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Papers
20 resultsShowing papers similar to The wheel of time: The environmental dance of aged micro- and nanoplastics and their biological resonance
ClearWeathering pathways and protocols for environmentally relevant microplastics and nanoplastics: What are we missing?
This review highlights a major gap in microplastics research: most lab studies use brand-new, pristine plastic particles, but microplastics in the real world have been weathered by sunlight, water, and biological activity. Weathered microplastics behave differently, releasing more chemicals and interacting with organisms in ways that fresh plastics do not. Only about 10% of published studies have used aged microplastics, meaning current risk assessments may not reflect the true dangers of environmental microplastic exposure.
Nanoplastics in aquatic environments: The hidden impact of aging on fate and toxicity
This review highlights that most toxicity studies on nanoplastics use brand-new pristine particles, but real-world nanoplastics are aged by sunlight and chemical exposure, which fundamentally changes their surface properties and toxicity. Aged nanoplastics may be more harmful than pristine ones because they interact differently with biological systems, meaning current safety assessments likely underestimate the true risks.
A review on enriched microplastics in environment: From the perspective of their aging impact and associate risk
This review explores what happens to microplastics as they age in the environment over long periods. Researchers found that natural weathering changes the physical and chemical properties of microplastics in ways that may increase their ability to harbor harmful microorganisms and interact with other pollutants, suggesting that aging may actually make microplastic pollution more hazardous over time rather than less.
Insights into the Photoaging Behavior of Microplastics: Environmental Fate and Ecological Risk
This review examines how sunlight ages microplastics in the environment, breaking them into smaller pieces and changing their surface chemistry in ways that make them more toxic and more likely to carry other pollutants. Sun-aged microplastics release dissolved organic matter that can harm aquatic life, and their roughened surfaces attract more bacteria and chemical contaminants. Since most microplastics in nature have been exposed to sunlight, their real-world health risks may be higher than studies using fresh lab plastics suggest.
Mechanistic insights into non-negligible toxicity evolution of microplastics under different aging processes
This review examines how different environmental aging processes, such as UV exposure, mechanical wear, and chemical weathering, change the physical and chemical properties of microplastics and alter their toxicity. Researchers found that aged microplastics and the chemicals they leach tend to be more harmful to organisms than fresh particles, causing growth inhibition and genetic damage. The findings suggest that the environmental risks of microplastics may increase significantly as they degrade over time.
Mechanism and characterization of microplastic aging process: A review
This review explains how microplastics age and break down in the environment through sunlight, heat, and chemical reactions, and why this aging process matters. As microplastics weather, their surfaces change in ways that make them better at absorbing toxic pollutants and more harmful to living organisms. Understanding these aging processes is important because the microplastics people encounter in food and water have typically been weathered, meaning they may be more dangerous than the fresh plastics used in most lab studies.
A comprehensive review of microplastic aging: Laboratory simulations, physicochemical properties, adsorption mechanisms, and environmental impacts
This review examines how microplastics change as they age in the environment through exposure to sunlight, water, and chemicals, becoming rougher and more chemically reactive over time. Aged microplastics absorb more pollutants than fresh ones and release harmful additives and free radicals, meaning the microplastics people encounter in the real world may be more dangerous than the pristine particles typically used in lab studies.
Aging Process of Microplastics in the Environment
This review examines how natural environmental processes — UV radiation, physical abrasion, chemical reactions, and biodegradation — alter the surface, shape, and chemistry of microplastics over time, and how these changes affect their ability to absorb and transport other pollutants. Understanding microplastic aging is critical because weathered particles behave differently than fresh plastic, often becoming more hazardous as pollutant carriers in ecosystems.
Distribution and Biological Response of Nanoplastics in Constructed Wetland Microcosms: Mechanistic Insights into the Role of Photoaging
This study looked at how sunlight aging changes the behavior of nanoplastics in wetland ecosystems. Researchers found that sun-aged nanoplastics accumulated differently in plants, water, and soil compared to fresh ones, and caused stronger biological responses in wetland organisms, suggesting that weathered nanoplastics in the environment may be more harmful than previously thought.
