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Sulfenic acid, 132

Organosulfur Halides. When sulfur is directly linked only to an organic radical and to a halogen atom, the radical name is attached to the word sulfur and the name(s) and number of the halide(s) are stated as a separate word. Alternatively, the name can be formed from R—SOH, a sulfenic acid whose radical prefix is sulfenyl-. For example, CH3CH2—S — Br would be named either ethylsulfur monobromide or ethanesulfenyl bromide. When another principal group is present, a composite prefix is formed from the number and substitutive name(s) of the halogen atoms in front of the syllable thio. For example, BrS—COOH is (bromothio)formic acid. [Pg.38]

Sulfur Acids. Organic oxy acids of sulfur, that is, —SO3H, —SO2H, and —SOH, are named sulfonic acid, sulfinic acid, and sulfenic acid, respectively. In subordinate use, the respective prefixes are sulfo-, sulfino, and sulfeno-. The grouping —SO2—O—SO2— or —SO—O—SO is named sulfonic or sulfinic anhydride, respectively. [Pg.38]

Protection of carboxyflc acids and sulfenic acids requires efficient sdyl donors, eg, BSA, MTSA, and bis(ttimeth5isdyl)urea [18297-63-7] (BSU). BSU is often prepared in situ from hexamethyldisda2ane and urea to yield over 90% of the sdylated derivative in synthesis of cephalosporins (5). [Pg.71]

Sulfoxides containing P-hydiogen atoms, eg, di-Abutylsulfoxide [2211 -92-9] react with strongly basic systems, eg, potassium /-butoxide, in DMSO by sulfenic acid elimination to produce olefins (eq.l2) (44) ... [Pg.109]

In other cases, sulfenic acid elimination can involve y-hydrogen atoms with the formation of cyclopropane derivatives. y-Klimination is favored when DMSO is the reaction solvent. An example involving l-methylsulfinyl-2-ethyl-3-phenyl propane [14198-15-3] is shown in equation 13 (45) ... [Pg.109]

The reaction of thiirane 1-oxides with water or methanol is usually acid-catalyzed and gives /3-substituted sulfenic acids which dimerize to thiolsulfinates (54 Scheme 70) (72JA5786). If acetic acid is used a mixture of disulfide (55) and thiolsulfonate (56) is obtained. Treatment of thiirane 1,1-dioxides with hydroxide ion may involve attack on carbon as well as on sulfur as exemplified by 2-phenylthiirane 1,1-dioxide (Scheme 71). [Pg.157]

From 0-lactam-4-sulfenic acids Thioketene + isocyanate... [Pg.267]

Penicillin sulfoxides can be epimerized by heat to afford thermal equilibrium mixtures of a- and /3-sulfoxides, the position of the equilibrium depending on the C(6) side chain (Scheme 5). Deuterium incorporation studies support a sulfenic acid, e.g. (18), as the intermediate in these transformations. This mechanism is also supported by the finding that when an a-sulfoxide epimerizes to a /3-sulfoxide there is a simultaneous epimerization at C(2) (71JCS(C)3540). With irradiation by UV light it is possible to convert a more thermodynamically stable /3-sulfoxide to the a-sulfoxide (69JA1530). [Pg.306]

Scheme 6 depicts a typical penicillin sulfoxide rearrangement (69JA1401). The mechanism probably involves an initial thermal formation of a sulfenic acid which is trapped by the acetic anhydride as the mixed sulfenic-acetic anhydride. Nucleophilic attack by the double bond on the sulfur leads to an episulfonium ion which, depending on the site of acetate attack, can afford either the penam (19) or the cepham (20). Product ratios are dependent on reaction conditions. For example, in another related study acetic anhydride gave predominantly the penam product, while chloroacetic anhydride gave the cepham product (7lJCS(O3540). The rearrangement can also be effected by acid in this case the principal products are the cepham (21) and the cephem (22 Scheme 7). Since these early studies a wide variety of reagents have been found to catalyze the conversion of a penicillin sulfoxide to the cepham/cephem ring system (e.g. 77JOC2887). Scheme 6 depicts a typical penicillin sulfoxide rearrangement (69JA1401). The mechanism probably involves an initial thermal formation of a sulfenic acid which is trapped by the acetic anhydride as the mixed sulfenic-acetic anhydride. Nucleophilic attack by the double bond on the sulfur leads to an episulfonium ion which, depending on the site of acetate attack, can afford either the penam (19) or the cepham (20). Product ratios are dependent on reaction conditions. For example, in another related study acetic anhydride gave predominantly the penam product, while chloroacetic anhydride gave the cepham product (7lJCS(O3540). The rearrangement can also be effected by acid in this case the principal products are the cepham (21) and the cephem (22 Scheme 7). Since these early studies a wide variety of reagents have been found to catalyze the conversion of a penicillin sulfoxide to the cepham/cephem ring system (e.g. 77JOC2887).
The intermediate sulfenic acid derived from a penicillin sulfoxide has been trapped by a large assortment of reagents and, in one case, the sulfenic acid itself has been isolated (74JA1609). Only some of these products will be discussed here, and the reader is referred to the cited reviews (especially B-80MI51102) for additional examples. [Pg.306]

