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61,005 resultsShowing papers similar to New Insights into the Mechanisms of Toxicity of Aging Microplastics
ClearAging of microplastics increases their adsorption affinity towards organic contaminants
Researchers found that microplastics that have been weathered by sunlight and environmental exposure absorb significantly more chemical pollutants than fresh microplastics, with up to a 4.7-fold increase in adsorption. Ultraviolet exposure changes the surface chemistry of the plastics, making them stickier for contaminants. This matters because most microplastics in nature are weathered, meaning they may be carrying more toxic chemicals into the food chain than laboratory studies using new plastics would suggest.
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.
Fragmentation of polypropylene into microplastics promoted by photo-aging; release of metals, toxicity and inhibition of biodegradability
This study showed that when polypropylene plastic ages in sunlight, it fragments into microplastics much faster and releases metal contaminants that were originally added during manufacturing. The resulting particles and chemical leachates were toxic to aquatic organisms and resistant to biodegradation, meaning aged plastics in the environment are more hazardous than fresh ones.
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.
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.
UVB-aged microplastics and cellular damage : An in vitro study
Researchers conducted in vitro experiments to assess whether UVB-aged microplastics cause greater cellular damage than unaged plastics, given that UV irradiation fragments and chemically alters plastic surfaces. The study found that UVB aging enhanced the capacity of microplastics to cause cellular toxicity.
Polyethylene, whose surface has been modified by UV irradiation, induces cytotoxicity: A comparison with microplastics found in beaches
Researchers showed that polyethylene microplastics degraded by UV light, mimicking what happens to plastics in the environment, were toxic to immune and skin cells in lab tests. Fresh, undegraded plastic particles did not cause the same harm, meaning weathered microplastics found in nature are likely more dangerous than the pristine plastics typically used in lab studies. This suggests that real-world human exposure to environmentally aged microplastics may carry greater health risks than current research indicates.
Non-Negligible Effects of UV Irradiation on Transformation and Environmental Risks of Microplastics in the Water Environment
This review examines how UV irradiation drives photoaging of microplastics in aquatic environments, altering their surface chemistry, mechanical properties, and adsorption capacity for co-pollutants, and thereby amplifying their ecotoxicological risks beyond those of virgin plastic particles.
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.
Aging mechanism of microplastics with UV irradiation and its effects on the adsorption of heavy metals
Researchers aged polystyrene microplastics using UV irradiation under three conditions (air, pure water, seawater) and found that aging changed surface chemistry and increased the microplastics' capacity to adsorb heavy metals, with seawater aging producing the most pronounced surface oxidation.
UVB-Aged Microplastics and Cellular Damage: An in Vitro Study
Researchers compared the cellular damage caused by UV-aged versus new microplastic particles using lab-grown human cells. They found that UV-aged microplastics caused significantly more DNA damage and oxidative stress than pristine particles, likely due to chemical changes on their surfaces during weathering. The findings suggest that environmentally weathered microplastics may pose greater health risks than freshly produced ones.
Unraveling the impacts of photolysis-induced aging microplastics on enhanced immunotoxicity and nephrotoxicity
Researchers compared the toxicity of pristine and sun-aged polyethylene and PET microplastics on kidney cells and immune cells and found that aged particles were up to 40 percent more toxic. The increased harm was attributed to environmentally persistent free radicals that form on plastic surfaces during UV exposure, which amplify oxidative stress inside cells. The study highlights that weathered microplastics in the real environment may pose greater health risks than the pristine particles typically used in laboratory studies.
Progress on the photo aging mechanism of microplastics and related impact factors in water environment
This review examined the photo-aging mechanisms of microplastics in aquatic environments, finding that solar UV radiation drives oxidation reactions that alter surface chemistry, fragment particles further, and enhance their capacity to adsorb and release co-occurring pollutants.
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.
Impact of aged and virgin polyethylene microplastics on multi end-points effects of freshwater fish tissues
Freshwater fish exposed to polyethylene microplastics for 15 days showed increased oxidative stress in both liver and muscle tissue, with aged, UV-weathered microplastics causing more damage than new ones. The weathering process changed the plastic surface in ways that made the particles more chemically reactive and potentially more harmful. This matters because microplastics in the environment are typically aged, meaning lab studies using only pristine particles may underestimate real-world toxicity.
Releasing characteristics of toxic chemicals from polystyrene microplastics in the aqueous environment during photoaging process
This study revealed that as polystyrene microplastics age under UV light, they release a growing number of toxic chemicals including organic compounds and heavy metals into surrounding water. The rate of chemical release increased dramatically with aging time, meaning that weathered microplastics in the environment are more chemically hazardous than fresh ones, with implications for water quality and human exposure.
UV-aging exacerbates the diversified toxicity of microplastics in the gut of gibel carp (Carassius auratus gibelio)
This study examined how UV aging of microplastics affects their toxicity in the gut of gibel carp, finding that aged MPs caused greater gut microbiome disruption and oxidative stress than virgin MPs. The results highlight that environmental weathering increases the ecological hazard of microplastics in freshwater aquaculture systems.
Photodegradation Controls of Potential Toxicity of Secondary Sunscreen-Derived Microplastics and Associated Leachates
Researchers studied how sunlight breaks down microplastics from sunscreen products and whether this makes them more or less toxic. They found that sunlight aging caused chemical changes on the plastic surfaces and released harmful compounds into the water, increasing toxicity to aquatic organisms. This is relevant because sunscreen microplastics are commonly washed into oceans and lakes, where sun exposure could make them more dangerous over time.
Contaminant release from aged microplastic
Researchers exposed recycled plastic granules of polyethylene, PVC, and polystyrene to simulated aging conditions including UV radiation and high temperatures. They found that aging significantly increased the rate at which chemical additives leached from the plastic particles into water, with UV exposure having the greatest effect. The study highlights that weathered microplastics in the environment may release harmful chemicals at much higher rates than fresh plastic materials.
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.
The wheel of time: The environmental dance of aged micro- and nanoplastics and their biological resonance
This review examines how micro- and nanoplastics change as they age in the environment through exposure to sunlight, water, and biological activity. Aged plastics behave differently than fresh ones: they accumulate faster in ecosystems, are more easily taken up by organisms, and can release trapped chemicals as they break down. The findings suggest that the real-world health and environmental risks of microplastics may be greater than lab studies using new, unweathered plastics indicate.
UV weathering alters toxicity and chemical composition of consumer plastic leachates
Researchers examined how UV weathering changes the toxicity and chemical makeup of leachates from eight types of consumer plastic products. They found that UV exposure increased cytotoxicity up to 13-fold, particularly for polyethylene leachates, and enhanced reactive toxicity by up to 82%. The increased toxicity was primarily linked to the release and transformation of organic chemicals rather than the microplastic particles themselves, highlighting UV weathering as a critical driver of plastic pollution hazards.
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.
Impact of Degradation of Polyethylene Particles on Their Cytotoxicity
Researchers found that degradation of polyethylene particles altered their cytotoxicity, with weathered and fragmented PE showing different toxic effects on cells compared to pristine particles, suggesting environmental aging changes microplastic health risks.