2 research outputs found
Modeling the Dynamics of Mixture Toxicity and Effects of Organic Micropollutants in a Small River under Unsteady Flow Conditions
The presence of anthropogenic organic micropollutants
in rivers
poses a long-term threat to surface water quality. To describe and
quantify the in-stream fate of single micropollutants, the advectionādispersionāreaction
(ADR) equation has been used previously. Understanding the dynamics
of the mixture effects and cytotoxicity that are cumulatively caused
by micropollutant mixtures along their flow path in rivers requires
a new concept. Thus, we extended the ADR equation from single micropollutants
to defined mixtures and then to the measured mixture effects of micropollutants
extracted from the same river water samples. Effects (single and mixture)
are expressed as effect units and toxic units, the inverse of effect
concentrations and inhibitory concentrations, respectively, quantified
using a panel of in vitro bioassays. We performed a Lagrangian sampling
campaign under unsteady flow, collecting river water that was impacted
by a wastewater treatment plant (WWTP) effluent. To reduce the computational
time, the solution of the ADR equation was expressed by a convolution-based
reactive transport approach, which was used to simulate the dynamics
of the effects. The dissipation dynamics of the individual micropollutants
were reproduced by the deterministic model following first-order kinetics.
The dynamics of experimental mixture effects without known compositions
were captured by the model ensemble obtained through Bayesian calibration.
The highly fluctuating WWTP effluent discharge dominated the temporal
patterns of the effect fluxes in the river. Minor inputs likely from
surface runoff and pesticide diffusion might contribute to the general
effect and cytotoxicity pattern but could not be confirmed by the
model-based analysis of the available effect and chemical data
Modeling the Dynamics of Mixture Toxicity and Effects of Organic Micropollutants in a Small River under Unsteady Flow Conditions
The presence of anthropogenic organic micropollutants
in rivers
poses a long-term threat to surface water quality. To describe and
quantify the in-stream fate of single micropollutants, the advectionādispersionāreaction
(ADR) equation has been used previously. Understanding the dynamics
of the mixture effects and cytotoxicity that are cumulatively caused
by micropollutant mixtures along their flow path in rivers requires
a new concept. Thus, we extended the ADR equation from single micropollutants
to defined mixtures and then to the measured mixture effects of micropollutants
extracted from the same river water samples. Effects (single and mixture)
are expressed as effect units and toxic units, the inverse of effect
concentrations and inhibitory concentrations, respectively, quantified
using a panel of in vitro bioassays. We performed a Lagrangian sampling
campaign under unsteady flow, collecting river water that was impacted
by a wastewater treatment plant (WWTP) effluent. To reduce the computational
time, the solution of the ADR equation was expressed by a convolution-based
reactive transport approach, which was used to simulate the dynamics
of the effects. The dissipation dynamics of the individual micropollutants
were reproduced by the deterministic model following first-order kinetics.
The dynamics of experimental mixture effects without known compositions
were captured by the model ensemble obtained through Bayesian calibration.
The highly fluctuating WWTP effluent discharge dominated the temporal
patterns of the effect fluxes in the river. Minor inputs likely from
surface runoff and pesticide diffusion might contribute to the general
effect and cytotoxicity pattern but could not be confirmed by the
model-based analysis of the available effect and chemical data