Various other reagents have been used to trap the intermediate sulfenic acid, and Scheme 14 shows some of these (74JCS(P1)1459, 74TL725, 74JCS(P1)1456, 77JCS(P1)1477, 70TL4897, 78TL4167). [Pg.308]

Section 15.13 Thiols are compounds of the type RSH. They are more acidic than alcohols and are readily deprotonated by reaction with aqueous base. Thiols can be oxidized to sulfenic acids (RSOH), sulfinic acids (RSO2H), and sulfonic acids (RSO3H). The redox relationship between thiols and disulfides is important in certain biochemical processes. [Pg.655]

The first compound of this class with inhibitory activity on the enzyme and on acid secretion was the 2-(pyridylmethyl)sulfinylbenzimidazole, timopra-zole, and the fust pump inhibitor used clinically was omeprazole, 2-[[3,5-dimethyl-4-methoxypyridin-2-yl] methylsulfinyl]-5-methoxy- lH-benzimidazole. Omeprazole is an acid-activated prodrug. Omeprazole and the other PPIs are accumulated in the acidic space of the parietal cell due to the pKa of the pyridine nitrogen and these are converted due to protonation of the benzimidazole nitrogen first to a thiol-reactive cationic sulfenic acid and then dehydrated to form the sulfenamide (Fig. 1). These thiophilic cations then bind to luminally... [Pg.1032]

Proton Pump Inhibitors and Acid Pump Antagonists. Figure 2 Chemical mechanism of irreversible PPIs. PPIs are accumulated in acidic lumen and converted to active sulfenic acid and/or sulfenamide by acid catalysis. These active forms bind to extracytoplasmic cysteines of the gastric H.K-ATPase [3]. [Pg.1033]

The reaction of 16a on heating with methanol to give the sulfenic acid intermediate 142 and the sulfmate 143 (which was further transformed into the disulfide 144) was interpreted in terms of the mechanism shown in equation 58161. [Pg.423]

The addition of sulfenic acids to olefins207 has been successfully applied in the synthesis of thietanoprostanoids, the thietane analogues of prostaglandin245. The general synthetic scheme is presented in equation 83207. The key step is the thermolysis of either erythro- or (7ireo-2-f-butylsulphinyl-3-vinyl-l-ol (209) to give the corresponding alkenesulfenic acids 210, which cyclize spontaneously to a mixture of stereoisomeric thietane oxides. [Pg.445]

Acyclic sulfoxides fragment into olefins and sulfenic acids on thermolysis97. Cyclic sulfoxides exhibit essentially the same ready mode of fragmentation106. [Pg.450]

The main result of the thermolysis of the three-membered ring sulfoxides and sulfones is the extrusion of the sulfur monoxide and the sulfur dioxide moieties (Section III.C. I)99 10 5. Only in the presence of a suitably disposed /J-hydrogen does the ordinary sulfoxide-sulfenic acid fragmentation take place in the thiirane oxide series (equation 9). [Pg.450]

It is noteworthy that, based on the sulfoxide- sulfenic acid rearrangement, the readily accessible 1,3-dithiolane systems (316) may be utilized (equation 116) as an efficient entry into the 1,4-dithiane series303, including the construction of carbocyclic fused systems304. The oxidation of the dithienes 318 to the corresponding sulfoxides (319 and 320) and sulfones is a simple, straightforward process. [Pg.462]

Jones and Lewton250 have also demonstrated the utility of the intramolecular addition of sulfenic acids to olefins as a stereospecific method for the synthesis of thiolan 1-oxides. [Pg.752]

The sulfenic acids have been found to be extremely active radical scavengers showing rate constants of at least 107 m"1 s 1 for the reactions with peroxyl radicals at 333 K17. It has also been suggested that the main inhibiting action of dialkyl sulfoxides or related compounds in the autoxidation of hydrocarbon derives from their ability to form the transient sulfenic acids on thermal decomposition, i.e.17... [Pg.1083]


See other pages where Sulfenic acid, 132 is mentioned: [Pg.315]    [Pg.18]    [Pg.71]    [Pg.131]    [Pg.11]    [Pg.152]    [Pg.156]    [Pg.162]    [Pg.306]    [Pg.307]    [Pg.312]    [Pg.303]    [Pg.273]    [Pg.93]    [Pg.436]    [Pg.226]    [Pg.400]    [Pg.401]    [Pg.425]    [Pg.718]    [Pg.732]    [Pg.747]    [Pg.747]    [Pg.750]    [Pg.750]    [Pg.876]   
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1-Propenyl sulfenic acid

2-Propene sulfenic acid

Alcohols sulfenic acid ester

Allyl sulfenic acid

Amino sulfenic acids

Azetidinone 4-sulfenic acid

Electrophilic sulfenic acid

Protein sulfenic acids

Sulfenate

Sulfenates

Sulfene

Sulfenes

Sulfenic acid derivatives

Sulfenic acid elimination

Sulfenic acid esters acids

Sulfenic acid esters disulfides

Sulfenic acid esters ethers

Sulfenic acid esters sulfoxides

Sulfenic acid oxidation

Sulfenic acid, synthesis

Sulfenic acids, esters

Sulfenic acids, heterocyclic

Sulfenic acids, reduction

Sulfoxides sulfenic acid elimination

Thiols, Sulfides and Sulfenic Acids

Thiolsulfonic and sulfenic acid ester

Thiosulfinates sulfenic acids

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