5-Thiophenyl acetates

Thiophenyl acetates (366 R = Me) and propionates (366 R = Et) react with electrogenerated polysulflde ions S3 in DMF to yield thiocarboxylate ions, thiolate ions, and phenyl tetrasulfanide (367), the last deriving from the reaction of thiolate ions with sulfur (Scheme 48). Smdies of the aminolysis by a set of substimted anilines of Y-aryl dithio-2-thiophenates (368 X = S) and dithio-2-furoates (368 X = O) in acetonitrile have shown that the rate-determining step in these reactions is the departure of the thiophenolate ion from the zwitterionic tetrahedral intermediate T= = (Scheme 49). Experiments with deuteriated anilines yielded k i/IcQ values of 1.7-1.9,... 

The kinetics and mechanism of the aminolysis of a series of 3- and 4-substituted phenyl acetates by imidazole in aqueous solution at 20 °C have been compared with corresponding data for thiophenyl acetates.17... 

The synthesis of the C1-C7 fragment, which corresponds to the lactone, starts with the homoallylic alcohol 2 which was prepared from 1. The existing stereocenter and the conjugate addition method of Evans [21] allow the control of the C5 stereocenter. The homoallylic alcohol 2 was oxidatively cleaved and homologated to the trans enoate 3 by a Wittig olefination. Treatment of 3 with benzaldehyde and a catalytic amount of KHMDS provided acetal 4. The internal Michael addition of the hemiacetal intermediate proceeds with complete stereoselectivity [22]. After deprotection and oxidation, the corresponding aldehyde was treated with Amberlyst-15 and then with camphor sulfonic acid (CSA), to yield pyrane 5 as a mixture of (3- and a-anomers (1.8/1). This compound was converted to the thiophenyl acetal 6 (4 steps) as this compound can be hydrolyzed later under mild conditions (Hg +) with subsequent oxidation of the lactol to the desired lactone. Compound 6 represents the C1-C7 fragment of discodermolide (Scheme 1). 

The final elaboration to discodermolide proceeded by transformation of the thiophenyl acetal at C-l to the corresponding lactone, DDQ deprotection of the PMB ether, carbamoylation of the C-19 alcohol and reduction of the C-l7 ketone. It was observed that reduction occurred with excellent selectivity for the correct R configuration thanks to the neighbouring carbamate group which provides significant chelation control. 

Very recently, the concise synthesis of a range of disubstituted 2-pyrones 96 from (thiophenyl)acetic acids and readily available trifluoromethyl enones via an isothio-nrea mediated one-pot Michael addition/lactonization/thiol elimination sequence has been demonstrated. Derivatization of these reactive pyrones to generate additional high-value products was next investigated and compounds 96a-c were prepared in good yields [39b] (Scheme 31). 

Acetanilides, benzoyl-colour couplers in colour photography, 1, 372 Acetanilides, pivaloyl-colour couplers in colour photography, 1, 372 Acetazolamide — see l,3,4-Thiadiazole-2-sulfonamide, 5-acetamido-Acetic acid, acetamidocyano-ethyl ester, 1, 307 Acetic acid, 2-acylphenyl-isochroman-3-one synthesis from, 3, 858 Acetic acid, 3-benzo[6]thiophenyl-biological activity, 4, 912 Acetic acid, l,2-benzoxazol-3-yl-electrophilic substitution, 6, 48... 

With a-hydroxy ketones and their related tosyloxy derivatives. The imidazo [2,T ]thiazole 364 was prepared by acetic acid-catalyzed cyclocondensation of 2-hydroxy-l,2-diphenyl-ethanone with thiophenyl-substituted 2-aminothiazole 363 (Equation 163) <2002MI110>. Under MW irradiation and in the presence of montmorillonite K-10 clay, a mixture of a-tosyloxyketones 365 and 2-imidazolidinethione led to the substituted 5,6-dihydro-imidazo[2,l- ]thiazoles 366 (Equation 164) <1998J(P1)4093>. When using a-tosyloxyacetophenone, prepared by reaction of acetophenone with [hydroxyl(tosyloxy)iodo]benzene (HTIB), 5-aminopyrazole 367 could be converted to imidazo[l,2- ]pyrazole 368 in basic medium (Equation 165) <2005JHC209>. 

