Meta Analysis
?
AI-assigned paper type based on the abstract. Classification may not be perfect — flag errors using the feedback button.
Tier 1
?
Systematic review or meta-analysis. Synthesizes findings across many studies. Strongest evidence.
Sign in to save
Is microplastic an oxidative stressor? Evidence from a meta-analysis on bivalves
Journal of Hazardous Materials2021
199 citations
?
Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count.
Score: 70
?
0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Wei Huang,
Menghong Hu,
Wei Huang,
Wei Huang,
Wei Huang,
Zhuoqing Li,
Elvis Genbo Xu,
Elvis Genbo Xu,
Youji Wang
Wei Huang,
Elvis Genbo Xu,
Youji Wang
Menghong Hu,
Menghong Hu,
Menghong Hu,
Menghong Hu,
Youji Wang
James Kar‐Hei Fang,
Youji Wang
Youji Wang
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
James Kar‐Hei Fang,
Elvis Genbo Xu,
James Kar‐Hei Fang,
Elvis Genbo Xu,
Elvis Genbo Xu,
Xueqing Chang,
Xueqing Chang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Elvis Genbo Xu,
Wei Huang,
Elvis Genbo Xu,
Menghong Hu,
Menghong Hu,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
Menghong Hu,
Menghong Hu,
Youji Wang
Elvis Genbo Xu,
James Kar‐Hei Fang,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Wei Huang,
Elvis Genbo Xu,
Wei Huang,
Menghong Hu,
Menghong Hu,
Wei Huang,
Youji Wang
James Kar‐Hei Fang,
Youji Wang
Youji Wang
Zhuoqing Li,
Inna M. Sokolova,
Xueqing Chang,
Xueqing Chang,
James Kar‐Hei Fang,
Menghong Hu,
Xueqing Chang,
Menghong Hu,
Wei Huang,
Wei Huang,
Youji Wang
Wei Huang,
Wei Huang,
Wei Huang,
Elvis Genbo Xu,
James Kar‐Hei Fang,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
Youji Wang
Youji Wang
Youji Wang
Youji Wang
Menghong Hu,
Menghong Hu,
Menghong Hu,
Menghong Hu,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Wei Huang,
Xueqing Chang,
Inna M. Sokolova,
Inna M. Sokolova,
Inna M. Sokolova,
Inna M. Sokolova,
Inna M. Sokolova,
James Kar‐Hei Fang,
Menghong Hu,
Elvis Genbo Xu,
Wei Huang,
Elvis Genbo Xu,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
Menghong Hu,
James Kar‐Hei Fang,
Inna M. Sokolova,
Wei Huang,
Menghong Hu,
Menghong Hu,
Menghong Hu,
Menghong Hu,
Elvis Genbo Xu,
James Kar‐Hei Fang,
Wei Huang,
Menghong Hu,
Elvis Genbo Xu,
Menghong Hu,
Menghong Hu,
Inna M. Sokolova,
James Kar‐Hei Fang,
Youji Wang
Youji Wang
Youji Wang
Youji Wang
Wei Huang,
James Kar‐Hei Fang,
Youji Wang
Youji Wang
Wei Huang,
Elvis Genbo Xu,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
Wei Huang,
Wei Huang,
Inna M. Sokolova,
Youji Wang
Wei Huang,
Wei Huang,
Inna M. Sokolova,
Wei Huang,
Youji Wang
Wei Huang,
Wei Huang,
Wei Huang,
Youji Wang
James Kar‐Hei Fang,
Wei Huang,
Wei Huang,
Youji Wang
Wei Huang,
Youji Wang
Youji Wang
Youji Wang
Wei Huang,
Youji Wang
Elvis Genbo Xu,
Youji Wang
Youji Wang
Elvis Genbo Xu,
James Kar‐Hei Fang,
Elvis Genbo Xu,
Menghong Hu,
Wei Huang,
Youji Wang
James Kar‐Hei Fang,
Wei Huang,
Wei Huang,
Menghong Hu,
Menghong Hu,
James Kar‐Hei Fang,
Menghong Hu,
Youji Wang
Youji Wang
James Kar‐Hei Fang,
Menghong Hu,
Youji Wang
Elvis Genbo Xu,
James Kar‐Hei Fang,
Youji Wang
Youji Wang
Youji Wang
Elvis Genbo Xu,
Elvis Genbo Xu,
Elvis Genbo Xu,
James Kar‐Hei Fang,
Youji Wang
Youji Wang
Wei Huang,
Elvis Genbo Xu,
Wei Huang,
Youji Wang
Elvis Genbo Xu,
Youji Wang
Elvis Genbo Xu,
Youji Wang
Youji Wang
Youji Wang
Elvis Genbo Xu,
Elvis Genbo Xu,
Menghong Hu,
Elvis Genbo Xu,
Wei Huang,
Menghong Hu,
Menghong Hu,
Wei Huang,
Youji Wang
Youji Wang
Youji Wang
Inna M. Sokolova,
