Understanding the structure-activity relationship and performance of highly active novel ATRP catalysts

Guanidium Unmasked: Repurposing Common Amide Coupling Reagents for the Synthesis of Pentasubstituted Guanidine Bases

Guanidines make up a class of compounds with important applications in catalysis and medicinal chemistry. In this systematic study, we report on the guanylation of aliphatic amines, anilines, (sulfon)amides, ureas, and carbamates by repurposing HATU, a common amide coupling reagent. The products are 2-substituted 1,1,3,3-tetramethylguanidines (TMGs), a group of sterically hindered superbases. The reaction of a guanidinium salt with aliphatic amines has been regarded as an unwanted side-reaction in amide coupling, yet the exact mechanistic details have been unclear. Our mechanistic investigation shows that the guanylation is highly dependent on the nature of the nitrogen nucleophile. Our findings were applied on two fronts: minimizing guanylation in competing amide coupling reactions as well as maximizing guanylation in a simple one-step synthesis of a broad variety of 2-substituted TMGs, including the late-stage functionalization of pharmaceuticals.

ATRP catalysts of tetradentate guanidine ligands - do guanidine donors induce a faster atom transfer?

Tripodal tetradentate N donor ligands stabilise the most active ATRP catalyst systems. Here, we set out to synthesise the new guanidine ligand TMG-4NMe2uns-penp, inspired by p-substituted tris(2-pyridylmethyl)amine (TPMA) ligands. The impact of changing pyridine against guanidine donors was examined through solid state and solution experiments and density functional theory (DFT) calculations. In the solid state, the molecular structures of copper complexes based on the ligands TMG-4NMe2uns-penp, TMG-uns-penp and TMG3tren were discussed concerning the influence of a NMe2 substituent at the pyridines and the guanidine donors. In solution, the TMG-4NMe2uns-penp system was investigated by several methods, including UV/Vis, EPR and NMR spectroscopy indicating similar properties to that of the highly active TPMANMe2 system. The redox potentials were determined and related to the catalytic activity. Besides the expected trends between these and the ligand structures, there is evidence that guanidine donors in tripodal ligand systems lead to a better deactivation and possibly a faster exchange within the ATRP equilibrium than TPMA systems. Supported by DFT calculations, it derives from an easier cleavable Cu-Br bond of the copper(II) deactivator species. The high activity was stated by a controlled initiator for continuous activator regeneration (ICAR) ATRP of styrene.