Investigating the photosensitivity of koneramines for cell imaging and therapeutic applications

Abstract: The photophysical properties of the anthracene appended koneramines (LAn) were analyzed and utilized as a chemosensor for the selective detection of Cd2+ and Zn2+. The complexation-induced inhibition of PET (photo-induced...

“…This suggests that the koneramine formation is immune to the size and electronic properties of the N-substitution of ethylenediamine component. This allows one to access the koneramine complex with any groups substituted on the non-coordinating backbone nitrogen (N4) such as lightsensitive anthracenyl, [13] pyrenyl or dansyl groups, redox-active ferrocenyl moiety, proton-sensitive pyridyl or pyrazinyl groups and even small molecule binding 1,3,5-triazinyl group. [12] Even though the koneramine complexes can be assembled in one-pot reactions and they are stable enough to be characterized using multiple analytical techniques, they are fragile in acidic environments and even in protic solvents at times; [12] this is due to the fragile hemiaminal ether linkage that could take part in a dynamic equilibrium with its iminium counterpart, especially in protic and/or nucleophilic solvents (Figure 4).…”

“…This suggests that the koneramine formation is immune to the size and electronic properties of the N ‐substitution of ethylenediamine component. This allows one to access the koneramine complex with any groups substituted on the non‐coordinating backbone nitrogen (N4) such as light‐sensitive anthracenyl, [13] pyrenyl or dansyl groups, redox‐active ferrocenyl moiety, proton‐sensitive pyridyl or pyrazinyl groups and even small molecule binding 1,3,5‐triazinyl group [12] …”

Late‐stage Ligand Modification After Coordination Strengthens Stereoselectively Self‐Assembled Hemiaminal Ether Complexes

“…This suggests that the koneramine formation is immune to the size and electronic properties of the N-substitution of ethylenediamine component. This allows one to access the koneramine complex with any groups substituted on the non-coordinating backbone nitrogen (N4) such as lightsensitive anthracenyl, [13] pyrenyl or dansyl groups, redox-active ferrocenyl moiety, proton-sensitive pyridyl or pyrazinyl groups and even small molecule binding 1,3,5-triazinyl group. [12] Even though the koneramine complexes can be assembled in one-pot reactions and they are stable enough to be characterized using multiple analytical techniques, they are fragile in acidic environments and even in protic solvents at times; [12] this is due to the fragile hemiaminal ether linkage that could take part in a dynamic equilibrium with its iminium counterpart, especially in protic and/or nucleophilic solvents (Figure 4).…”

“…This suggests that the koneramine formation is immune to the size and electronic properties of the N ‐substitution of ethylenediamine component. This allows one to access the koneramine complex with any groups substituted on the non‐coordinating backbone nitrogen (N4) such as light‐sensitive anthracenyl, [13] pyrenyl or dansyl groups, redox‐active ferrocenyl moiety, proton‐sensitive pyridyl or pyrazinyl groups and even small molecule binding 1,3,5‐triazinyl group [12] …”

Late‐stage Ligand Modification After Coordination Strengthens Stereoselectively Self‐Assembled Hemiaminal Ether Complexes

“…This multifaceted approach, harnessing the power of synergistic interactions, enhanced spectrum coverage, and resistance mitigation, epitomizes a judicious and innovative strategy in our ceaseless quest to combat bacterial infections and safeguard the public health. [30,31,32]…”

Pyridine‐2,6‐Dicarboxamide Proligands and their Cu(II)/Zn(II) Complexes Targeting Staphylococcus Aureus for the Attenuation of In Vivo Dental Biofilm

Metal and solvent dependent formation of imidazolidine or hemiaminal ether complexes