Sulfones, vinyl functionalization

Vinyl sulfones can function as acetylene equivalents through the elimination of sulfinic acid. Reck and coworkers prepared a series of vinyl sulfones for cycloaddition reactions with azides to prepare 1,2,3-triazole derivatives to be incorporated into new oxazolidinone antibacterial agents. Included in the series was the cycloaddition of l-fluoro-l-(phenylsulfonyl)ethylene with the oxizolidinone 156 to give, after elimination of phenylsulfonic acid, a 28% yield of a 1 7 mixture of the regioisomeric 4-and 5-fluorotriazoles (157 and 158) (Fig. 3.91). 

The addition of a fugitive acid such as camphorsulfonic acid to styrene polymerizations contaminates the polymer with a substance that could lead to corrosion of equipment being used to process the polymer. To solve this problem, Dow researchers added vinyl functional sulfonic acids (eg, 2-sulfoethyl methacrylate) to the polymerization (175). The acid then becomes copolymerized into the polymer, thus immobilizing it. Also, they found that the addition of as low as 10 ppm... 

In analogy to vinyl sulfone fiber-reactive dyes, water repellents with the vinyl sulfone function have been patented [42]. The /3-hydroxyethylsulfate group, which, in the presence of alkali forms the reactive vinyl sulfone intermediate, functions as a water-solubilizing group and gives the water repellent an amphiphilic character until reacted with alkali. 

The soluble polymeric drugs differ from the insoluble type in that they are soluble in the body fluids. For this reason, these polymers could be administered orally or injected into the body and would not require surgery. These polymers could be homopolymers, such as poly(acrylic acid) or sodium poly(vinyl sulfonate) which show some antineoplastic activity, or they could be a copolymer which contains a drug unit and a second monomer whose primary function is to confer solubility on the copolymer system in the body fluids. These could be copolymers of a drug unit containing monomer with such comonomers as acrylic acid, N-vinylpyrrolidone, vinylamine oxides, vinyl sulfonate, vinyl imidazole or related monomers. Several examples of such systems have been prepared (5,6, 9-11). 

In view of the limited capacity of the sulfur atom in the sulfoxide and sulfone functional groups to transmit conjugative effects due to the insulating effect of the LUMO sulfur d-orbitals45,46,56, the application of the UV technique even in the case of the cyclic vinyl sulfones (e.g. thiete dioxides 6b) cannot be expected to find extensive use. UV spectra of substituted thiete dioxides in which an extended conjugated system (e.g. 194) exists in the molecule, did provide useful information for structure elucidation231. However, the extent... 

Base-induced eliminative ring fission, in which both the double bond and the sulfone function take part, has been observed in thiete dioxides253. The reaction can be rationalized in terms of initial Michael-type addition to the double bond of the ring vinyl sulfone, followed by a reverse aldol condensation with ring opening. The isolation of the ether 270c in the treatment of 6c with potassium ethoxide (since the transformation 267 -> 268 is not possible in this case) is in agreement with the reaction mechanism outlined in equation 101253. 

The application of vinyl sulfones as synthones has been restricted since conversion of the sulfonyl group to another functional moiety is generally difficult. 

Vinyl sulfones such as 262 are smoothly converted to a,) -unsaturated nitriles such as 263 on treatment with KCN in the presence of dicyclohexyl-18-crown-6 in refluxing t-butyl alcohol (equation 155)148. The reaction conditions are compatible with base-labile functionalities such as a methoxycarbonyl group (equation 156)148. This method can be used in the preparation of the sesquiterpene aldehyde nuciferal from allyl phenyl sulfones. 

Hydrozirconation of terminal alkynes R-C=CH (R= aryl, alkyl) with 1 affords terminally ( )-Zr-substituted alkenes with high efficiency and excellent stereochemical and regiochemical control (>98%). These alkenylzirconocene complexes are of particular interest for synthetic use [136, 143, 144]. Moreover, beside the electropositive halogen sources [145] and heteroatom electrophiles [3] used in the pioneering studies to directly cleave the Zr-C bond, ( )-vinyl-Zr complexes were recently transformed into a number of other trans-functionalized alkenes such as ( )-vinyl-sul-fides[146], vinylic selenol esters [147], vinyl-sulfones [148], vinyl-iodonium [149], vinyl-(R0)2P(0) [150], and vinilic tellurides [143]. 

Vinyl sulfones are reactive as dienophiles. The sulfonyl group can be removed reductively with sodium amalgam (see Section 5.6.2). In this two-step reaction sequence, the vinyl sulfone functions as an ethylene equivalent. The sulfonyl group also permits alkylation of the adduct, via the carbanion. This three-step sequence permits the vinyl sulfone to serve as the synthetic equivalent of a terminal alkene.68... 

Most immobilization methods require modification of the ligands for anchoring to the support by introducing functional groups such as vinyl, trialkoxysilyl, sulfonic acid, and amino groups. The consequence is often a more elaborate synthesis of the ligand, which adds to the costs of an immobilized catalyst. However, two interesting approaches were developed in recent years, when unmodi-... 

Since PTFE was first synthesized more than 50 years ago, fluoropolymers have been produced by radical polymerization and copolymerizaton processes, but without any functional groups, for several reasons. First, the synthesis of functional vinyl compounds suitable for radical polymerization is much more complicated and expensive in comparison with common fluoroolefins. In radical polymerization of one of the simplest possible candidates—perfluorovinyl sulfonic acid (or sulfonyl fluoride—there was not enough reactivity to provide high-molecular-weight polymers or even perfluorinated copolymers with considerable functional comonomer content. Several methods for the synthesis of the other simplest monomer—trifluoroacrylic acid or its esters—were reported,1 but convenient improved synthesis of these compounds as well as radical copolymerization with TFE induced by y-irradiation were not described until 1980.2... 

A class of DUBs only identified since 2002 is the OTU (ovarian tumor protein) DUB class. The OTU domain was originally identified in an ovarian tumor protein from Drosophila mdanogaster, and over 100 proteins from organisms ranging from bacteria to humans are annotated as having an OTU domain. The members of this protein superfamily were annotated as cysteine proteases, but no specific function had been demonstrated for any of these proteins. The first hint of a role for OTU proteins in the ubiquitin pathway was afforded by the observation that an OTU-domain-containing protein, HSPC263, reacted with ubiquitin vinyl sulfone (an active-site-directed irreversible inhibitor of DUBs) [41]. 

M. Shi and Y.-L. Shi reported the synthesis and application of new bifunctional axially chiral (thio) urea-phosphine organocatalysts in the asymmetric aza-Morita-Baylis-Hillman (MBH) reaction [176, 177] of N-sulfonated imines with methyl vinyl ketone (MVK), phenyl vinyl ketone (PVK), ethyl vinyl ketone (EVK) or acrolein [316]. The design of the catalyst structure is based on axially chiral BINOL-derived phosphines [317, 318] that have already been successfully utilized as bifunctional catalysts in asymmetric aza-MBH reactions. The formal replacement of the hydrogen-bonding phenol group with a (thio)urea functionality led to catalysts 166-168 (Figure 6.51). 

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