3985-12-4

Upstream product

• 108-98-5 thiophenol 
• 108-42-9 3-chloro-aniline 
• 591-19-5 m-Bromoaniline 
• 591-50-4 iodobenzene 
• 22948-02-3 3-aminothiophenol 
• 98-09-9 benzenesulfonyl chloride 
• 873-55-2 sodium benzenesulfonate 
• 626-01-7 3-Iodoaniline 
• 585-79-5 m-nitrobromobenzene 
• 930-69-8 sodium thiophenolate 
• 100-05-0 4-nitrobenzenediazonium chloride 
• 37984-02-4 3-nitrophenyl phenyl sulfide 

Downstream Products

• 103206-21-9 N,N-dimethyl-3-(phenylthio)aniline 
• 47374-41-4 1,1,2,2,2-Pentafluoro-ethanesulfonic acid (3-phenylsulfanyl-phenyl)-amide 
• 37931-08-1 3-Phenylthio-perfluorbutansulfonanilid 
• 37931-10-5 3-Phenylthio-difluormethan-sulfonanilid 
• 37950-57-5 1,1,2,2,2-Pentafluoro-ethanesulfonic acid (3-phenylsulfanyl-phenyl)-amide; compound with triethyl-amine 
• 93001-61-7 3-Amino-diphenylsulfoxid 
• 95813-41-5 (3-benzenesulfonyl-phenyl)-phenyl-diazene 
• 37924-10-0 3-Phenylsulfonyl-perfluoraethansulfonanilid 

Relevant academic research and scientific papers

Electrochemistry Enabled Nickel-Catalyzed Selective C?S Bond Coupling Reaction

This work describes an electrochemical enabled nickel-catalyzed chemoselective C?S bond coupling protocol for the production of aryl sulfides and sulfones. By simply switching the nickel catalysts and electrodes, this electrochemical C?S bond coupling has demonstrated excellent redox activity, scalability and sustainability. Furthermore, the mechanism for this electrochemical cross-coupling reaction has been investigated.

Environmentally Friendly and Recyclable CuCl 2-Mediated C-S Bond Coupling Strategy Using DMEDA as Ligand, Base, and Solvent

Simple reaction conditions and recyclable reagents are crucial for environmentally friendly industrial applications. An environment-friendly, recyclable and economic strategy was developed to synthesize diaryl chalcogenides by the CuCl2-catalyzed C S bondformation reaction via iodobenzenes and benzenethiols/1,2-diphenyldisulfanes using N,N'-dimethylethane-1,2-diamine (DMEDA) as ligand, base, and solvent. For these reactions, especially the reactions of diiodobenzenes and aminobenzenethiols/disulfanediyldianilines, a range of substrates are compatible and give the corresponding products in good to excellent yields. Both of the reagents in the catalytic system (CuCl2/DMEDA) are inexpensive, conveniently separable, and recyclable for more than five cycles.

Hydroboration reduction reaction of aromatic nitro compounds without transition metal catalysis

The invention relates to a hydroboration reduction reaction of aromatic nitro compounds without transition metal catalysis. According to the method, triethyl boron and potassium tert-butoxide are used as catalysts for the first time, and an aromatic nitro compound and pinacol borane which is low in price and easy to obtain can be conveniently catalyzed to be subjected to a hydroboration reduction reaction under mild conditions to prepare aromatic amine products. Compared with a traditional method, the method generally has the advantages that the catalyst is cheap and easy to obtain, operation is convenient, and reaction is safe. The selective hydroboration reduction reaction of the non-transition metal reagent catalyzed aromatic nitro compound and pinacol borane is realized for the first time, and a practical new reaction strategy is provided for laboratory preparation or industrial production of aromatic amine products.