Youji Wang
Youji Wang
James Kar‐Hei Fang,
James Kar‐Hei Fang,
Youji Wang
Youji Wang
Menghong Hu,
Menghong Hu,
Menghong Hu,
James Kar‐Hei Fang,
Menghong Hu,
Menghong Hu,
Menghong Hu,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
Elvis Genbo Xu,
Inna M. Sokolova,
Elvis Genbo Xu,
Wei Huang,
Wei Huang,
Wei Huang,
Youji Wang
Youji Wang
Youji Wang
Wei Huang,
Elvis Genbo Xu,
Wei Huang,
Youji Wang
James Kar‐Hei Fang,
Wei Huang,
Menghong Hu,
Menghong Hu,
Youji Wang
Menghong Hu,
Wei Huang,
Youji Wang
Wei Huang,
Menghong Hu,
Menghong Hu,
Youji Wang
James Kar‐Hei Fang,
Menghong Hu,
Menghong Hu,
Youji Wang
Menghong Hu,
Menghong Hu,
Youji Wang
Wei Huang,
Menghong Hu,
Wei Huang,
Wei Huang,
James Kar‐Hei Fang,
James Kar‐Hei Fang,
Menghong Hu,
Menghong Hu,
Menghong Hu,
Menghong Hu,
Menghong Hu,
Wei Huang,
Youji Wang
Youji Wang
Youji Wang
Youji Wang
Youji Wang
Youji Wang
Youji Wang
Elvis Genbo Xu,
Elvis Genbo Xu,
Wei Huang,
Youji Wang
Youji Wang
Elvis Genbo Xu,
Wei Huang,
Youji Wang
Youji Wang
Elvis Genbo Xu,
Menghong Hu,
Youji Wang
Youji Wang
Youji Wang
Youji Wang
Youji Wang
Summary
Microplastics induce time-dependent oxidative stress in bivalves, with antioxidant enzymes (GPx, GST, SOD) increasing during short-term exposure but declining after long-term exposure, while glutathione levels and catalase activity remained elevated throughout and may serve as reliable biomarkers of sublethal microplastic effects.
Study Type
Review
Microplastic pollution is a major threat to the marine environment attracting attention from scientific and public communities. Although we have sufficient evidence that microplastic is ubiquitous in all ecosystems, the question of the harmfulness of microplastic exposure is still under debate. Filter feeders like bivalves are commonly exposed to microplastics in water and sediments and thus can serve as excellent biological indicators for microplastic pollution. A relatively rich toxicological literature has been focusing on microplastic effects on bivalves but we have yet to reach an agreement on the toxic effects and mechanisms of microplastics. Here, we conducted a meta-analysis and bibliometrics analysis of the microplastic studies in bivalves. The bibliometric analysis (used to evaluate the general research trends) showed that the investigation of microplastic distribution in the marine environment and the molecular mechanisms of microplastic toxicity are the two major hot spots of research. Based on analyses of ecologically and environmentally relevant microplastics concentrations, particle sizes and polymer types, we discuss the physiological effects of microplastics on bivalves, and the severity and direction of the effects at the cellular, tissue, organ and organismal levels. The meta-analysis results show that microplastics can induce time-dependent oxidative stress in bivalves. Generally, the activities of antioxidant enzymes, such as glutathione peroxidase (GPx), glutathione-S-transferase (GST) and superoxide dismutase (SOD) increased during short-term exposure but declined after long-term exposure to microplastics. Non-linear response of GPx, GST and SOD enzymes to MP exposure over time indicate that these enzymes are not good biomarkers of MPs effects in marine bivalves. The tissue glutathione levels and catalase (CAT activity) showed an increase during both short- and long term MP exposures and thus can be used as oxidative stress biomarkers of sublethal MPs effects in marine bivalves.