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61,005 resultsShowing papers similar to olYours iReview on microplastic-polymer composite interactions: Assessing contaminant adsorption, structural integrity, and environmental impacts
ClearReview on microplastic-polymer composite interactions: assessing contaminant adsorption, structural integrity, and environmental impacts
This review examined how microplastics interact with polymer composites and serve as carriers for heavy metals, organic pollutants, and pathogens. The study assessed how polymer type, surface properties, and environmental conditions influence contaminant adsorption and transport, highlighting the complex role of microplastics in pollutant cycling.
Interaction of chemical contaminants with microplastics: Principles and perspectives
This review examines how microplastics interact with chemical contaminants in the environment, acting as carriers that can transport pollutants through aquatic food webs. Researchers describe how polymer structure, weathering, and crystallinity influence a microplastic's ability to absorb and release environmental pollutants. The study notes that most research has relied on pristine laboratory plastics rather than field samples, creating a gap in our understanding of real-world contamination dynamics.
The impact of microplastic pollution on ecological environment: a review
This review examines the broad ecological impact of microplastic pollution, focusing on how the strong adsorption capacity of microplastic surfaces allows them to carry persistent organic pollutants through the environment. Researchers found that the combined effects of microplastics and adsorbed chemicals increase toxicity to organisms across different levels of the food chain. The study calls for more research into the long-term ecological consequences of microplastic pollution and its synergistic effects with other contaminants.
Microplastic properties and their interaction with hydrophobic organic contaminants: a review
This review examines the physical and chemical properties of microplastics that determine how they interact with hydrophobic organic contaminants in the environment. Researchers found that factors like polymer type, particle size, weathering, and surface chemistry all influence how strongly microplastics bind to co-occurring pollutants. The findings suggest that microplastics can serve as carriers for harmful chemicals, potentially increasing exposure risks for organisms that ingest them.
The chemical behaviors of microplastics in marine environment: A review
This review summarized interactions between microplastics and organic pollutants and metals in the marine environment, covering sorption behavior across polymer types, the role of degradation in altering sorption capacity, and global monitoring data on pollutant concentrations on marine plastics. The authors conclude that microplastic type, pollutant properties, and environmental conditions all strongly influence chemical accumulation on plastic surfaces.
Additives and polymer composition influence the interaction of microplastics with xenobiotics
This study examined how chemical additives and structural composition of microplastics affect how they absorb environmental contaminants. Polymer additives significantly influence which toxic chemicals stick to microplastic surfaces, affecting how contaminants move through ecosystems.
Interactions between microplastics and organic compounds in aquatic environments: A mini review
Researchers reviewed the mechanisms of interaction between microplastics and organic compounds in aquatic environments, examining factors related to the plastics themselves, the organic compounds, and environmental conditions. The study found that properties like crystallinity, surface area, and weathering state of microplastics all influence how they adsorb and transport organic pollutants, with implications for environmental and health risk assessments.
A critical review on the interaction of polymer particles and co-existing contaminants: Adsorption mechanism, exposure factors, effects on plankton species
This review critically examines how microplastics and nanoplastics interact with co-existing contaminants including organic pollutants, toxic metals, and nanoparticles. Researchers found that the combined toxicity depends on multiple factors including plastic size, polymer type, weathering, and the nature of the co-contaminant. The study reveals that mixture effects on plankton species vary widely, with some combinations producing synergistic harm and others showing antagonistic interactions.
Sources, Mechanisms, and Interactions of Microplastics with Abiotic and Biotic Factors in Aquatic Environment
This review examines the sources, mechanisms, and interactions of microplastics with abiotic and biotic components of aquatic environments, covering adsorption of co-contaminants, biofilm formation, biological uptake pathways, and trophic transfer through food webs.
Interactions of microplastics with contaminants in freshwater systems: a review of characteristics, bioaccessibility, and environmental factors affecting sorption
This review examined how microplastics act as vectors for environmental contaminants in freshwater systems, analyzing the characteristics, bioaccessibility, and environmental factors that influence pollutant sorption onto plastic particles and their potential transfer to organisms including humans.
Effect of microplastics on the environmental behavior of emerging contaminants in aquatic matrices
This study examines how microplastics affect the environmental behavior of emerging contaminants in aquatic systems. Microplastics can adsorb other pollutants and alter their bioavailability, potentially increasing or decreasing toxic effects depending on the chemicals and environmental conditions.
