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20 resultsShowing papers similar to Size-dependent effects of polystyrene micro- and nanoplastics on the quality of rice grains and the metabolism mechanism
ClearMicroplastics affect rice (Oryza sativa L.) quality by interfering metabolite accumulation and energy expenditure pathways: A field study
Researchers conducted a field study examining how polystyrene microplastics affect rice grain quality at the molecular level using metabolomic and transcriptomic analysis. They found that microplastic exposure interfered with metabolite accumulation and energy pathways in the rice plants, ultimately reducing grain quality. The study provides real-world evidence that microplastic contamination in agricultural soils can directly compromise the nutritional quality of a major food crop.
Uptake and translocation of nano/microplastics by rice seedlings: Evidence from a hydroponic experiment
In a hydroponic experiment, researchers showed that both nano-sized (80 nm) and micro-sized (1 micrometer) polystyrene particles were absorbed by rice plant roots and transported up into stems and leaves. The particles traveled through the plant's vascular system and accumulated in cell walls and between cells. This finding is concerning because it demonstrates that microplastics in soil and water can enter food crops like rice and potentially reach people through their diet.
Response of rice (Oryza sativa L.) roots to nanoplastic treatment at seedling stage
Researchers exposed rice seedlings to polystyrene nanoplastics and found that the particles were taken up by the roots, aided by water-transporting proteins in the plant. The nanoplastics triggered oxidative stress, reduced root length, and disrupted carbon metabolism and hormone production in the seedlings. The study raises concerns that nanoplastic contamination in agricultural soils could affect crop growth and potentially enter the human food supply through rice consumption.
Fate of nano/microplastics and associated toxic pollutants in paddy ecosystems: Current knowledge and future perspectives
Researchers reviewed how micro- and nanoplastics enter rice paddies through irrigation, mulch films, and atmospheric deposition, then harm soil health and rice plant growth by disrupting nutrient cycles and increasing oxidative stress. Their findings are especially significant because rice feeds more than half the world's population, yet research on plastic contamination in paddy systems remains very limited.
Effects of microplastics on growth and metabolism of rice (Oryza sativa L.)
Researchers found that polystyrene and polyvinyl chloride microplastics inhibited rice growth and disrupted ionic homeostasis and antioxidant metabolism in a dose-dependent manner, with PVC microplastics causing more severe effects than polystyrene.
Polylactic acid microplastics have stronger positive effects on the qualitative traits of rice (Oryza sativa L.) than polyethylene microplastics: Evidence from a simulated field experiment
Researchers found that both polyethylene and biodegradable polylactic acid microplastics in soil affected the quality of rice grains by changing their mineral content, fatty acid profiles, and amino acid levels. Interestingly, PLA microplastics had some positive effects on grain yield and weight, while PE microplastics more significantly disrupted the nutritional composition. This study shows that microplastic contamination in farm soil can alter the nutritional quality of rice, a staple food for billions of people, even when the plants appear to grow well.
Investigating the Impact of Microplastics Type of Polyethylene, Polypropylene, and Polystyrene on Seed Germination and Early Growth of Rice Plants
Researchers investigated how three common types of microplastics, polyethylene, polypropylene, and polystyrene, affect rice seed germination and early seedling growth. They found that microplastic exposure altered root development and shoot growth, with the effects varying by polymer type. The study raises concerns about how microplastic-contaminated agricultural soils could affect staple crop establishment and food production.
Life-long impacts of nanoplastics to rice plant (Oryza sativa L.): Decreased grain yield with perturbed metallome and soil microbiome
Researchers studied how nano-sized PET plastic particles affect rice plants throughout their entire life cycle at concentrations found in real-world environments. They found that nanoplastic exposure reduced grain quality and yield, disrupted mineral nutrient balance, and significantly altered the soil microbial community. The study highlights a potential threat to global food security, since rice is a staple food for billions of people.
Polystyrene nanoplastics affect seed germination, cell biology and physiology of rice seedlings in-short term treatments: Evidence of their internalization and translocation
Researchers found that polystyrene nanoplastics were absorbed by rice roots and translocated to shoots, impairing seed germination, seedling growth, and cell division while disrupting reactive oxygen species homeostasis in short-term treatments.
Effect of Polystyrene Microplastics on Rice Seed Germination and Antioxidant Enzyme Activity
Researchers tested how different concentrations of polystyrene microplastics affect rice seed germination, root growth, and antioxidant enzyme activity. They found that at higher concentrations, the microplastics inhibited root growth and triggered oxidative stress responses in the seedlings. The study indicates that microplastic contamination in agricultural soils could interfere with early crop development, potentially affecting food production.
