Microplastics (MPs), are defined as tiny plastics with particle size less than 5 mm. Ecological concerns and health risks of MPs contamination have been attracting a worldwide attention within a decade. While a large body of literature has shown that MPs are highly likely to be accumulated in aquatic and terrestrial biota, information about the toxic interactions of MPs on organisms from a mechanistic point of view is more limited. This thesis filled this knowledge gap by assessing polystyrene (PS)-MPs in zebrafish, red tilapia, and mice systems based on a toxicokinetic/toxicodynamic (TK/TD) modeling to quantify organ-bioaccumulation and biomarker responses appraised with published datasets. Exposure risks for aquatic model organisms including bivalves were also presented by utilizing the published environmentally relevant concentration data of PS-MPs in marine and freshwater ecosystems. The organ-specific TK-parameters and mean residence times for zebrafish, red tilapia, and mice posed by size-specific PS-MPs could be obtained. The highest uptake rates were in the liver of zebrafish, in the gut of red tilapia and mice, respectively. Results showed that steady-state bioconcentration factors (BCFsss) of PS-MPs among all organs were much greater than 1, indicating the bioaccumulating potential of PS-MPs in animals. In comparison to mice, zebrafish have commonly much greater BCFsss in organs. The sensitivities of biomarkers regarding immunological response, oxidative stress, detoxification, and energy and lipid metabolisms to PS-MPs in liver of organisms were determined by the TD assessment. These concentration-effect relationships based on the Hill model varied with species used, exposure time, and particle size of PS-MPs in each system. As the result, toxicity thresholds of PS-MPs were in a large variability. Results demonstrated that the most sensitive biomarkers in bivalves, zebrafish, red tilapia, and mice systems, based on strict threshold concentrations, were phagocytic cells, superoxide dismutase (SOD), 7-ethoxyresorufin O-deethylase, and SOD, respectively. A risk-based probabilistic model was further used to characterize the potential hazards of marine bivalves and freshwater fish in response to predicted environmental concentrations of PS-MPs quantified by exceedance risks and risk quotients. Among five global plastic-filled gyres, the highest and lowest risks were occurred in the North Pacific and South Pacific Oceans for bivalves, respectively. For freshwater fish, the Winyah Bay in USA appeared to be the greatest risks among the selected local areas. The present results warranted further attention on worldwide MPs pollution posing hazards to aquatic organisms, particularly sensitive species like zebrafish taking the brunt of the long-term toxicity risk. Moreover, the mice-based TK parameters and threshold criteria greatly assist in designing robust researches to evaluate MPs consumption by humans. An extrapolation framework was proposed for mechanistically estimating toxicity thresholds of MPs from mice to humans in a health risk assessment perspective. Overall, results derived from the TK/TD assessment, the Weibull threshold model, and the ecotoxicological risk assessment could be adopted to rapidly evaluate MPs-induced toxicities at various concentrations. The strict thresholds could be recommended as criteria for environmental management of MPs and offer a tool-kit in establishing the scheme for risk assessment of human consumption.