6316-52-5Relevant articles and documents
Palladium-Catalyzed Synthesis of Aryl Amides through Silanoate-Mediated Hydrolysis of Nitriles
McPherson, Christopher G.,Livingstone, Keith,Jamieson, Craig,Simpson, Iain
supporting information, p. 88 - 92 (2015/12/26)
A procedure for the formation of aryl amides through the palladium-catalyzed coupling of nitriles and aryl bromides, via the formation of intermediary silanoate derived imidate species is reported. Optimization was undertaken and examples of the process are described that furnish the products in up to 86% isolated yield.
Regioselective ortho-nitration of N-phenyl carboxamides and primary anilines using bismuth nitrate/acetic anhydride
Lu, Yang,Li, Yaming,Zhang, Rong,Jin, Kun,Duan, Chunying
supporting information, p. 9422 - 9427 (2013/10/08)
An efficient and one-pot synthetic method for the regioselective ortho-nitration of the N-phenyl carboxamides and primary anilines has been developed by using bismuth nitrate and acetic anhydride as the nitrating reagents. Reaction proceeds at room temperature and results in corresponding ortho-nitrated products in moderate to excellent yields. This method provides an operationally simple, regioselective, and efficient access to synthesize o-nitro anilines under the mild conditions.
Model Systems for Flavoenzyme Activity: Relationships between Cofactor Structure, Binding and Redox Properties
Legrand, Yves-Marie,Gray, Mark,Cooke, Graeme,Rotello, Vincent M.
, p. 15789 - 15795 (2007/10/03)
A series of flavins were synthesized bearing electron-withdrawing and -donating substituents. The electrochemical properties of these flavins in a nonpolar solvent were determined. The recognition of these flavins by a diamidopyridine (DAP) receptor and the effect this receptor has on flavin redox potential was also quantified. It was found that the DAP-flavin binding affinity and the reduction potentials (E1/2) for both the DAP-bound and unbound flavins correlated well with functions derived from linear free energy relationships (LFERs). These results provide insight and predictive capability for the interplay of electronics and redox state-specific interactions for both abiotic and enzymatic systems.