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61,005 resultsShowing papers similar to Global hotspots and trends in interactions of microplastics and heavy metals: a bibliometric analysis and literature review
ClearThe Unseen Threat of the Synergistic Effects of Microplastics and Heavy Metals in Aquatic Environments: A Critical Review
This review examines how microplastics and heavy metals interact in water environments, finding that microplastics can attract and concentrate toxic metals on their surfaces through various chemical forces. This combination effect is a concern for human health because contaminated microplastics carrying heavy metals can be consumed through seafood, delivering a double dose of pollutants.
Bibliometric and visual analysis of heavy metal health risk assessment: development, hotspots and trends
Researchers conducted a bibliometric analysis of heavy metal health risk assessment literature from 2000 to 2022, identifying development trends and research hotspots. The study reveals growing global attention to environmental heavy metal contamination, which often co-occurs with microplastic pollution in soil and water systems.
Interaction of microplastics with heavy metals in soil: Mechanisms, influencing factors and biological effects
This review summarizes how microplastics and heavy metals interact in soil, where microplastics can absorb and carry toxic metals through the food chain and into the human body. Aging and weathering of microplastics changes their surface properties, making them better at picking up heavy metals, which raises concerns about combined exposure through contaminated crops and water.
Microplastic-mediated environmental behavior of metal contaminants: mechanism and implication
This review examines how microplastics interact with heavy metals across water, soil, and air environments, acting as carriers that concentrate and transport toxic metals. Researchers found that microplastics can increase the bioavailability and toxicity of metal contaminants to living organisms. The study highlights major gaps in current analytical methods and calls for better tools to understand these complex pollutant interactions.
A critical review on the interactions of microplastics with heavy metals: Mechanism and their combined effect on organisms and humans
This review examines how microplastics interact with heavy metals in the environment and what their combined effects mean for organisms and human health. Microplastics absorb heavy metals from surrounding water and soil, and when ingested, the acidic conditions in the gut can cause those metals to be released inside the body. The combination of microplastics and heavy metals may be more toxic than either pollutant alone, creating a compounded health risk.
Microplastic and Heavy Metal Toxicity: a Bibliometric Analysis on Marine Environment
This bibliometric study analyzed 147 Scopus publications on the combined marine toxicity of microplastics and heavy metals, mapping research trends using VOSviewer. The analysis found rapid growth in the field since 2015, with co-contamination studies and metal adsorption to plastic surfaces emerging as the most active research clusters.
A Bibliometric Analysis of Toxicological Impacts of Microplastics in the Environment.
This bibliometric analysis of microplastic toxicology research found exponential growth in gut health studies since 2016, highlighting rising concern over how microplastics — especially in combination with heavy metals — cause immunotoxicity, biofilm formation, and accumulation in human tissues.
Co-occurrence and Interaction of Microplastics with Heavy Metals
This review examines the co-occurrence of microplastics and heavy metals in aquatic and terrestrial ecosystems, synthesizing evidence on how MPs adsorb metals, alter their bioavailability, and facilitate their transfer up food chains, compounding toxicological risks beyond either pollutant alone.
Microplastics and potentially toxic elements: A review of interactions, fate and bioavailability in the environment
This review summarizes how microplastics interact with toxic metals in the environment, finding that microplastics absorb and transport metals through soil and water via processes like electrostatic attraction and surface bonding. When organisms consume microplastics carrying toxic metals, they can experience greater harm than from either pollutant alone. This combined threat is relevant to human health because contaminated microplastics in the food chain could deliver concentrated doses of toxic metals to people through food and water.
Advances in Studies on Heavy Metals in Urban Soil: A Bibliometric Analysis
This bibliometric analysis maps two decades of research on heavy metal contamination in urban soils, identifying key trends, leading researchers, and priority topics. The field has grown significantly, with focus areas including pollution source identification, health risk assessment, and the use of environmental magnetism techniques. While centered on heavy metals rather than microplastics, the research is relevant because microplastics in urban soil often carry and concentrate heavy metals, creating combined pollution that threatens human health.
Influence of Microplastics on the Mobility, Bioavailability, and Toxicity of Heavy Metals: A Review
This review examines how microplastics interact with heavy metals in the environment, potentially influencing the metals' mobility, bioavailability, and toxicity to living organisms. Researchers found that microplastics can adsorb heavy metals and transport them to new locations, but the interactions depend on the type of plastic, metal, and environmental conditions. The study highlights that microplastics acting as carriers for toxic metals represents an underappreciated environmental and health risk.
Interaction of Microplastics and Heavy Metals on Aquatic Organisms : A Review
This systematic review examines how microplastics interact with heavy metals in waterways, finding that plastic particles absorb toxic metals and then release them inside organisms that ingest them. This combination increases the toxicity of both pollutants, leading to DNA damage, tissue changes, and reproductive problems in aquatic life, with potential consequences for human health through the food chain.
