Iodine oxidative coupling

The thiol form (12) is susceptible to oxidation (see Fig. 2). Iodine treatment regenerates thiamine in good yield. Heating an aqueous solution at pH 8 in air gives rise to thiamine disulfide [67-16-3] (21), thiochrome (14), and other products (22). The disulfide is readily reduced to thiamine in vivo and is as biologically active. Other mixed disulfides, of interest as fat-soluble forms, are formed from thiamine, possibly via oxidative coupling to the thiol form (12). 

Derivatives of Methylene Violet 6 possessing long aliphatic chains are obtained by oxidative coupling of 3-acetoxyphenothiazine with a secondary amine in the presence of an oxidant such as iodine. The oxidative coupling of phenothiazine with amine is well known but in this case the reaction does not stop there but proceeds further at reflux temperatures to the phenothiazinone 74.9 Reduction of the latter dye and treatment with acetic anhydride yields the ballasted phenothiazine 6. Reaction of 75 with the dye chloroformate 70 yields the ballasted leuco dye developer 76. 

A Sml2-induced reductive cyclization of (V-(alkylketo)pyrroles provided an entry into medium ring 1,2-annelated pyrroles <06EJO4989>. An oxidative radical alkylation of pyrroles with xanthates promoted by triethylborane provided access to a-(pyrrol-2-yl)carboxylic acid derivatives <06TL2517>. An oxidative coupling of pyrroles promoted by a hypervalent iodine(III) reagent provided bipyrroles directly <060L2007>. 

Triiodothyronine is not classified as a thyroid inhibitor it is an amino acid derivative of thyronine and results from the oxidative coupling of monoiodotyrosyl and diiodotyrosyl residues. Iodine 131, the most often used radioisotope of I, is rapidly absorbed by the thyroid and is deposited in follicular colloid. Prom the site of its deposition, Bll causes fibrosis of the thyroid subsequent to pyknosis and necrosis of the follicular cells. 

FIGURE 6.23 The synthesis of insulin, starting with a cystine-containing peptide. [Kamber et al., 1977]. Moc = methoxycarbonyl, Bpoc = biphenylisopropoxycarbonyl, Trt = trityl, Acm = acetamidomethyl. (a) HOBt-assisted carbodiimide-mediated coupling (b) removal of Trt by HC1 in CF3CH2OH-CH2Cl2 (9 1) at pH 3.5 (c) removal of Bpoc by CF3CH2OH-CH2 Cl2 (9 1) at 60°C (d) removal of Acm and oxidation by iodine. 

Thyroxine is actually a simple derivative of the aromatic amino acid tyrosine (see Section 13.1), but is believed to be derived by degradation of a larger protein molecule containing tyrosine residues. One hypothesis for their formation invokes suitably placed tyrosine residues in the protein thyroglobulin being iodinated to di-iodotyrosine. These residues then react together by phenolic oxidative coupling. 

If one tries to transfer carbanions to halogen compounds by reacting with elementary halogen oxidative coupling often is the main reaction. Better results are observed with carbontetrachloride, carbontetrabromide, or other polyhaloalkenes as reagents l As a good alternative we offer the reaction with diphenylarsanechloride and then with bromine, iodine, or sulfurylchloride as has been demonstrated by the example shown in Scheme 27. 

A small group of cyclic thioureas have been used in the treatment of excessive thyroid function. They include 6-n-propylthiouracil (176 R1 = H, R2 = Prn), 5-iodo-2-thiouracil (176 R1 = I, R2 = H), l-methyl-2-mercaptoimidazole (methimazole) and its ethoxycarbonyl derivative carbimazole (177), which lacks the bitter taste of the unacylated compound. These compounds block the synthesis of thyroxin by inhibiting the oxidation of iodide to iodine and the oxidative coupling of iodotyrosine residues. 

Oxidative dimerization of allylic sulfones.1 This oxidant is the reagent of choice for coupling of allylic sulfones to 1,6-disulfones by [3-3 ]coupling. Iodine effects coupling to 1,2-disulfones. 

The use of hypervalent iodine reagents in carbon-carbon bond forming reactions is summarized with particular emphasis on applications in organic synthesis. The most important recent methods involve the radical decarboxylative alkylation of organic substrates with [bis(acyloxy)iodo]arenes, spirocyclization of para- and ortho-substituted phenols, the intramolecular oxidative coupling of phenol ethers, and the reactions of iodonium salts and ylides. A significant recent research activity is centered in the area of the transition metal-mediated coupling reactions of the alkenyl-, aryl-, and alkynyliodonium salts. 

More involved studies of the oxidation of plant phenols [27], as well as the introduction of thallium and hypervalent iodine complexes and the use of electrochemical methods, have emphasized the importance of another intermediate involved in oxidative coupling reactions, namely the phenoxonium ion 8 [28-30]. Due to its ionic nature, reaction through an oxo-nium ion can improve the regioselectivity of bond formation and lead to fewer unwanted products (for example, no coupling via the oxygen atom). The coupling reaction can then be viewed as an electrophilic aromatic substitution between 17 and a nucleophilic aromatic unit 15 (Scheme 5). 

Scheme 8. Hypervalent iodine-mediated phenyl methyl ether oxidative coupling.

Oxidative Coupling Reactions with Hypervalent Iodine Reagents... 

Oxidative Coupling Reactions with Hypen/aient iodine Reagents I 487... 

Oxidative Coupling Reactions with Hypen/alent Iodine Reagents I 491... 

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