3D-QSAR/HQSAR-based analysis of bioconcentration and molecular modification of monophenyl aromatic compounds

Authors : Qing LI, Wenwen GU, Yu LI

Pages : 286-306

View : 11 | Download : 7

Publication Date : 0000-00-00

Article Type : Research Paper

Abstract :Comparative molecular field analysis insert ignore into journalissuearticles values(CoMFA); and comparative molecular similarity indices analysis insert ignore into journalissuearticles values(CoMSIA); of three-dimensional quantitative structure-activity relationship insert ignore into journalissuearticles values(3D-QSAR); models were conducted using 36 aromatic compound congeners as the training set and eight aromatic compound congeners as the test set. Logarithms of experimental bioconcentration data insert ignore into journalissuearticles values(logBCF); were used as dependent variables and the physicochemical properties of the aromatic compound congeners were used as independent variables. Furthermore, the molecular holographic quantitative structure--activity relationship insert ignore into journalissuearticles values(HQSAR); model constructed by the HQSAR module in Sybyl software was used to establish a method to find molecular activity substitution sites of bioconcentration potential by coupling the molecule activity contribution map of HQSAR with the electrostatic contour map of CoMSIA. Pentachlorobenzene insert ignore into journalissuearticles values(PeCB); was used as the target molecule to design PeCB derivatives with low bioconcentrations. Seven PeCB derivatives with low bioconcentrations showed no significant changes in molecular toxicity and migration, while 5-NO$_{2}$-PeCB and six other PeCB derivatives showed increased degradation abilities. By quantitative calculation using density functional theory, the flame retardancy and insulation properties of the PeCB derivatives were found to remain unchanged, except for those of 5-NO$_{2}$-PeCB.
Keywords : Aromatic compounds, bioconcentration, three dimensional quantitative, holographic quantitative structure activity relationship