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Upstream product

• 10271-55-3 2-(ethylthio)-1-phenylethanone 
• 100-42-5 styrene 
• 70-29-1 diethyl sulphide 
• 20035-08-9 sodium ethanesulfinate 
• 93-91-4 1-phenylbutan-1,3-dione 
• 37984-88-6 ethanesulfonic acid hydrazide 
• 2206-94-2 1-acetoxy-1-phenylethene 
• 19433-17-1 acetophenone O-acetyloxime 
• 13735-81-4 1-styrenyloxytrimethylsilane 
• 594-44-5 Ethanesulfonyl chloride 
• 98-86-2 acetophenone 
• 536-74-3 phenylacetylene 
• 40721-68-4 N-morpholino-1-phenylethan-1-imine 
• 1889-59-4 ethyl vinyl sulfone 

Relevant academic research and scientific papers

Method for preparing beta-carbonyl sulfone compound by using half-sandwich iridium complex

The invention relates to a method for preparing a beta-carbonyl sulfone compound by using a half-sandwich iridium complex, which comprises the following step: in the presence of alkali, by taking acetophenone and sulfonyl chloride as raw materials and taking the half-sandwich iridium complex containing an o-carboborylbenzoxazole structure as a catalyst, conducting reacting at room temperature to prepare the beta-carbonyl sulfone compound. Compared with the prior art, the method has the advantages that the half-sandwich iridium complex containing the o-carboborylbenzoxazole structure is used as the catalyst, acetophenone and sulfonyl chloride are efficiently catalyzed to react under the room temperature condition to synthesize the beta-carbonyl sulfone compound, the product yield is high, the reaction condition is mild, the substrate is cheap and easy to obtain, and the catalytic efficiency is high.

Oxidative Sulfonylation of Hydrazones Enabled by Synergistic Copper/Silver Catalysis

A copper/silver-cocatalyzed protocol for oxidative sulfonylation of hydrazones is demonstrated. A wide range of β-ketosulfones and N-acylsulfonamides are directly synthesized in moderate to good yields. Our work provides a viable method for scalable preparation of β-ketosulfone derivatives that have found wide applications in the pharmaceutical industry.

A glucose oxidase-hemoglobin system for efficient oxysulfonylation of alkenes/alkynes in water

Background: β-ketosulfones are important bioactive compounds that have been extensively studied in organic chemistry. In this work, a green and efficient process for the synthesis of β-ketosulfones from alkenes (1) or alkynes (3) with sodium benzenesulfinate (2) was developed. Results: Under optimal conditions (alkenes (0.5 mmol) or alkynes (0.5 mmol), sodium benzenesulfinate (0.5 mmol), water (2 mL), hemoproteins (heme concentration: 0.06 mol%), GOX (42 U/ml), room temperature, 2 h), high yields of β-ketosulfones could be obtained when HgbRb (hemoglobin from rabbit blood) and GOX (glucose oxidase from Aspergillus niger) was used as the catalyst. Conclusion: This enzymatic method demonstrates the great potential for the synthesis of β-ketosulfones and extends the application of dual protein systems in organic synthesis.

Method for synthesizing beta-ketosulfone derivative under mild condition and obtained beta-ketosulfone derivative

The invention discloses a method for synthesizing a beta-ketosulfone derivative under a mild condition, which comprises the following steps: dissolving aryl olefin and sodium sulfinate in a solvent in a reaction container, adding an acidic additive, sealing the reaction container under the conditions that air exists in the reaction container and no transition metal exists, and purifying after reaction to obtain the beta-ketosulfone derivative. The free radical addition oxidation reaction of olefin and sulfinic acid can be realized under the mild condition without transition metal, the reaction raw materials are cheap and easy to obtain, no organic metal reagent or transition metal is needed, air is used as an oxidizing agent, no dangerous peroxide or persulfide is needed, and the method is compatible with air. The method has the advantages of simple operation and the like, and overcomes the defects of transition metal participation, large catalyst consumption, expensive reagents, high method cost, more reaction steps, more by-products and the like in the prior art.

