Development of quantitative structure activity relationships (QSARs) for predicting the aggregation of TiO2 nanoparticles under favorable conditions

Authors

• Jaewoong Lee, University of Nebraska-Lincoln

Document Type

Article

Date of this Version

3-8-2024

Citation

Heliyon 10 (2024) e27966. https://doi.org/10.1016/j.heliyon.2024.e27966

Comments

Open access.

Abstract

This study developed multi-linear regression (MLR) quantitative structure-activity relationships (QSARs) to predict n-TiO₂ aggregation in the presence of high concentrations of representative emerging organic contaminants (EOCs), which presented favorable conditions to interaction with n-TiO₂. The largest diameter change (Δ 517 nm at 0 h and Δ 1164 nm at 12 h) of n-TiO₂ was observed by estrone, while the smallest diameter change (Δ -114 nm at 0 h and – 4 nm at 12 h) was observed by lincomycin during experimental periods. In addition, the zeta potential changes of n-TiO₂ were observed that the biggest changes were observed by 17β-estradiol (-1.3 mV) and alachlor (-10.02 mV) at 0 h, while 17β-estradiol (-1.31 mV) and pendimethalin (-11.4 mV) showed the biggest changes at 12 h comparing to control. These changes of n-TiO₂ diameter and zeta potential may implicate the effects of unique physico-chemical properties of each EOC on the surface modification of n-TiO₂. Based on the interaction results, this study investigated the QSARs between n-TiO₂ aggregation and physico-chemical descriptors of EOCs with 7 representative descriptors (pK_a, C_w, log K_ow, M.W., P.S.A., M.V., # of HBD) for predicting n-TiO₂ aggregation rate kinetics at 0 h and 12 h by applying MATLAB statistical methods (model 1 - fitlm and model 2 - stepwiselm). In a model 1, QSARs showed the good coefficients of determination (R2 = 0.92) at 0 h and (R² = 0.87) at 12 h with 7 descriptors. In a model 2, QSARs showed the goodness of fit of a model (R² = 0.9998) with 8 descriptors (pK_a, C_w, log K_ow, M.W., P.S.A., M.V., #HBD, pKa⋅#H bond donors) at 0 h, while QSARs showed the coefficients of determination (R² = 0.68) with 2 descriptors (pK_a, M.V.) at 12 h. Particularly, we observed that some descriptors of EOCs such as pK_a and # of HBD having polarity have more influenced on the n-TiO₂ aggregation rate kinetics. Our developed QSARs demonstrated that the 7 descriptors of EOCs were significantly effective descriptors for predicting n-TiO₂ aggregation rate kinetics in favorable conditions, which may implicate the complexity interactions between heterogeneous surfaces of n-TiO₂ and physicochemical properties of EOCs.