A similar cyclization is brought about on treatment of /3-(3-benzo[6]thienyl)-a-mercaptoacrylic acids (129) with iodine in THF, when the tricyclic compounds (130) are formed (70AHC(ll)l77>. 

Reactions of alkynyliodonium salts with multidentate nucleophiles can be employed for the synthesis of heterocyclic compounds. Recent examples include preparations of thiazoles, selenazoles, and 2-mercaptothiazoles by the treatment of alkynyliodonium mesylates or tosylates with thioamides, selenoamides, and ammonium dithiocarbamate (Scheme 62) [169-171]. A novel hetero-Claisen rearrangement of tricovalent iodine(III) intermediates was proposed to account for the 2,4-disubstitution pattern of the thiazoles [169]. 

Alkynyl( aryl) iodine (I II) compounds 89 can also be employed in hetero-Claisen rearrangements [151] after reaction with appropriate thioamides yielding thiazoles of type 90 in reasonable yields as shown in Scheme 38 [152]. Ring enlargement reactions of furan derivatives into pyranones by hypervalent iodine compounds were reported as well [153]. 

Of all the methods described for the synthesis of thiazole compounds, the most efficient involves the condensation of equimolar quantities of thiourea and a-halo ketones or aldehydes to yield the corresponding 2-aminothiazoles (Scheme 167) (l888LA(249)3l). The reaction occurs more readily than that of thioamides and can be carried out in aqueous or alcoholic solution, even in a distinctly acid medium, an advantage not shared by thioamides which are often unstable in acids. The yields are usually excellent. A derived method condenses the thiourea (2 mol) with the non-halogenated methylene ketone (1 mol) in the presence of iodine (1 mol) or another oxidizing agent (chlorine, bromine, sulfuryl chloride, chlorosulfonic acid or sulfur monochloride) (Scheme 168) (45JA2242). 

Another approach to the solid phase synthesis of thiazoles involves an interesting C-sulfanylation step. The starting material for this synthesis is a resin bound piperazine 55 which is converted into a thiourea and then treated with an a-bromoketone to give the thiazole 56. Treatment of 56 with either thiols or disulfides and iodine or sulfonyl chlorides with iodine and triphenylphosphine afforded 5-sulfanylthiazoles 57, which could be obtained in high yields and purity after cleavage from the resin <02EJOC2953>. 

Iodine and thiourea can be used to form an aminothiazole fused to a cyclopentane ring <2002BML1563>. In this way, 6-aryl-8//-indeno[ 1,2-r/]thiazol-2-ylamine hydroiodide 253 was prepared by treatment of ketone 254 with iodine and thiourea in either DMF or ethanol with heating (Scheme 102) <2005JME5131>. 

Methyl 3- /7/-D-daunosaminide 154 has been derived from d-149 via a Wittig-type olefination using (2-thiazolylmethylene)triphenylphosphorane (Scheme 13.53). A 1 1 mixture of (E)- and (Z)-alkenes is obtained, which is isomerized in the presence of iodine into a 9 1 mixture of ( )-152 and (Z)-152. Methylation of the thiazole moiety increases the electrophilicity of the alkene, which then accepts nucleophiles such as benzylamine. The adduct is treated with NaBH4 to give a thiazolidine. Acetylation and mercury-mediated hydrolysis of the thiazolidine ring generates 153, which, on acidic treatment in methanol, yields the A-benzyl 3- /7/-D-daunosaminide 154 [99]. 

Hypervalent iodine reagents has been used in modified Hantzsch thiazole synthesis. Treatment... 

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