Interactions Between Microplastics and Heavy Metals in Aquatic Environments: A Review
This review examines how microplastics interact with heavy metals in water, with a particular focus on the role that microorganisms play in driving these interactions. Bacteria that colonize microplastic surfaces can change how metals bind to and release from the particles, potentially increasing their toxicity. The combined threat of microplastics and heavy metals to aquatic ecosystems and human health through seafood consumption is a growing concern that needs more research.
Co-exposure of microplastics and heavy metals in the marine environment and remediation techniques: a comprehensive review
This review examines how microplastics and heavy metals interact when they co-exist in the marine environment, with microplastics acting as carriers that concentrate metals on their surfaces. Researchers describe the mechanisms behind this interaction, including surface complexation, hydrogen bonding, and electrostatic forces. The study also surveys current remediation techniques aimed at removing both microplastics and heavy metal-laden microplastics from marine ecosystems.
Global research hotspots and trends on microplastics: a bibliometric analysis
A bibliometric analysis of microplastics publications from 1990 to 2022 found a 19-fold increase in publications and 35-fold increase in citations since 2015, with research clustering around distribution, toxicity, analytical methods, and adsorption of co-pollutants.
Microplastics and human health: A scientometric analysis
Researchers conducted a scientometric analysis of the scientific literature on microplastics and human health, mapping research trends and publication patterns. The study reveals a rapidly growing body of evidence exploring how ubiquitous microplastic contamination may affect human health, while identifying gaps in current research that need further investigation.
The evolving interface of aged microplastics and heavy metals: implications for environmental fate and toxicity
This review examined how microplastics interact with heavy metals in the environment, focusing on how plastics serve as carriers that increase metal mobility and bioavailability. Researchers found that factors like polymer aging, biofilm formation, and water chemistry significantly affect how efficiently microplastics absorb metals, and that the combined exposure creates compounded toxicity including oxidative stress and organ damage in organisms. The findings highlight the need for more research on the long-term and multigenerational effects of these combined pollutants.
Synergistic Impacts of Microplastics and Heavy Metals in Aquatic Environments and Strategies for Mitigation
This review examines the combined pollution of aquatic habitats by heavy metals and microplastics, covering their widespread distribution from polar regions to deep-sea sediments and the ecological risks of their interaction. The authors discuss adsorption of heavy metals onto microplastic surfaces, combined toxicity to aquatic organisms, and mitigation strategies for managing this dual contamination in water bodies.
Trends, challenges, and research pathways in emerging contaminants: a comprehensive bibliometric analysis
This large-scale bibliometric analysis reviewed over 62,000 studies on emerging contaminants published between 2000 and 2024, finding that microplastics are among the fastest-growing areas of environmental health research. The analysis highlights that understanding how microplastics interact with other pollutants like pharmaceuticals and endocrine disruptors is a critical frontier for protecting human health.
Microplastic-Toxic Chemical Interaction: A Review Study on Quantified Levels, Mechanism and Implication
This review summarizes quantified levels of heavy metals and hydrophobic organic contaminants sorbed onto microplastics in environmental media, examining adsorption and desorption mechanisms and discussing health implications of ingested microplastics acting as vectors for toxic chemical transport.
Interactions of microplastics with heavy metals in the aquatic environment: Mechanisms and mitigation
This review synthesized mechanisms of heavy metal adsorption onto microplastics in aquatic environments and evaluated strategies for removing both contaminants simultaneously. The authors found that temperature, salinity, and plastic surface aging govern metal binding, and identified hybrid adsorbent materials as the most promising approach for co-removal of metals and microplastics from water.
Review on the relationship between microplastics and heavy metals in freshwater near mining areas
This review synthesized knowledge on the interaction between microplastics and heavy metals in freshwater environments, covering adsorption mechanisms, combined toxicity, and the role of microplastics as metal vectors. Co-contamination was found to amplify ecological risks beyond what either stressor causes alone.
How aging microplastics influence heavy metal environmental fate and bioavailability: A systematic review
This systematic review found that environmental aging (UV, weathering) degrades microplastics into smaller particles with higher surface reactivity, increasing their capacity to adsorb heavy metals. These aged microplastic-heavy metal complexes bioaccumulate through the food chain, posing greater ecological and human health risks than either pollutant alone.
Interactions between microplastics (MPs) and trace/toxic metals in marine environments: implications and insights—a comprehensive review
This review examines how microplastics interact with trace and toxic metals in ocean environments, finding that plastic particles can adsorb metals onto their surfaces and alter how those metals move through marine ecosystems. These interactions can increase metal toxicity, reduce the availability of essential nutrients for marine life, and disrupt ocean food chains in ways that may ultimately affect seafood safety for humans.