Pyrrole sulfoxides

Arai and coworkers197 reported the utilization of a chiral pyrrole sulfoxide as a chiral auxiliary in the asymmetric Diels-Alder reactions of its /V-cinnamoyl and /V-crotonyl derivatives 313 with cyclopentadiene which gave 314-317 (equation 87). The results have been summarized in Table 18. The yield as well as the endo/exo selectivity and the de proved to depend on the type and amount of Lewis acid used. 

Characterization of Pyrrole Sulfoxides from Allium Subgenus melanocrommyum... 

Ethyl-4-methyl-l-(phenylsulfonyl)indole 4-Ethyl-7-methyl-l-phenylsulfonyl-l,5-dihydropyrano-[3,4-b]pyrrol-5-one phenyl vinyl sulfoxide 60 [3]... 

Vinyl Pyrroles. Relatively new synthetic routes based on a one-pot reaction between ketoximes and acetjiene ia an alkaU metal hydroxide—dimethyl sulfoxide (DMSO) system have made vinyl pyrroles accessible. It requires no pyrrole precursors and uses cheap and readily available ketones (42). 

Vinyl chloride reacts with sulfides, thiols, alcohols, and oximes in basic media. Reaction with hydrated sodium sulfide [1313-82-2] in a mixture of dimethyl sulfoxide [67-68-5] (DMSO) and potassium hydroxide [1310-58-3], KOH, yields divinyl sulfide [627-51-0] and sulfur-containing heterocycles (27). Various vinyl sulfides can be obtained by reacting vinyl chloride with thiols in the presence of base (28). Vinyl ethers are produced in similar fashion, from the reaction of vinyl chloride with alcohols in the presence of a strong base (29,30). A variety of pyrroles and indoles have also been prepared by reacting vinyl chloride with different ketoximes or oximes in a mixture of DMSO and KOH (31). 

The classical structures of pyrrole, furan and thiophene (31) suggest that these compounds might show chemical reactions similar to those of amines, ethers and thioethers (32) respectively. On this basis, the initial attack of the electrophile would be expected to take place at the heteroatom and lead to products such as quaternary ammonium and oxonium salts, sulfoxides and sulfones. Products of this type from the heteroaromatic compounds under consideration are relatively rare. 

Pyrrole, 4-ethynyl-2-formyl-3-methyl-synthesis, 4, 222 Pyrrole, formyl-oxidation, 4, 289 reactions, 4, 292 with sulfoxides, 4, 293 synthesis, 4, 223, 274, 287 Pyrrole, 1-formyl-barrier to rotation, 4, 193 Pyrrole, 2-formyl-benzoylation, 4, 220 conformation, 2, 107 4, 193 diacetoxythallium derivative iodination, 4, 216 dipole moment, 4, 194 ketals, 4, 290 protonation, 4, 47 reactions... 

VV -values for bromoform and pyrrole, acidic liquids, against poly(vinyl chloride), an acidic polymer, and dimethyl sulfoxide, a predominantly basic liquid, against polyfmethyl methacrylate), a basic polymer, but large values for the acidic liquids against PMMA and the basic liquid against PVC. 2-Iodoethanol, a bifunctional liquid, showed appreciable -values with both polymers. Despite these results in line with expectations, other results based on wettability measurements are not so clear-cut. For example, Vrbanac [94] found significant apparent acid-base interactions of various aromatic liquids against poly(ethylene), presumably a neutral substrate. 

Remote asymmetric induction using chiral sulfoxides, derivatives of furan, thiophene, and pyrrole 98YGK798. 

The rearrangement of cyclic sulfoxide 130a, which could be obtained from the corresponding thiolsulfinate 163 (Section III.C.l), was studied in different experimental conditions. The ci3-sulfoxide refluxed in toluene for 24 h gave a 1 1 mixture of the pyrrole 131 and the dihydro-1,4-thiazine 132. 

The hexahydropyrrolo[l,2- ]imidazole chloro cycloadducts 57a-c, as a 1/1 mixture of stereoisomers, underwent an elimination on treatment with l,8-diazabicyclo[5.4.0]undec-7-ene (DBU) in dimethyl sulfoxide (DMSO) at 100°C. It was not possible to isolate the desired dihydropyrroles 58a-c and a second elimination occurred to form the T-substituted pyrroles 59a-c respectively (Scheme 4) <1998J(P1)2061>. 

Other electrochemical processes of organic compounds on Pb electrodes or electrodes with UPD Pb have been studied - formaldehyde [323], oxalic acid [386], trichloro- and trifluoroethane [387], 1-phenylethylamine [388], 3-hydroxychi-nuclidine [388], dichlorodifluoromethane [389], polychlorobenzenes [390], 1-propa-nol [391], pyrrole polymerization [392], and inorganic compounds - phosphine [388] and sulfate(IV) ions [393]. Simultaneous catalytic or inhibiting influence of organic solvents - acetonitrile, dimethyl-sulfoxide, and Pb + presence on electrooxidation of small organic molecules on Pt electrodes has been studied using on-line mass spectroscopy [394],... 

The action of phosphorus halides on pyrrolinones and related compounds offers an alternative route to chloropyrroles. Yields of around 60% of 2,5-dichloropyrroles were obtained in this way from N-substituted succinimides (82ZC126). Vilsmeier reaction of N-alkylsuccinimidals formed chlorinated pyrrole aldehydes in modest yields (90CJC791), and there are other examples [66YZ158 81H(15)547]. A useful synthesis of chloropyrrole-2-carboxylates employed the action of phosphorus pentachloride on pyrrolidin-2-one-5-carboxylates (40) (87CB45) (Scheme 15), and in a Pummerer-type reaction pyrrol-3-yl sulfoxides were transformed by thionyl chloride into chloropyrroles. Yields were increased to >80% by the use of oxalyl chloride (88JOC2634) (Scheme 15). 

Many common reactions of aliphatic amines, ethers and sulfides (1) involve initial attack by an electrophilic reagent at a lone pair of electrons on the heteroatom salts, quaternary salts, coordination compounds, amine oxides, sulfoxides and sulfones are formed in this way. Corresponding reactions are very rare (c/. Section 3.3.1.3) with pyrroles, furans and thiophenes. These heterocycles react with electrophilic reagents at the carbon atoms (2-3) rather than at the heteroatom. Vinyl ethers and amines (4) show intermediate behavior reacting frequently at the (3-carbon but sometimes at the heteroatom. 

The H-NMR spectra (Table I) show no evidence of tautomerism of 1-hydroxypyrroles to 2H- or 3//-pyrrole 1-oxides and are similar to those of corresponding pyrroles. The hydroxyl proton is not always seen, as in the case of 1-hydroxyindole, and is easily exchanged out by deuterium oxide. The H-NMR spectrum of 2-cyano-2-methyl-2//-pyrrole 1-oxide (2) in dimethyl sulfoxide (DMSO) was unambiguous (Table I), but in deuter-iochloroform, the 3- and 4-protons appeared at the same position. 

Pyrrolization takes place in both polar aprotic solvents (sulfoxides and more reluctantly, amidophosphates) and mixtures thereof with nonpolar and low polarity solvents (dioxane, benzene) taken in a volume ratio to cyclohexanone oxime of (1-25) (1-10). The use of mixed DMSO-... 

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