Polystyrene microplastic interaction with Oryza sativa: toxicity and metabolic mechanism
Researchers confirmed for the first time that polystyrene nanoplastics can enter rice plant root cells through a process called endocytosis. This finding provides important new understanding of how microplastic contamination in soil may affect crop plants and potentially enter the food supply.
Microplastics have rice cultivar-dependent impacts on grain yield and quality, and nitrogenous gas losses from paddy, but not on soil properties
A pot experiment with different rice cultivars found that polyethylene microplastics affected grain yield, quality, and nitrogen cycling in a cultivar-dependent manner, indicating that genetic background modulates plant sensitivity to microplastic contamination. The findings have implications for agricultural management in regions where microplastic-contaminated soils are common.
Evidence and Impacts of Nanoplastic Accumulation on Crop Grains
Researchers investigated whether nanoplastics from contaminated soil can accumulate inside crop grains, studying rice and peanuts grown in nanoplastic-treated soil. They found that nanoplastics traveled from the roots into the grains, reducing rice seed-setting rates by about 3% and peanut seed weight by roughly 3.5%, while also lowering nutritional quality. This is the first study to confirm nanoplastic accumulation in edible crop grains, raising concerns about food chain contamination.
The effect of microplastic contaminated compost on the growth of rice seedlings
Researchers found that adding PET microplastics to compost significantly harmed rice seedling growth, reducing root length by 38%, plant height by 25%, and chlorophyll content by up to 55%. The microplastics appeared to interfere with nutrient uptake and photosynthesis. This is concerning because compost used in agriculture is often contaminated with plastic waste, which could reduce crop yields and potentially affect food quality.
Unveiling the detrimental effects of polylactic acid microplastics on rice seedlings and soil health
Researchers found that even biodegradable polylactic acid (PLA) microplastics significantly harmed rice plants at high concentrations, reducing root and shoot weight by roughly half and disrupting photosynthesis, while also altering soil enzyme activity and bacterial communities. These findings challenge the assumption that biodegradable plastics are harmless to agriculture and raise questions about their impact on food crops that humans depend on.
Effects of microplastics on arsenic uptake and distribution in rice seedlings
Researchers investigated how polystyrene micro- and nanoplastics affect arsenic uptake in rice seedlings grown in a hydroponic system. They found that nanoplastics (82 nm) increased arsenic accumulation in rice leaves by 12 to 37 percent, while larger microplastics (200 nm) reduced it. The study suggests that the size of plastic particles plays an important role in determining how they influence heavy metal uptake in crop plants, with implications for food safety.
Molecular mechanisms of toxicity and detoxification in rice (Oryza sativa L.) exposed to polystyrene nanoplastics
Researchers studied how polystyrene nanoplastics affect rice seedlings at the molecular level. They found that nanoplastic exposure significantly reduced root and shoot growth by over 50%, while triggering oxidative stress and activating genes related to both toxicity and defense responses. The study provides new insights into how crop plants respond to nanoplastic contamination at the genetic and physiological level.
Metabolomics reveals the size effect of microplastics impeding membrane synthesis in rice cells
Researchers studied how polystyrene particles of different sizes (30 nm, 200 nm, and 2 micrometers) affect rice cells, finding that larger particles caused significantly more damage. Exposure to 2-micrometer particles reduced cell viability by 66.4% and protein content by nearly half, while disrupting fatty acid biosynthesis critical for cell membrane formation. The findings suggest that microplastic particle size plays a key role in determining toxicity at the cellular level in plants.
Ecological and physiological risks of micro- and nanoplastics in rice agroecosystems: Challenges and engineering-based mitigation approaches
Researchers reviewed how micro- and nanoplastics harm rice — a staple crop feeding billions — by disrupting root growth, reducing photosynthesis, altering soil microbes, and making heavy metals more available to plants. The review proposes that ecological engineering strategies like microbial bioremediation and organic soil amendments could help protect agricultural land from plastic contamination.
Understanding the Role of Low-Dose Polystyrene Microplastic in Copper Toxicity to Rice Seed (Oryza sativa L.)
This study explored how polystyrene microplastics interact with copper toxicity in rice seeds. Researchers found that microplastics actually reduced copper's harmful effects by physically accumulating on seed coats and blocking copper absorption, lowering the amount of copper taken up by seedlings by about 34%. The findings highlight how microplastics can alter the way other environmental contaminants affect plants.