Search Results (2)

Due to the abundant and promising biological activities of aromatic hydrazones, it is of great significance to study the biological activities of their metal complexes for the research and development of metal-based drugs. In this review, we focus on the metal complexes of polycyclic aromatic hydrazones, which still do not receive much attention, and summarize the studies related to their biological activities. Although the large number of metal complexes in phenylhydrazone prevent them all from being summarized, the significant value of polycyclic aromatic hydrocarbons themselves (such as naphthalene and anthracene) as pharmacophores are also considered. Therefore, the bioactivities of the metal complexes of naphthylhydrazone and anthrahydrazone are focused on, and the recent research progress on the metal complexes of anthrahydrazone by the authors is also included. In terms of biological activities, these complexes mainly show antibacterial and anticancer activities, along with less bioactivities. The present review demonstrates that the structural design and bioactivities of these complexes are fundamental, which also indicates a certain structure—activity relationship (SAR) in some substructural areas. However, a systematic and comprehensive conclusion of the SAR is still not available, which suggests that more attention should be paid to the bioactivities of the metal complexes of polycyclic aromatic hydrazones since their potential in structural design and biological activity remains to be explored. We hope that this review will attract more researchers to devote their interest and energy into this promising area. Full article

A new rhodium(III) complex of a 9-anthrahydrazone ligand ((Z)-2-(2-(Anthracen-9-ylmethylene)hydrazineyl)pyrimidine, 9-PMAH) is six-coordinated respectively by one bidentate ligand, one solvent DMSO, and three chlorides, to form a distorted octahedral coordination geometry. The ligand chelates to Rh(III) via the hydrazone N atom (N1) and pyrimidine N atom (N3), whereas DMSO coordinates to Rh(III) via the S atom. The three chloride ligands (Cl1, Cl2, and Cl3) are in a mer-configuration of the octahedron, with the DMSO cis- to the pyrimidine nitrogen. In solution, the complex may exist in the positively charged species, [Rh^IIICl₂(DMSO)(9-PMAH)]⁺, but can be stable in this mode for no less than 48 h. It was suggested by the fluorescence spectroscopic analysis that the complex showed much higher intercalative binding ability with ct-DNA than the typical DNA intercalator, EtBr. Full article