97044-22-9

Upstream product

• 6462-50-6 sodium 4-methoxybenzenesulfinate 
• 106-45-6 para-thiocresol 
• 459-64-3 4-methoxybenzenediazonium tetrafluoroborate 
• 104-94-9 4-methoxy-aniline 
• 1709-60-0 4-methoxybenzenesulfinic acid 
• 5335-87-5 4,4'-dimethoxyphenyl disulfide 
• 824-79-3 sodium 4-methylbenzenesulfinate 
• 1950-68-1 4-methoxybenzenesulfonyl hydrazide 
• 103-19-5 di(p-tolyl) disulfide 

Relevant academic research and scientific papers

Preparation method of thiosulfonate compound

The invention belongs to the field of organic synthetic chemistry, and particularly discloses a preparation method of a thiosulfonate compound. The specific preparation process comprises the following steps: taking aryl diazonium salt, sodium pyrosulfite and thiophenol/mercaptan as raw materials, taking organic dye as a photocatalyst, adding an organic solvent, and reacting for 12 hours at room temperature under the irradiation of an LED visible light lamp and nitrogen protection to generate thiosulfonate; and after the reaction is finished, adding distilled water into the reaction system, extracting the reaction liquid with ethyl acetate, concentrating the extraction liquid to obtain a crude product, and carrying out silica gel column chromatography separation on the crude product to obtain thiosulfonate. According to the method, simple and easily available sodium pyrosulfite is used as a sulfone source, cheap organic dye is used as a photocatalyst, clean light energy is used as a reaction energy source, a high-energy-consumption heating device and a metal catalyst or strong acid are not used, the reaction condition is mild, the operation is simple and convenient, and a green synthesis strategy is provided for thiosulfonate.

Atom transfer radical addition to styrenes with thiosulfonates enabled by synergetic copper/photoredox catalysis

A synergetic copper/photoredox catalyzed ATRA of styrenes and thiosulfonates is developed. Besides aryl ethylenes, the challenging α-substituted styrenes were employed to construct the benzylic quaternary carbon centers. Owing to the mild conditions as well as the high level of substrate compability, this ATRA could be applied to derivatize bioactive natural products in late stage, and to install fluorophores across alkenes. The mechanistic studies reveal sulfonyl radicals as the key intermediate in the transformation.

TFA promoted multi-component reaction of aryldiazonium with sodium metabisulphite and thiols: Construction of thiosulfonate under transition-metal free conditions

A TFA promoted multi-component reaction of aryldiazonium with sodium metabisulphite and thiols to construct thiosulfonates under transition-metal free conditions is reported. The thiosulfonates were isolated in good yields with broad tolerance of function

Metal-Free Synthesis of Thiosulfonates via Insertion of Sulfur Dioxide

A simple and catalyst-free strategy was developed for the synthesis of unsymmetrical thiosulfonates using readily available DABCO?(SO2)2 as a solid and bench-stable sulfur dioxide surrogate. The corresponding thiosulfonates were obtained through a radical pathway with good functional group tolerance. This strategy offers a promising synthesis method for the construction of diverse and useful thiosulfonates in the field of synthetic and pharmaceutical chemistry and extends the number of still limited sulfur dioxide fixation strategies. (Figure presented.).

Visible-light mediated sulfonylation of thiols via insertion of sulfur dioxide

A simple and efficient visible-light mediated synthesis of thiosulfonates via a radical-radical coupling of sulfenyl radicals and arylsulfonyl radicals was developed. The reaction of thiols, aryldiazonium tetrafluoroborates and DABSO proceeded at room temperature using 5 mol% eosin Y. The reaction displayed wide functional group tolerance and delivered the unsymmetrical thiosulfonates in good to excellent yields.

Electrochemical Oxidative Cross-Coupling Reaction to Access Unsymmetrical Thiosulfonates and Selenosulfonates

The electrochemical oxidative cross-dehydrogenative coupling of arylsulfinic acids with thiophenols was achieved via a radical process. A wide range of arylsulfinic acids and substituted thiophenols were found to be tolerated, providing unsymmetrical thio

Solvent Controlled Transformation between Sulfonyl Hydrazides and Alkynes: Divergent Synthesis of Benzo[b]thiophene-1,1-dioxides and (E)-β-iodo Vinylsulfones

A green, efficient and controllable transformation between sulfonyl hydrazides and alkynes leading to benzo[b]thiophene-1,1-dioxides and (E)-β-iodo vinylsulfones via radical pathway has been developed. The reaction occurs rapidly in the presence of simply H2O2 and KI without the help of any transition metal. The chemoselectivity of the reaction is determined by the solvent in which the process is performed: TFE favors the cyclic product, while H2O medium generates the iodosulfonylative product. Notably, this protocol also represents the first direct approach to the aggregation-induced-emmision (AIE) active benzo[b]thiophene-1,1-dioxides from readily available sulfonyl hydrazides and alkynes in one step. (Figure presented.).

H2O2-mediated metal-free protocol towards unsymmetrical thiosulfonates from sulfonyl hydrazides and disulfides in PEG-400

A green and practical protocol between sulfonyl hydrazides and disulfides is herein reported for the synthesis of unsymmetrical thiosulfonates with the assistance of H2O2 in PEG-400, releasing N2 and H2O as the byproducts. The efficient and compatible process was considered to take place in the absence of metallic catalysts through a radical mechanism as determined by EPR analysis.

Metal-free NaI/TBHP-mediated sulfonylation of thiols with sulfonyl hydrazides

A highly efficient sulfonylation of thiols has been achieved through the metal-free NaI/TBHP-mediated cross-coupling of sulfonyl hydrazides and thiols at room temperature. This method provides a convenient and practical route to thiosulfonates in 84-99% y

Electrochemical sulfonylation of thiols with sulfonyl hydrazides: A metal- and oxidant-free protocol for the synthesis of thiosulfonates

An efficient electrochemical transformation of structurally diverse sulfonyl hydrazides and thiols into thiosulfonates in the presence of ammonium iodide as redox catalyst and electrolyte in acetonitrile at ambient temperature is reported. Transition metal- and oxidant-free conditions are the striking features of this protocol. The in vitro cytotoxicity of all compounds is evaluated by MTT assay against four human cancer cell lines. The results reveal that 3ac and 3ag exhibit potential inhibitory activity against tumor cells. Furthermore, 3ag inhibits cell migration ability and tubulin polymerization in T-24 cells, leading to cell cycle arrest and apoptosis.