21101-60-0

Upstream product

• 101-59-7 4-amino-4'-nitrodiphenyl sulfide 
• 110-46-3 isopentyl nitrite 
• 937-32-6 4-nitrobenzenesulfenyl chloride 
• 108-95-2 phenol 
• 637-89-8 4-sulfanylphenol 
• 586-78-7 para-nitrophenyl bromide 
• 17796-89-3 1-[(4-nitrophenyl)sulfanyl]pyrrolidine-2,5-dione 
• 27691-43-6 1-(benzylsulphanyl)-4-Nitrobenzene 
• 1849-36-1 para-nitrobenzenethiol 
• 701-57-5 1-methylthio-4-nitro-benzene 
• 100-32-3 di(p-nitrophenyl) disulfide 
• 62-53-3 aniline 
• 636-98-6 p-nitrobenzene iodide 
• 350-46-9 4-Fluoronitrobenzene 

Downstream Products

• 22865-50-5 4-(4-methoxyphenylsulfanyl)nitrobenzene 
• 100062-94-0 4-(4-aminophenylsulfamyl)phenol 
• 59010-91-2 O-Methyl O-[4-(4'-nitrophenylthio)phenyl] S-n-propyl Phosphorothiolate 
• 62248-53-7 4-(4-ethoxy-phenylsulfanyl)-aniline 
• 62248-51-5 4-(4-butoxyphenyl)thioaniline 
• 1375738-29-6 4-benzyloxy-4'-nitrodiphenylsulfide 
• 62248-47-9 4-butoxy-4'-nitrodiphenylsulfide 
• 876486-96-3 4-ethoxy-4'-nitrodiphenylsulfide 
• 1375738-26-3 4-propoxy-4'-nitrodiphenylsulfide 
• 1241-12-9 4-(2-Diethylaminoethoxy-4'-nitrodiphenyl Sulfide 

Relevant academic research and scientific papers

Making the family portrait complete: Synthesis of Electron Withdrawing Group activated Hoveyda-Grubbs catalysts bearing sulfone and ketone functionalities

Synthesis of five Electron Withdrawing Group (EWG) activated Hoveyda-Grubbs’ catalysts containing thioperfluoroalkyl, sulfone and ketone functions is reported. The catalytic activity of these catalysts was well correlated with the σp values of

Transition-Metal-Free Aryl-Heteroatom Bond Formation via C-S Bond Cleavage

Aryl-heteroatom bonds (C-Het) are almost ubiquitously present in chemical molecules. However, methods for diverse C-Het bond formations from a simple substrate are limited. Herein, we report a convenient and efficient C-S bond transformation of aryl sulfoniums to various C-Het bonds (C-O, C-S, C-Sn, C-Si, C-Se) in the absence of any transition-metal catalyst. These reactions proceeded in mild conditions with a wide substrate scope.

TBATB mediated debenzylative cross-coupling of aryl benzyl sulfides with electron rich compounds: Synthesis of diaryl sulfides

An efficient TBATB mediated debenzylative cross coupling of aryl benzyl sulfides with electron rich compounds provides diaryl sulfides in moderate to excellent yield. The salient features of the present protocol are simplicity, high efficiency and compati

Iron or boron-catalyzed C-H arylthiation of substituted phenols at room temperature

A simple, efficient and environmentally friendly method for iron or boron-catalyzed C-H arylthiation of substituted phenols at room temperature has been developed, and the corresponding diaryl sulfides were prepared in good to excellent yields. The protocol uses readily available 1-(substituted phenylthio)pyrrolidine-2,5-diones as the arylthiation reagents and inexpensive and environmentally friendly FeCl3 or BF3·OEt 2 as the catalyst, moreover no ligands, additives or extrusion of air are required, and the reactions can be performed successfully at room temperature. This journal is the Partner Organisations 2014.

Silver ion mediated in situ synthesis of mixed diaryl sulfides from diaryl disulfides

The AgNO3-mediated in situ scission of aromatic disulfides in the presence of electron-rich aromatic compounds results in the efficient synthesis of diaryl sulfides. Key features of this new methodology are high yields of aromatic and heteroaromatic sulfides, mild reaction conditions, simplicity, simple workup, and avoiding foul-smelling reactants like thiols. Georg Thieme Verlag Stuttgart · New York.