Recent advances on microplastic aging: Identification, mechanism, influence factors, and additives release
This review found that environmental aging transforms microplastic surface properties through abrasion, chemical oxidation, UV irradiation, and biodegradation, altering their environmental behavior and ecological risk. Aging also triggers the release of toxic plastic additives, but significant gaps remain between laboratory aging simulations and real-world conditions.
The fate, impacts and potential risks of photoaging process of the microplastics in the aqueous environment
This review examines how ultraviolet light from sunlight causes microplastics in water to age and change their physical and chemical properties, including surface texture, chemical structure, and water-repelling ability. Researchers found that photoaged microplastics become better at carrying other pollutants and may pose greater environmental risks than fresh plastics. The study highlights that aged microplastics can also increase biological toxicity and human exposure risks compared to their original form.
The environmental effects of microplastics and microplastic derived dissolved organic matter in aquatic environments: A review
This review examines how microplastics interact with other pollutants in water and how aging from sunlight and weathering changes their behavior. As microplastics break down, they release dissolved organic matter and develop surface changes that increase their ability to carry harmful chemicals like pesticides and pharmaceuticals. The findings suggest that weathered microplastics in real-world environments may be more dangerous than fresh plastics used in most lab studies.
Microplastic aging processes: Environmental relevance and analytical implications
Researchers reviewed how microplastics change physically and chemically over time in the environment — a process called 'aging' — and found that standard lab methods for detecting microplastics were mostly developed using fresh, unaged plastics, making it harder to accurately measure real-world contamination. Improved analytical methods that account for aged microplastics are needed for reliable environmental assessment.
From Pristine to Laboratory-weathered Micro- and Nanoplastics: Interaction with Environmental Contaminants and Biological Effects
This review contrasts pristine and laboratory-weathered micro- and nanoplastics in terms of surface chemistry, adsorption of co-contaminants, and biological effects, arguing that weathered particles better represent real-world exposures and often exhibit different or greater toxicity.
[Research Progress on Plastic Aging Processes and Their Environmental Hazards].
This review examines the full dynamic aging process of plastics—from large pieces through microplastics and nanoplastics—including the mechanisms by which additives and soluble compounds are released during degradation. It concludes that while aging mechanisms are similar across plastic sizes, smaller particles carry greater potential for harm due to higher surface area and bioavailability.
Characteristics and behaviors of microplastics undergoing photoaging and Advanced Oxidation Processes (AOPs) initiated aging
This review examines how microplastics change as they age in the environment through sunlight exposure and chemical processes. Aging alters the surface properties of microplastics, making them better at absorbing toxic chemicals and heavy metals from the surrounding environment. Since nearly all microplastics found in nature have undergone some degree of aging, understanding these changes is essential for accurately assessing how dangerous real-world microplastic pollution is to human health.
Innovative overview of the occurrence, aging characteristics, and ecological toxicity of microplastics in environmental media
This review summarizes existing research on where microplastics are found in the environment, how they age and break down, and their toxic effects on living organisms. The paper highlights that as microplastics weather in the environment through sunlight and chemical exposure, they become smaller and can carry other pollutants, potentially increasing their health risks. It also covers emerging strategies for detecting and removing microplastics.
Effects of microplastic aging on its detectability and physico-chemical properties in loess and sandy soil
This study compared fresh microplastics to aged particles collected from soil and found that weathering significantly changes their physical and chemical properties, including making them more mobile. Aged microplastics may behave very differently in the environment than the pristine particles typically used in laboratory studies.
Micro- and Nanoplastic Processes: Degradation, Fragmentation, Aggregation and the Need for Environmentally Relevant Reference Materials
This research review explains how tiny plastic particles break down and change when exposed to sunlight, water, and bacteria in the environment. These weathered plastic pieces behave very differently from fresh plastics—they can clump together and move through soil and water in new ways, potentially affecting where they end up in our food and water systems. Understanding how plastics age and change is crucial for predicting their long-term impacts on human health and the environment.
Aging of plastics in aquatic environments: Pathways, environmental behavior, ecological impacts, analyses and quantifications
This review examines how plastics age and degrade in aquatic environments through photo-oxidation, mechanical abrasion, and biodegradation. Researchers discuss the physicochemical changes that occur in aging plastics and the release of potentially harmful oxidation products during degradation. The study suggests that understanding these complex aging dynamics is essential for assessing the environmental and ecological risks posed by microplastics.