posted on 2021-12-08, 16:10authored byWiebke
Mareile Heinze, Denise M. Mitrano, Elma Lahive, John Koestel, Geert Cornelis
Plastic pollution
is increasingly perceived as an emerging threat
to terrestrial environments, but the spatial and temporal dimension
of plastic exposure in soils is poorly understood. Bioturbation displaces
microplastics (>1 μm) in soils and likely also nanoplastics
(<1 μm), but empirical evidence is lacking. We used a combination
of methods that allowed us to not only quantify but to also understand
the mechanisms of biologically driven transport of nanoplastics in
microcosms with the deep-burrowing earthworm Lumbricus terrestris. We hypothesized that ingestion and subsurface excretion drives
deep vertical transport of nanoplastics that subsequently accumulate
in the drilosphere, i.e., burrow walls. Significant vertical transport
of palladium-doped polystyrene nanoplastics (diameter 256 nm), traceable
using elemental analysis, was observed and increased over 4 weeks.
Nanoplastics were detected in depurated earthworms confirming their
uptake without any detectable negative impact. Nanoplastics were indeed
enriched in the drilosphere where cast material was visibly incorporated,
and the reuse of initial burrows could be monitored via X-ray computed
tomography. Moreover, the speed of nanoplastics transport to the deeper
soil profile could not be explained with a local mixing model. Earthworms
thus repeatedly ingested and excreted nanoplastics in the drilosphere
calling for a more explicit inclusion of bioturbation in nanoplastic
fate modeling under consideration of the dominant mechanism. Further
investigation is required to quantify nanoplastic re-entrainment,
such as during events of preferential flow in burrows.