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61,005 resultsShowing papers similar to Impact of microplastics on plant biogenic volatile organic compounds emission: A preliminary study
ClearTranscriptomic and metabolomic changes in lettuce triggered by microplastics-stress
Researchers grew lettuce in water containing polystyrene microplastics and found that the particles accumulated in root tips and leaf veins, causing water loss stress and changes in gene expression. The plants responded by activating stress defense systems and altering their metabolism, including increased production of protective compounds in root secretions. This study provides molecular-level evidence that microplastics can stress food crops and change their biology, raising questions about the safety and nutritional quality of vegetables grown in contaminated environments.
Polyethylene microplastic modulates lettuce root exudates and induces oxidative damage under prolonged hydroponic exposure
Researchers grew lettuce in water containing polyethylene microplastics for 28 days and found that the plastics changed the chemical signals the roots released and caused oxidative damage in the leaves. While the plants looked mostly normal on the outside, the microplastics altered the root chemistry in ways that could affect nutrient uptake and plant defense. This is relevant to human health because lettuce is widely consumed and may be grown in microplastic-contaminated water or soil.
The short-term effect of microplastics in lettuce involves size- and dose-dependent coordinate shaping of root metabolome, exudation profile and rhizomicrobiome
Researchers exposed lettuce plants to polyethylene plastic particles of four different sizes and concentrations, finding that the plastics altered root chemistry, changed what the roots released into the soil, and shifted the bacteria living around them. The effects depended strongly on particle size, with smaller particles causing different metabolic changes than larger ones. This study shows that microplastics in farm soil can change the biology of food crops from the roots up, potentially affecting both crop health and nutritional quality.
Determination of extractable pollutants from microplastics to vegetables: Accumulation and incorporation into the food chain
Researchers developed a method to detect plastic-related chemical compounds that leach into vegetables, finding that root vegetables contained higher levels of these contaminants than non-root varieties. The study identified 16 quantifiable plastic-associated compounds in the samples, including potentially harmful substances like styrene and phthalates. The findings raise concerns about how microplastics in soil may introduce chemical pollutants into the food chain through crop uptake.
Metabolic response of lettuce (Lactuca sativa L.) to polystyrene nanoplastics and microplastics after foliar exposure
Researchers exposed lettuce plants to polystyrene nanoplastics and microplastics through their leaves and found that the particles altered the plant's metabolism differently depending on particle size. This foliar exposure pathway means that microplastics and nanoplastics settling on leafy vegetables from the air can change the plant's internal chemistry. Since lettuce is widely consumed raw, these metabolic changes raise questions about how microplastic-contaminated produce might affect nutritional quality and human health.
Type-dependent effects of microplastics on tomato (Lycopersicon esculentum L.): Focus on root exudates and metabolic reprogramming
Researchers grew tomato plants in the presence of three different types of microplastics and found that each type produced distinct effects on plant physiology, root secretions, and metabolic processes. Polystyrene had the strongest negative impact, significantly altering root exudate composition and triggering metabolic reprogramming in the plants. The study demonstrates that the type of plastic matters when assessing how microplastic pollution affects crop growth and soil chemistry.
Effects of polystyrene, polyethylene, and polypropylene microplastics on the soil-rhizosphere-plant system: Phytotoxicity, enzyme activity, and microbial community
Researchers tested how three common types of microplastics (polystyrene, polyethylene, and polypropylene) affect lettuce growth and soil health. All three types inhibited plant growth, disrupted antioxidant systems in the leaves, and altered the microbial communities in the soil around roots, with polystyrene and polypropylene causing the most disturbance.
Environmental levels of microplastics disrupt growth and stress pathways in edible crops via species-specific mechanisms
Researchers studied how environmentally realistic levels of microplastics affect the growth and stress responses of edible crops. The study found that microplastics disrupt plant growth and stress pathways through mechanisms that vary by crop species. These findings highlight the importance of understanding how different plants interact with microplastic particles when assessing risks to agricultural food production.
Transcriptomic and physiological effects of polyethylene microplastics on Zea mays seedlings and their role as a vector for organic pollutants
Researchers found that polyethylene microplastics cause transcriptomic and physiological changes in corn seedlings, altering gene expression related to stress responses and growth, while also serving as vectors that increase the bioavailability of organic pollutants to plant roots.
Influence of polyethylene microplastics on Brassica rapa: Toxicity mechanism investigation
Researchers exposed the fast-growing plant Brassica rapa (related to turnip and cabbage) to polyethylene microplastics that had been degraded by sunlight, finding that the plastics stunted plant growth by up to 51% and triggered cellular stress responses. Genetic analysis revealed the microplastics disrupted the plant's immune and growth pathways, providing insight into how plastic pollution in agricultural soil could affect food crops.
Uptake and accumulation of microplastics in an edible plant
Researchers demonstrated for the first time that edible plants can take up and accumulate microplastics from soil. Using fluorescently labeled polystyrene beads, they showed that 0.2-micrometer particles entered lettuce roots through small cracks at lateral root emergence sites, traveled through the vascular system, and accumulated in the leaves. The findings raise concerns about a previously unrecognized pathway for human microplastic exposure through the consumption of vegetables grown in contaminated soil.