Preventing Pd-NHC bond cleavage and switching from nano-scale to molecular catalytic systems: Amines and temperature as catalyst activators

Many reactions catalyzed by Pd complexes with N-heterocyclic carbene (NHC) ligands are performed in the presence of amines which usually act as coupling reagents or mild bases. However, amines can react with Pd/NHC complexes in a number of ways: enhancing molecular catalysis, causing the catalyst deactivation or triggering the ligandless modes of catalysis by producing NHC-free active palladium species. This study gains insight into conditions required for the efficient use of amines as activators of molecular Pd/NHC catalysis and preventing the undesirable reductive cleavage of the Pd-NHC bond in catalytic systems. Reactions of Pd/NHC complexes with various amines within a temperature range of 25-140 °C and thermal stability of the resulting amino-complexes are examined. The results indicate the major influence of the amine structure and reaction temperature on the catalyst transformation. In particular, thermal decomposition of Pd/NHC complexes with aliphatic amine ligands predominantly leads to reductive Pd-NHC bond cleavage, while deprotonation of the complexes with primary and secondary aliphatic amine ligands in the presence of strong bases at 25-60 °C promotes the activation of molecular Pd/NHC catalysis. Efficient Pd-PEPPSI complex-amine systems suitable for strong-base-promoted C-S cross-coupling reactions between aryl halides and thiols are suggested on the basis of these findings.

Crystallographic and SAR analyses reveal the high requirements needed to selectively and potently inhibit SIRT2 deacetylase and decanoylase

A high-quality X-ray crystal structure reveals the mechanism of compound 1a inhibiting SIRT2 deacetylase and decanoylase. Structure-activity relationship (SAR) analysis of the synthesized derivatives of 1a reveals the high requirements needed for selectiv

Novel SIRT2 protein inhibitor and usage thereof in pharmacy

The invention discloses a compound or salt, crystallographic form and solvate compounds of the compound acceptable in pharmacy, and the compound and the salt, crystallographic form, solvate compounds of the compound are shown as formula I, wherein X is selected from the formulas (please see the specifications for the formula); R1 is selected from aryl or ceteroary or substituted aryl or substituted ceteroary or from the formula (please see the specifications for the formula); R2 is selected from the formulas (please see the specifications for the formula); and R3 is selected from halogen or C1-C4 alkyl or C1-C4 alkoxy. The novel compound shown in formula I has the advantages that not only is good inhibitory activity achieved to SIRT2, but also the inhibiting effect is achieved to the tumor, and the novel compound has good pharmaceutical potentiality and provides a novel potential choice for the clinical medicament.

QUINAZOLINONES AS PROLYL HYDROXYLASE INHIBITORS

Quinazolinone compounds of formula (I) are described, which are useful as prolyl hydroxylase inhibitors. Such compounds may be used in pharmaceutical compositions and methods for the treatment of disease states, disorders, and conditions mediated by prolyl hydroxylase activity. Thus, the compounds may be administered to treat, e.g., anemia, vascular disorders, metabolic disorders, and wound healing.

A general, efficient, and functional-group-tolerant catalyst system for the palladium-catalyzed thioetherification of aryl bromides and iodides

The cross-coupling reaction of aryl bromides and iodides with aliphatic and aromatic thiols catalyzed by palladium complexes of the bisphosphine ligand CyPF-tBu (1) is reported. Reactions occur in excellent yields, broad scope, high tolerance of functional groups, and with turnover numbers that exceed those of previous catalysts by 2 or 3 orders of magnitude. These couplings of bromo- and iodoarenes are more efficient than the corresponding reactions of chloroarenes and could be conducted with less catalyst loading and/or milder reaction conditions. Consequently, limitations regarding scope and functional group tolerance previously reported in the coupling of aryl chlorides are now overcome.

Iron-catalyzed thioetherification of thiols with aryl iodides

FeCl3 in combination with bisphosphine ligands represents an efficient catalyst system for the cross-coupling of aryl- and alkyl thiols with aryl iodides, a broad spectrum of functional groups can be tolerated during the catalysis. The Royal Society of Chemistry 2009.

CATALYSTS FOR ARYL SULFIDE SYNTHESIS AND METHOD OF PRODUCING ARYL SULFIDES

The present invention relates to the formation of aryl sulfides and aryl thiols from aryl halides and thiols, thiolates or thiolate equivalents. The present invention provides a catalyst for the coupling of aryl halides with alkyl or aryl thiols or a hydrogen sulfide equivalent to form aryl alkyl, aryl silyl or diaryl sulfides. The reaction encompasses bromoarenes and other similar compounds containing leaving groups as well as nitrile, ester, keto, free hydroxyl, free amino, free carboxylic acid and other common functionalities. The invention can be used to prepare pharmaceutical compounds, especially including their intermediates, agricultural agents and aryl sulfide polymers.