Potential microbial toxicity and non-target impact of different concentrations of glyphosate-containing herbicide (GCH) in a model pervious paving system

- GCH concentration influences species richness of protists.
- GCH concentration above 72 mg L−1 was fatal to the protists.
- GCH concentration above 720 mg L−1 had adverse effect on the bacteria community.
- Colpoda cucullus and Colpoda steinii may be used as biomarkers of GCH-polluted environment.
- At GCH concentration of 72 mg L−1, biodegradation processes may not be affected.

Pervious Pavement Systems are Sustainable Drainage devices that meet the three-fold SUDS functions of stormwater quantity reduction, quality improvement and amenity benefits. This paper reports on a study to determine the impact of different concentrations of glyphosate-containing herbicides on non-target microorganisms and on the pollutant retention performance of PPS. The experiment was conducted using 0.0484 m2 test rigs based on a four-layered design. Previous studies have shown that PPS can trap up to 98.7% of applied hydrocarbons, but results of this study show that application of glyphosate-containing herbicides affected this capability as 15%, 9% and 5% of added hydrocarbons were released by high (7200 mg L−1), medium (720 mg L−1) and low (72 mg L−1) glyphosate-containing herbicides concentrations respectively. The concentrations of nutrients released also indicate a potential for eutrophication if these effluents were to infiltrate into aquifers or be released into surface waters. The effect of glyphosate-containing herbicides application on the bacterial and fungal communities was slightly different; fungi exhibited a “top-down” trend as doses of 7200 mg L−1 glyphosate-containing herbicides yielded the highest fungal growth whilst those with a concentration of 720 mg L−1 glyphosate-containing herbicides applied yielded the highest bacterial growth. In the case of protists, doses of glyphosate-containing herbicides above 72 mg L−1 were fatal, but they survived at the lower concentration, especially the ciliates Colpoda cucullus and Colpoda steinii thus indicating potential for their use as biomarkers of herbicide-polluted environments. Data also showed that at the lowest concentration of glyphosate-containing herbicides (72 mg L−1), biodegradation processes may not be affected as all trophic levels required for optimum biodegradation of contaminants were present.