TY - JOUR
T1 - Experimental evidence from the field that naturally weathered microplastics accumulate cyanobacterial toxins in eutrophic lakes
AU - Hataley, Eden K.
AU - Shahmohamadloo, Rene S.
AU - Ortiz Almirall, Xavier
AU - Harrison, Anna L.
AU - Rochman, Chelsea M.
AU - Zou, Shan
AU - Orihel, Diane M.
N1 - Funding text:
We thank K. Schneider and T. Schneider and the residents of Hideaway Lane for providing access to Buck Lake and Dog Lake, respectively. We also thank H. Vanderlip and A. Zborowski for their assistance in the lab and A. Tian, M. Dias, K. Brouwer, and J. Reynolds for their assistance in the field. Our research was funded by the Natural Sciences and Engineering Council of Canada (Discovery Grant RGPIN‐2020‐06956 to D. M. Orihel) and in‐kind contributions from the Ontario Ministry of the Environment, Conservation and Parks. E. K. Hataley was supported by the Natural Sciences and Engineering Council of Canada (Collaborative Research and Training Experience Program Grant 401208952 to R. S. Brown, Queen's University, D. M. Orihel, and others). Kal‐Polymers (Mississauga, Canada) provided samples of recycled plastic polymers for our study.
Copyright: © 2022 SETAC
PY - 2022/12
Y1 - 2022/12
N2 - Freshwater ecosystems with recurring harmful algal blooms can also be polluted with plastics. Thus the two environmental problems may interact. To test whether microplastics influence the partitioning of microcystins in freshwater lakes, we examined the sorption of four microcystin congeners to different polymers of commercially available plastics (low-density polyethylene, polyethylene terephthalate, polyvinyl chloride, and polypropylene). We conducted three experiments: a batch sorption experiment in the laboratory with pristine microplastics of four different polymers, a second batch sorption experiment in the laboratory to compare pristine and naturally weathered microplastics of a single polymer, and a 2-month sorption experiment in the field with three different polymers experiencing natural weathering in a eutrophic lake. This series of experiments led to a surprising result: microcystins sorbed poorly to all polymers tested under laboratory conditions (<0.01% of the initial amount added), irrespective of weathering, yet in the field experiment, all polymers accumulated microcystins under ambient conditions in a eutrophic lake (range: 0-84.1 ng/g). Furthermore, we found that the sorption capacity for microcystins differed among polymers in the laboratory experiment yet were largely the same in the field. We also found that the affinity for plastic varied among microcystin congeners, namely, more polar congeners demonstrated a greater affinity for plastic than less polar congeners. Our study improves our understanding of the role of polymer and congener type in microplastic-microcystin sorption and provides novel evidence from the field, showing that naturally weathered microplastics in freshwater lakes can accumulate microcystins. Consequently, we caution that microplastics may alter the persistence, transport, and bioavailability of microcystins in freshwaters, which could have implications for human and wildlife health. Environ Toxicol Chem 2022;00:1-12. (c) 2022 SETAC
AB - Freshwater ecosystems with recurring harmful algal blooms can also be polluted with plastics. Thus the two environmental problems may interact. To test whether microplastics influence the partitioning of microcystins in freshwater lakes, we examined the sorption of four microcystin congeners to different polymers of commercially available plastics (low-density polyethylene, polyethylene terephthalate, polyvinyl chloride, and polypropylene). We conducted three experiments: a batch sorption experiment in the laboratory with pristine microplastics of four different polymers, a second batch sorption experiment in the laboratory to compare pristine and naturally weathered microplastics of a single polymer, and a 2-month sorption experiment in the field with three different polymers experiencing natural weathering in a eutrophic lake. This series of experiments led to a surprising result: microcystins sorbed poorly to all polymers tested under laboratory conditions (<0.01% of the initial amount added), irrespective of weathering, yet in the field experiment, all polymers accumulated microcystins under ambient conditions in a eutrophic lake (range: 0-84.1 ng/g). Furthermore, we found that the sorption capacity for microcystins differed among polymers in the laboratory experiment yet were largely the same in the field. We also found that the affinity for plastic varied among microcystin congeners, namely, more polar congeners demonstrated a greater affinity for plastic than less polar congeners. Our study improves our understanding of the role of polymer and congener type in microplastic-microcystin sorption and provides novel evidence from the field, showing that naturally weathered microplastics in freshwater lakes can accumulate microcystins. Consequently, we caution that microplastics may alter the persistence, transport, and bioavailability of microcystins in freshwaters, which could have implications for human and wildlife health. Environ Toxicol Chem 2022;00:1-12. (c) 2022 SETAC
KW - Absorption
KW - Adsorption
KW - Algal toxins
KW - Biofilm
KW - Freshwater toxicology
KW - Microplastics
UR - https://www.scopus.com/record/display.uri?eid=2-s2.0-85141787026&origin=inward
UR - https://www.webofscience.com/api/gateway?GWVersion=2&SrcApp=pure_univeritat_ramon_llull&SrcAuth=WosAPI&KeyUT=WOS:000880170500001&DestLinkType=FullRecord&DestApp=WOS
U2 - 10.1002/etc.5485
DO - 10.1002/etc.5485
M3 - Article
C2 - 36148929
SN - 0730-7268
VL - 41
SP - 3017
EP - 3028
JO - Environmental Toxicology and Chemistry
JF - Environmental Toxicology and Chemistry
IS - 12
ER -