Polymeric Composites and Microplastics: Regulatory and Toxicological Perspectives
This review examines the regulatory and toxicological dimensions of polymeric composites and microplastics, covering how chemical additives such as plasticizers, stabilizers, and flame retardants interact with polymer matrices and how environmental degradation releases these substances into ecosystems. Researchers found significant knowledge gaps regarding the impact of composite materials on marine biota and food chains, calling for standardized holistic studies under simulated environmental and landfill conditions.
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.
Interaction of toxic chemicals with microplastics: A critical review
This critical review examined how toxic chemicals interact with microplastics in the environment, synthesizing evidence on adsorption, desorption, and the conditions under which microplastics either increase or decrease the bioavailability of co-occurring pollutants.
Microplastics, physical-chemical and biological principles of this environmental liability
This review covers the physical, chemical, and biological principles underlying microplastic behavior in the environment, including how particles fragment, sorb contaminants, and interact with organisms. The authors frame microplastics as a complex environmental stressor whose impacts depend on particle size, shape, polymer type, and the specific biological system exposed.
Interaction of Environmental Pollutants with Microplastics: A Critical Review of Sorption Factors, Bioaccumulation and Ecotoxicological Effects
This critical review examines how microplastics interact with and enhance the toxicity of co-occurring environmental pollutants including heavy metals, persistent organic compounds, and pharmaceuticals, synthesizing evidence on sorption mechanisms and combined ecotoxicological effects.
Interactions of microplastics with organic, inorganic and bio-pollutants and the ecotoxicological effects on terrestrial and aquatic organisms
This review systematically examines how microplastics interact with organic pollutants, heavy metals, and biological contaminants in the environment. Researchers found that microplastics can adsorb and transport these pollutants, creating complex combinations that may be more toxic to organisms than either pollutant alone. The study highlights the risks these interactions pose to both ecosystem health and human well-being.
Understanding Interface Exchanges for Assessing Environmental Sorption of Additives from Microplastics: Current Knowledge and Perspectives
This review examines how chemical additives move between microplastics and the surrounding environment, including water, soil, and living organisms. The study highlights the complexity of these interactions and emphasizes that understanding how microplastics absorb and release chemicals is essential for properly assessing their environmental and health risks.
Microplastics in the environment: Interactions with microbes and chemical contaminants
This review covers what is known about microplastic interactions with microbes and co-occurring chemical contaminants in the environment, examining how biofilms on microplastics alter pollutant transport and the ecological consequences for soil, water, and atmospheric systems.
Partitioning of chemical contaminants to microplastics: Sorption mechanisms, environmental distribution and effects on toxicity and bioaccumulation
This review critically examines how chemical contaminants like persistent organic pollutants and heavy metals sorb onto microplastic surfaces in the environment. Researchers found that while microplastics can concentrate pollutants at levels far above surrounding water, the actual contribution of microplastics to contaminant transfer into organisms may be less significant than direct exposure from water and food. The study calls for more realistic experimental designs to clarify the true risk.
Ecotoxic effects of microplastics and contaminated microplastics – Emerging evidence and perspective
This review examined the ecotoxic effects of microplastics alone and when contaminated with other environmental pollutants. Researchers analyzed how microplastics' small size, surface properties, and hydrophobicity contribute to their environmental persistence and tendency to bind other contaminants. The study suggests that contaminated microplastics may pose greater ecological risks than pristine particles due to combined toxic effects.
Microplastics and Nanoplastics in the Aquatic Environment: Contamination, Determination and Interaction with Other Contaminants
This review gathers information on microplastic and nanoplastic contamination in aquatic environments, examining their detection methods, environmental persistence, and interactions with other contaminants including their capacity to adsorb and release chemical compounds.
Weathering of microplastics and interaction with other coexisting constituents in terrestrial and aquatic environments
This review summarizes how microplastics weather and interact with other environmental constituents in both terrestrial and aquatic systems. Researchers found that weathering processes such as UV exposure and microbial activity alter the surface properties of microplastics, increasing their ability to adsorb heavy metals, organic pollutants, and pathogens. The study highlights that weathered microplastics may pose greater environmental risks than pristine particles due to their enhanced capacity to carry contaminants.
Prevention of Biofouling Due to Water Absorption of Natural Fiber Composites in the Aquatic Environment: A Critical Review
This review examines how natural fiber composites used in boats and marine structures absorb water and become damaged by marine organisms over time. While focused on engineering materials rather than health effects, the study is relevant to microplastic research because degrading composite materials in aquatic environments can release plastic particles and chemical additives into the water. Understanding how these materials break down helps identify an often-overlooked source of microplastic pollution in marine environments.