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An assessment of direct and indirect effects of two herbicides on aquatic communities

Herbicides are often detected in watersheds at concentrations that are toxic to phytoplankton, potentially causing indirect effects on higher trophic organisms. The long‐term effects of 5 applications over 30 d of binary mixtures of the herbicides diuron and hexazinone were assessed at “low” and “hi...

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Published in:Environmental toxicology and chemistry 2017-08, Vol.36 (8), p.2234-2244
Main Authors: Hasenbein, Simone, Lawler, Sharon P., Connon, Richard E.
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description Herbicides are often detected in watersheds at concentrations that are toxic to phytoplankton, potentially causing indirect effects on higher trophic organisms. The long‐term effects of 5 applications over 30 d of binary mixtures of the herbicides diuron and hexazinone were assessed at “low” and “high” concentrations typically found in the environment, using mesocosms. Sixteen of 95 phytoplankton taxa, 3 of 18 zooplankton taxa, and 6 of 14 macroinvertebrate taxa responded negatively to contaminant exposures. Herbicide applications altered the phytoplankton community structure. Relative abundance of Cyanophyceae decreased following 5 applications from 52.1% in the control to 37.3% in the low treatment and to 25.9% in the high treatment, while Chlorophyceae increased to 50.6% in the low treatment and to 61.7% in the high treatment compared with the control (39.7%). Chlorophyceae had the greatest number of affected species (8), whereas 1 species within the Cyanophyceae was negatively affected on more than 1 sampling day. Further, chlorophyll a was reduced on 4 and 5 d out of the 8 total sampling days in the low and high treatments, respectively, compared with the control. These results highlight that integrating multiple taxa and contaminants with long‐term exposures in ecological risk assessments of herbicides can facilitate the ability to make predictive and mechanistic generalizations about the role of herbicides in shaping patterns of species abundance in natural systems. Environ Toxicol Chem 2017;36:2234–2244. © 2017 SETAC
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The long‐term effects of 5 applications over 30 d of binary mixtures of the herbicides diuron and hexazinone were assessed at “low” and “high” concentrations typically found in the environment, using mesocosms. Sixteen of 95 phytoplankton taxa, 3 of 18 zooplankton taxa, and 6 of 14 macroinvertebrate taxa responded negatively to contaminant exposures. Herbicide applications altered the phytoplankton community structure. Relative abundance of Cyanophyceae decreased following 5 applications from 52.1% in the control to 37.3% in the low treatment and to 25.9% in the high treatment, while Chlorophyceae increased to 50.6% in the low treatment and to 61.7% in the high treatment compared with the control (39.7%). Chlorophyceae had the greatest number of affected species (8), whereas 1 species within the Cyanophyceae was negatively affected on more than 1 sampling day. Further, chlorophyll a was reduced on 4 and 5 d out of the 8 total sampling days in the low and high treatments, respectively, compared with the control. These results highlight that integrating multiple taxa and contaminants with long‐term exposures in ecological risk assessments of herbicides can facilitate the ability to make predictive and mechanistic generalizations about the role of herbicides in shaping patterns of species abundance in natural systems. 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subjects Abundance
Algae
Amphipoda - drug effects
Amphipoda - metabolism
Animals
Aquatic communities
Aquatic Organisms - drug effects
Aquatic Organisms - metabolism
Aquatic toxicology
Binary mixtures
Chlorophyll
Chlorophyll - metabolism
Chlorophyll a
Community structure
Contaminants
Diuron
Diuron - toxicity
Ecological risk assessment
Environmental Monitoring - methods
Exposure
Food web
Herbicides
Herbicides - toxicity
Hexazinone
Long-term effects
Macroinvertebrates
Mesocosm
Mesocosms
Phytoplankton
Phytoplankton - drug effects
Phytoplankton - metabolism
Plankton
Relative abundance
Risk assessment
Sampling
Taxa
Triazines - toxicity
Water Pollutants, Chemical - toxicity
Watersheds
Zooplankton
Zooplankton - drug effects
Zooplankton - metabolism
title An assessment of direct and indirect effects of two herbicides on aquatic communities
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