Involvement of electron and hydrogen transfers through redox metabolism on activity and toxicity of the nimesulide.

An electronic study of nimesulide was performed by using density functional theory calculations. The activities of the six different derivatives were related with electron donating or accepting capacities. All compounds which had nitro moiety had low electron donating and high electron accepting capacities. However, the reduced derivative of nimesulide have more electron donating capacity than other compounds. The highest spin density contribution in nitro and lowest spin density contribution on phenoxyl moieties can be related with preferential metabolism by reduction when compared with the oxidation. The redox behavior between nitro and amino groups can be related with anti-inflammatory mechanism of nimesulide. These results explain the redox influence of nitro moiety on biological metabolism and mechanism of nimesulide.

Understanding the cytotoxicity or cytoprotective effects of biological and synthetic quinone derivatives by redox mechanism.

Quinones represent an important class of biological compounds, but are also involved with toxicological intermediates and among their hazardous effects include cytotoxicity, immunotoxicity, and carcinogenesis. The structure-toxicity relationship for quinone derivatives has been used to cytotoxicity or cytoprotective effects by redox mechanism is determined using quantum chemical calculations through the density functional theory (DFT). According to our DFT study, the electron acceptance is related with LUMO, electron affinity, and stabilization energy values. The highest spin density distribution in the heteroatoms is more favored for the more cytotoxic compounds. The electrophilic capacities of these compounds have been related with LUMO values. The cytotoxic properties of quinones are related to the stabilization energy after electron accepting by redox mechanism. Electron affinity is the most relevant parameter related to toxicity mechanism. Regioisomers has different electrophilic capacity. The electrophilicity increases on molecules containing electron-withdrawing groups (EWG) and reduces on molecules containing electron-donating groups (EDG). These results explain the toxic difference between natural and synthetic quinone derivatives and can be used in the design and study of new drugs.