Abstract
There has been an on-going pursuit for relations between the levels of chemicals in plants/crops and the source levels in soil or water in order to address impacts of toxic substances on human health and ecological quality. In this research, we applied the quasi-equilibrium partition model to analyze the relations for nonionic organic contaminants between plant/crop roots and external soil/water media. The model relates the in-situ root concentration factors of chemicals from external water into plant/crop roots (RCF((water))) with the system physicochemical parameters and the chemical quasi-equilibrium states with plant/crop roots (α(pt,) ≤1). With known RCF((water)) values, root lipid contents (f(lip)), and octanol-water K(ow)'s, the chemical-plant α(pt) values and their ranges of variation at given f(lip)K(ow) could be calculated. Because of the inherent relation between α(pt) and f(lip)K(ow), a highly distinct correlation emerges between log RCF((water)) and log f(lip)K(ow) (R(2) = 0.825; n = 368), with the supporting data drawn from 19 disparate soil-plant studies covering some 6 orders of magnitude in f(lip)K(ow) and 4 orders of magnitude in RCF((water)). This correlation performs far better than any relationship previously developed for predicting the contamination levels of pesticides and toxic organic chemicals in plant/crop roots for assessing risks on food safety.