Microwave-assisted Ullmann-Buchwald C-S bond formation using a copper(I) catalyst and trans-cyclohexane-1,2-diol as ligand

Microwave irradiation of a thiophenol or alkyl thiol (1 equiv.) and an aryl halide (1 equiv.) in 2-propanol at 120°C for three hours in the presence of K2CO3 (2 equiv.) as base using copper(I) iodide as catalyst (5 mol%) and trans-cyclohexane-1,2-diol (2 equiv.) as ligand provides a rapid and convenient method for C-S bond formation. The process is most efficient using thiophenol and aryl iodide precursors, both of which may contain electron-donating and electronwithdrawing groups, to give the corresponding diaryl sulfide in good to excellent yield. ARKAT-USA, Inc.

Design, synthesis and antitumor activity of novel cis-furoquinoline derivatives

A series of novel cis-furoquinoline derivatives was synthesized and tested for their antitumor activities in vitro against HepG2 cells, Lu-04 cells and Leu02 cells to evaluate structure-activity relationships. Assay-based antiproliferative activity study revealed that several compounds had significant effects on cytotoxicity, among which compounds 2f, 2l, 2q were found to be the most active compounds. Above all, compounds 2f, 2l, 2q would be potential anticancer agents which deserved further research.

Correspondence between Molecular Functionality and Crystal Structures. Supramolecular Chemistry of a Family of Homologated Aminophenols

The crystal structures and packing features of a family of 13 aminophenols, or supraminols, are analyzed and correlated. These compounds are divided into three groups: (a) compounds 1-5 with methylene spacers of the general type HO-C6H4-(CH2)n- C6H 4-NH2 (n = 1 to 5) and both OH and NH2 in a para position; (b) compounds la, 2a, 2b, 2c, and 3a in which one or more of the methylene linkers in 1 to 3 are exchanged with an S-atom; and (c) compounds 2d, 1b, and 6a prepared with considerations of crystal engineering and where the crystal structures may be anticipated on the basis of structures 1-5, 1a, 2a, 2b, 2c, and 3a. These 13 aminols can be described in terms of three major supramolecular synthons based on hydrogen bonding between OH and NH2 groups: the tetrameric loop or square motif, the infinite N(H)O chain, and β-As sheet. These three synthons are not completely independent of each other but interrelate, with the structures tending toward the more stable β-As sheet in some cases. Compounds 1-5 show an alternation in melting points, and compounds with n = even exhibit systematically higher melting points compared to those with n = odd. The alternating melting points are reflected in, and explained by, the alternation in the crystal structures. The n = odd structures tend toward the β-As sheet as n increases and can be considered as a variable series whereas for n = even, the β-As sheet is invariably formed constituting a fixed series. Substitution of a methylene group by an isosteric S-atom may causes a change in the crystal structure. These observations are rationalized in terms of geometrical and chemical effects of the functional groups. This study shows that even for compounds with complex crystal structures the packing may be reasonably anticipated provided a sufficient number of examples are available.

Discovery of new inhibitors of aldose reductase from molecular docking and database screening

Aldose reductase (ALR2) is a target enzyme for the treatment of diabetic complications. Owing to the limited number of currently available drugs for the treatment of diabetic complications, the discovery of new inhibitors of ALR2 that can potentially be optimized as drugs appears highly desirable. In this study, a molecular docking analysis of the structures of more than 127,000 organic compounds contained in the National Cancer Institute database was performed to find and score molecules that are complementary to ALR2. Besides retrieving several carboxylic acid derivatives, which are known to generally inhibit aldose reductase, docking proposed other families of putative inhibitors such as sulfonic acids, nitro-derivatives, sulfonamides and carbonyl derivatives. Twenty-five compounds, chosen as the highest-scoring representatives of each of these families, were tested as aldose reductase inhibitors. Five of them were found to inhibit aldose reductase in the micromolar range. For these active compounds, selectivity with respect to the closely-related aldehyde reductase was determined by measuring the corresponding inhibitory activities. The structures of the complexes between the new lead inhibitors and aldose reductase, here refined with molecular mechanics and molecular dynamics calculations, suggest that new pharmacophoric groups can bind aldose reductase very efficiently. In the case of the family of the nitro-derivative inhibitors, a class of particularly interesting compounds, a round of optimizations was performed with the synthesis and biological evaluation of a series of derivatives aimed at testing the proposed binding mode and at improving interaction with active site residues. Starting from a hit compound having an IC50 of 42 μM, the most potent compound synthesized showed a 10-fold increase in inhibitory activity and 10-fold selectivity with respect to ALR1, and structure-activity relationships of the designed compounds were in agreement with the proposed mode of binding at the active site.