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Microplastics affect arsenic bioavailability by altering gut microbiota and metabolites in a mouse model

Authors :
Shan Chen
Jin-Lei Yang
Yao-Sheng Zhang
Hong-Yu Wang
Xin-Ying Lin
Rong-Yue Xue
Meng-Ya Li
Shi-Wei Li
Albert L. Juhasz
Lena Q. Ma
Dong-Mei Zhou
Hong-Bo Li
Chen, Shan
Yang, Jin Lei
Zhang, Yao Sheng
Wang, Hong Yu
Lin, Xin Ying
Xue, Rong Yue
Li, Meng Ya
Li, Shi Wei
Juhasz, Albert L
Ma, Lena Q
Zhou, Dong Mei
Source :
Environmental Pollution. 324:121376
Publication Year :
2023
Publisher :
Elsevier BV, 2023.

Abstract

Refereed/Peer-reviewed Microplastics exposure is a new human health crisis. Although progress in understanding health effects of microplastic exposure has been made, microplastic impacts on absorption of co-exposure toxic pollutants such as arsenic (As), i.e., oral bioavailability, remain unclear. Microplastic ingestion may interfere As biotransformation, gut microbiota, and/or gut metabolites, thereby affecting As oral bioavailability. Here, mice were exposed to arsenate (6 μg As g−1) alone and in combination with polyethylene particles of 30 and 200 μm (PE-30 and PE-200 having surface area of 2.17 × 103 and 3.23 × 102 cm2 g−1) in diet (2, 20, and 200 μg PE g−1) to determine the influence of microplastic co-ingestion on arsenic (As) oral bioavailability. By determining the percentage of cumulative As consumption recovered in urine of mice, As oral bioavailability increased significantly (P < 0.05) from 72.0 ± 5.41% to 89.7 ± 6.33% with PE-30 at 200 μg PE g−1 rather than with PE-200 at 2, 20, and 200 μg PE g−1 (58.5 ± 19.0%, 72.3 ± 6.28%, and 69.2 ± 17.8%). Both PE-30 and PE-200 exerted limited effects on pre- and post-absorption As biotransformation in intestinal content, intestine tissue, feces, and urine. They affected gut microbiota dose-dependently, with lower exposure concentrations having more pronounced effects. Consistent with the PE-30-specific As oral bioavailability increase, PE exposure significantly up-regulated gut metabolite expression, and PE-30 exerted greater effects than PE-200, suggesting that gut metabolite changes may contribute to As oral bioavailability increase. This was supported by 1.58–4.07-fold higher As solubility in the presence of up-regulated metabolites (e.g., amino acid derivatives, organic acids, and pyrimidines and purines) in the intestinal tract assessed by an in vitro assay. Our results suggested that microplastic exposure especially smaller particles may exacerbate the oral bioavailability of As, providing a new angle to understand health effects of microplastics.

Details

ISSN :
02697491
Volume :
324
Database :
OpenAIRE
Journal :
Environmental Pollution
Accession number :
edsair.doi.dedup.....82b66eb9338aa5c7668c7e5aaa6957f9
Full Text :
https://doi.org/10.1016/j.envpol.2023.121376