620-24-6Relevant articles and documents
Electroreduction of m-Hydroxybenzoic Acid. Preparation of m-Phenoxybenzyl Alcohol for the New Insecticide Ethofenprox
Oi, Ryu,Shimakawa, Chitoshi,Shimokawa, Yasushi,Takenaka, Shinji
, p. 4193 - 4196 (1987)
The electroreduction of m-hydroxybenzoic acid was examined from both mechanistic and technical points of view, and a practical route to m-phenoxybenzyl alcohol has been developed.
Synthesis of unsymmetrical 5,6-POCOP′-type pincer complexes of nickel(II): Impact of nickelacycle size on structures and spectroscopic properties
Salah, Abderrahmen,Corpet, Martin,Ul-Hassan Khan, Najm,Zargarian, Davit,Spasyuk, Denis M.
, p. 6649 - 6658 (2015)
This report describes the synthesis and characterization of a family of unsymmetrical pincer complexes of nickel(ii), featuring both 5- and 6-membered nickelacycles. The room temperature reaction of NiBr2(NCCH3)x with bis(phosphinite) ligand, 1-(i-Pr2PO),3-(i-Pr2POCH2)-C6H4 (POCHOP′), results in direct nickelation at the 2-position of the aromatic ring to give (5,6-POCOP′)NiBr (5,6-POCOP′ = κP,κC,κP′-2-(i-Pr2PO),6-(i-Pr2POCH2)-C6H3). This complex undergoes salt metathesis reactions with M′X to give the corresponding charge neutral derivatives, (5,6-POCOP′)NiX (X = OSO2CF3, OSO2(4-CH3-C6H4), CH3, and CCCH3), whereas the abstraction of bromide by AgBPh4 in acetonitrile gave the cationic derivative, [(5,6-POCOP′)Ni(NCCH3)][BPh4]. The new complexes have been characterized by multinuclear NMR spectroscopy and X-ray diffraction studies. The reactivities of the new complexes (5,6-POCOP′)NiX (X = Br, OSO2CF3) have been explored briefly to establish the nucleophilicity of the X ligand and the substitutional lability of the phosphinite moiety in the 6-membered cycle.
Synthesis, crystal and structural characterization, Hirshfeld surface analysis and DFT calculations of three symmetrical and asymmetrical phosphonium salts
Delaram, Behnaz,Gholizadeh, Mostafa,Makari, Faezeh,Nokhbeh, Seyed Reza,Salimi, Alireza
, (2021/07/01)
Three stable phosphonium salts of 1,4-butanediylebis(triphenylphosphonium) dibromide I, butane-4?bromo-1-(triphenylphosphonium) bromide II and 1,3-propanediylbis(triphenylphosphonium) tetrahydroborate III were synthesized and structurally characterized. Single crystal X-ray diffraction analysis, spectroscopic methods and thermal analysis methods were used for the characterization of titled compounds. Crystallographic data showed that compound I crystallized in the triclinic crystal system with Pī space group and compound II crystallized in the monoclinic crystal system with P21/c space group. The crystal packing structures of I and II were stabilized by various intermolecular interactions, especially of C–H···π contacts. The molecular Hirshfeld surface analysis and 2D fingerprint revealed that the C···H contacts have 24.3% and 18.4% contributions in the crystal packings of compounds I and II, respectively. In addition, the H···Br (28.5%) contact has a considerable contribution to the crystal architecture of compound II. Theoretical studies were performed by DFT method to investigate the structural properties of the titled compounds. The isotopic ratio of boron in tetrahydroborate anion of compound III calculated by 1H NMR spectroscopy. The isotopic ratio for 10B/11B was 19.099 / 80.900%. Reduction of some carbonyl compounds to corresponding alcohols was performed by compound III and the optimum conditions were determined.
α-D-Mannoside ligands with a valency ranging from one to three: Synthesis and hemagglutination inhibitory properties
Al-Mughaid, Hussein,Khazaaleh, Maha
, (2021/07/25)
Six mono-, di-, and trivalent α-D-mannopyranosyl conjugates built on aromatic scaffolds were synthesized in excellent yields by Cu(I) catalyzed azide-alkyne cycloaddition reaction (CuAAC). These conjugates were designed to have unique, flexible tails that combine a mid-tail triazole ring, to interact with the tyrosine gate, with a terminal phenyl group armed with benzylic hydroxyl groups to avoid solubility problems as well as to provide options to connect to other supports. Biological evaluation of the prepared conjugates in hemagglutination inhibition (HAI) assay revealed that potency increases with valency and the trivalent ligand 6d (HAI = 0.005 mM) is approximately sevenfold better than the best meta-oriented monovalent analogues 2d and 4d (HAI ≈ 0.033 mM) and so may serve as a good starting point to find new lead ligands.