Dioxygen-Triggered Oxosulfonylation/Sulfonylation of Terminal Olefins toward β-Keto Sulfones/Sulfones

A dioxygen-triggered oxosulfonylation/sulfonylation of unactivated olefins to achieve β-keto sulfones/sulfones has been developed. Interestingly, pluralistic mechanisms were found when different types of compounds were applied as substrates, and different products were achieved. The reaction is carried out with a high atomic efficiency in the absence of a metal and a catalyst at room temperature under an air atmosphere. Importantly, as a proof-of-concept, a bioactive molecule was synthesized on a gram-scale level using this method.

Metal-Free Electrochemical Coupling of Vinyl Azides: Synthesis of Phenanthridines and β-Ketosulfones

We reported an efficient and environmentally benign electrochemical synthesis of phenanthridines by oxidative coupling of vinyl azides with sodium azide or benzenesulfonyl hydrazides, for the first time. The reaction conditions are mild, and no additional metal-catalyst or exogenous oxidants are needed. The protocol has broad substrate scope and high functional group tolerance. Furthermore, this green electrochemical procedure can be readily extended to the synthesis of β-ketosulfones. Gram scale reactions further demonstrate the practicability.

Cyanide-Mediated Synthesis of Sulfones and Sulfonamides from Vinyl Sulfones

We report a facile synthesis of sulfones, β-keto sulfones, and sulfonamides from vinyl sulfones via an addition-elimination sequence where in situ generation of nucleophilic sulfinate ion is mediated by cyanide. The use vinyl sulfones renders high selectivity for S -alkylation to produce sulfones in high yields. In the presence of N -bromosuccinimide, primary and secondary amines underwent sulfonamide formation. A preliminary mechanistic study showed the formation of acrylonitrile as an innocent byproduct, without interfering with the desired reaction pathway while generating a sulfinate nucleophile.

Biomimetic photocatalytic sulfonation of alkenes to access β-ketosulfones with single-atom iron site

Biomimetic photocatalysis as an important organic transformation strategy has received increasing attention, with the performances of biomimetic catalysts largely depending on their design. This protocol has been initially used to fabricate a biomimetic photocatalyst of single-atom iron site through coupling carbon nitride with hemin (CNH) for the visible light-promoted sulfonation of alkenes to produce β-ketosulfones with up to 94% yield. The experimental results show that the role of CN in CNH is concentrated on enhancing the separation ability of photogenerated electron pairs and holes to improve the photocatalytic activity and stability. Moreover, the as-prepared photocatalyst of single atom iron can be irradiated under near-infrared light with a satisfactory yield, and is also feasible for the sulfonation reactions of androstenones. Importantly, this biomimetic catalysis-based synthesis system has some merits, namely high catalysis efficiency, favorable recyclability, high turnover number, and excellent functional group tolerance, making it promising for extensive applications in organic transformations for the synthesis of β-ketosulfones to access various bioactive drugs.

A Naphthalimide-Based ND-O-EAc Photocatalyst for Sulfonation of Alkenes to Access β-Ketosulfones Under Visible Light

The development of facile, efficient, cost-effective, and visible light-driven photocatalysts for organic synthetic chemistry has received increasing attention. This protocol has initially synthesized a naphthalimide-based ND-O-EAc visible light photocatalyst for the sulfonation of alkenes to produce β-ketosulfones. Compared with the current photosynthetic strategies, the newly developed catalytic system has some merits, namely high efficiency, gram-scale preparation of low-cost photocatalyst, no metal contamination, wide substrate scope, and green terminal oxidant of air. Moreover, the prepared photocatalyst of ND-O-EAc is feasible for the sulfonation reactions of androstenones. Importantly, such a photocatalysis strategy can easily realize the scale-up synthesis for β-ketosulfone drugs under the mild conditions up to 90 % yield.

Visible-light-promoted aerobic oxidative synthesis of β-ketosulfones under photocatalyst-free conditions

A simple and convenient visible-light-mediated method has been developed for the construction of β-ketosulfones via aerobic oxidative difunctionalization of alkynes with arylazo sulfones and dioxygen in air under photocatalyst-free conditions. The present photochemical methodology provides a facile and attractive protocol to construct a series of β-ketosulfones in moderate to good yields.