Uptake of microplastics and impacts on plant traits of savoy cabbage
Researchers found that savoy cabbage plants can absorb polystyrene microplastic particles as small as 0.5 micrometers directly into their cells. Different types and sizes of plastic particles affected plant growth and leaf chemistry in distinct ways, including changes to certain amino acid and defense compound levels. This is concerning because it demonstrates a direct pathway for microplastics to enter the human diet through vegetables.
Leaf absorption contributes to accumulation of microplastics in plants
Researchers found that plant leaves can absorb tiny plastic particles directly from the air, not just through the roots. Leafy vegetables grown outdoors in polluted areas contained measurable amounts of common plastics like PET and polystyrene. This means airborne microplastics may be entering our food supply through the plants we eat.
Effects of polystyrene microplastics on the growth and metabolism of highland barley seedlings based on LC-MS
Researchers exposed highland barley seedlings to different concentrations of polystyrene microplastics and found that low to medium levels actually increased plant growth, while high levels significantly reduced it. The microplastics triggered oxidative stress and disrupted key metabolic pathways involved in flavonoid production, energy metabolism, and fatty acid production. These changes to crop metabolism could affect the nutritional quality and safety of food crops grown in microplastic-contaminated soil.
Variability in microplastic abundance, bisphenol A contamination, antioxidant properties, and health risks associated with vegetable consumption
Researchers examined variability in microplastic abundance and bisphenol A contamination alongside antioxidant protein responses in marine organisms, finding that combined chemical exposure induced stronger oxidative stress responses than MPs or BPA alone.
Transport Dynamics and Physiological Responses of Polystyrene Nanoplastics in Pakchoi: Implications for Food Safety and Environmental Health
Researchers tracked fluorescently labeled nanoplastics as they traveled through pakchoi (a leafy green vegetable), entering through the roots, moving up through the plant's water-transport system, and accumulating in the leaves. The nanoplastics caused oxidative damage and disrupted plant hormones, demonstrating a clear pathway by which plastic pollution in soil could enter the human food supply through everyday vegetables.
Effects of polyethylene microplastic on the phytotoxicity of di-n-butyl phthalate in lettuce (Lactuca sativa L. var. ramosa Hort)
Researchers investigated how polyethylene microplastics interact with the chemical pollutant di-n-butyl phthalate in lettuce and found that microplastics altered the plant's response to the toxin. The combination reduced photosynthesis, lowered chlorophyll content, and disrupted the plant's antioxidant defenses. The study highlights that microplastics in soil can change how plants respond to other contaminants, potentially compounding environmental harm.
Micro plastic driving changes in the soil microbes and lettuce growth under the influence of heavy metals contaminated soil
Researchers studied how microplastics interact with heavy metals in contaminated soil and their combined effects on lettuce growth and soil bacteria. Different types of microplastics altered soil chemistry and changed which microbes thrived, sometimes making heavy metals more available to plants. The study suggests that microplastic-contaminated agricultural soil could affect both the safety and nutritional quality of leafy vegetables that people eat.
The effects of Micro/Nano-plastics exposure on plants and their toxic mechanisms: A review from multi-omics perspectives.
A multi-omics review of micro/nanoplastic effects on plants found that plastic exposure disrupts gene expression, protein function, and metabolic pathways across multiple plant systems, with potential consequences for crop yield and agricultural food safety.
Microplastic pollution in agriculture: How exposure pathway (Seed, Leaf, Root) dictates phytotoxicity in lettuce (Lactuca sativa L.)
This study compared the phytotoxicity of polyethylene microplastics applied to lettuce via seed, leaf, and root exposure pathways, finding that root exposure caused the greatest growth inhibition and oxidative stress. The route of MP exposure significantly influenced the type and severity of toxic effects on crops.
Unraveling consequences of the co-exposure of polyethylene microplastics and acid rain on plant-microbe-soil system
Researchers found that co-exposure to polyethylene microplastics and acid rain produced interactive effects on the soil-lettuce system, with high microplastic concentrations combined with acid rain increasing soil CO2 emissions and altering microbial community structure.
Effect of microplastics on dry matter content in Lactuca sativa L.
This study tested the effects of microplastic particles on dry matter content in lettuce plants, finding that microplastic exposure affected plant biomass production. As agricultural soils accumulate microplastics, their effects on crop yield and nutritional quality become important food safety concerns.
Effects of naturally aged microplastics on arsenic and cadmium accumulation in lettuce: Insights into rhizosphere microecology
Researchers studied how naturally aged microplastics in soil affect the uptake of arsenic and cadmium by lettuce. At low concentrations, microplastics actually reduced heavy metal absorption and helped plant growth, but at higher concentrations they increased the amount of toxic metals taken up by the lettuce. This means microplastic-contaminated farmland could lead to higher levels of heavy metals in salad greens and other vegetables that people eat.
Tracking Microplastics and Their Associated Chemical Additives in Plant Tissues: A Pyrolysis GC-MS Approach to Identification, Quantification, and Translocation Mechanism
Researchers developed an acid digestion and pyrolysis gas chromatography method to detect and quantify polystyrene microplastics — and the chemical additives they carry — inside basil plants grown in contaminated soil. They confirmed that microplastics taken up by plant roots translocate into stems and leaves that humans eat, and identified several potentially harmful chemical additives associated with the particles. This matters because it establishes a direct contamination pathway from plastic-polluted soil into food crops.