Alkaline hydrolysis rates of a series of thiophenyl 4-X-benzoates (47 X = H, Me, N02) was significantly enhanced in the presence of cyclodextrins (CDs), and this was attributed to strong binding of the benzoyl moiety within the CD cavity and covalent catalysis by secondary hydroxy groups of the CDs (48).63 The effect of MeCN and MeOH on the alkaline hydrolysis of acetylsalicylic acid in aqueous micellar solutions was reported.64 Butylaminolysis of p-nitrophenyl acetate in chlorobenzene in the presence of different kinds of phase-transfer catalysts (crown ethers and gly-mes) supported the existence of a novel reaction pathway exhibiting a first-order dependence on the concentration of the phase-transfer catalyst and a second-order... 

The reaction of 2,4,6-triphenyl-X -phosphorin (20) with 2-thiophenyl-, 2-benzofuryl-2, 2-benzo-1,3-thiazolyl-, and ferroceny1-lithium affords the corresponding 1-substituted 1,2-dihydro-X phosphorin (21), which on treatment with mercury (II) acetate in methanol gives the related X --phosphorin, for example, 1-methoxy-1-(2-thiophenyl)-2,4,6--triphenyl-X -phosphorin (22) (Markl, C. Martin, and W. Weber, Tetrahedron Letters, 1981, 1207). 

The 1,2-benzisothiazolo[2,3-6] 1,2-benzisothiazolium triiodide 208 was prepared by treatment of 3-(2-thiophenyl)-l,2-benzisothiazole 207 (R = H) with iodine a dark solid was obtained, which was recrystallized from nitromethane as a fine red prism (88CJC1405, Scheme 73). The attempt to convert triiodide 208 into the perchlorate in acetic acid failed. The reaction of 3-(2-thiocyanatophenyl)-l,2-benzisothiazole 207 (R = CN) with perchloric acid did not yield an isolable salt (90JCS(P1)2881). 

Spiroketals have been obtained by RCM of cyclic ketals 18 without loss of stereochemical integrity at the spiro linkage <04TL5505> and a stereoselective solid-phase synthesis of 6,6-spiroketals has been reported in which aldol reactions of boron enolates are the key feature <04AG(E)3195>. Spiro orthoesters are accessible from thiophenyl ketene acetals and diols (Scheme 5) <04SL2013>. 

Exploration of the template controlled free-radical oligomerization of other activated olefins began with standard monomers utilized in bulk polymer synthesis and the template 63. Vinyl acetate and acrylonitrile led only to uncontrolled polymerization, while vinylene carbonate did not react under the standard experimental conditions. More exotic monomers, such as vinyl trifluoroacetate and rert-butyl acrylate, were also unsuccessful. Only methyl acrylate polymerization was arrested by template 64 to provide the macrocyclized product 96 in modest yield as a mixture of five diastereomers (Scheme 8-25). Subsequent studies with the more effective thiophenyl-bearing template 63 at lower temperatures improved this yield to 35%. The diastereomer distribution was reminiscent of the methyl methacrylate-derived product, although no stereochemical assignments were made in this case either. 

In 1951, Feodor Lynen (1911-1979) and his coworker E. Reichert demon-started that S-acetyl coenzyme A is a more generally implicated form of active acetate than acetyl phosphate that was recognized in this role by Fritz Lipmann in 1940. The thiol ester character of 5-acetyl Co A called the attention of Th. Wieland to energy-rich S-acyl compounds as promising intermediates for the formation of the peptide bond. In 1951, the same year when the isolation of 5-acetyl CoA was published [3], Wieland and his coworkers described [4] the preparation of thiophenyl esters of benzyloxycarbonyl-amino acids and benzyloxycarbonyl-peptides and their application in the synthesis of blocked peptides ... 

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