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20 resultsShowing papers similar to Potential impact of polyethylene microplastics on the growth of water spinach (Ipomoea aquatica F.): Endophyte and rhizosphere effects
Clear[Effects of Low-density Polyethylene Microplastics on the Growth and Physiology Characteristics of Ipomoea aquatica Forsk].
Researchers grew water spinach in soil spiked with low-density polyethylene microplastics at varying concentrations and found that even moderate doses reduced germination rates, stunted growth, and disrupted photosynthesis. The study suggests that microplastic contamination in agricultural soil could threaten food crop yields and quality.
Water Spinach (Ipomoea aquatica F.) Effectively Absorbs and Accumulates Microplastics at the Micron Level—A Study of the Co-Exposure to Microplastics with Varying Particle Sizes
Researchers discovered that water spinach plants can absorb and accumulate micron-sized polystyrene microplastics in their leaves when the particles are taken up through the roots. The plastic particles traveled from roots through the plant's transport system to accumulate in leaf tissue, and high concentrations stunted plant growth. This finding is directly concerning for food safety because it shows that leafy vegetables people eat can contain microplastics absorbed from contaminated soil or water.
The Effects of Microplastics and Heavy Metals Individually and in Combination on the Growth of Water Spinach (Ipomoea aquatic) and Rhizosphere Microorganisms
Researchers tested how combinations of microplastics and heavy metals (cadmium and lead) affect the growth of water spinach and the microbial communities in its root zone. They found that all three stressors individually inhibited plant growth, and combining microplastics with heavy metals intensified the toxic effects while reducing the availability of essential soil nutrients. The study suggests that microplastic-heavy metal interactions in agricultural soils may pose compounding risks to both crop health and soil ecosystem function.
Effects of polyethylene microplastics on the microbial community structure of maize rhizosphere soil
Researchers investigated how polyethylene microplastics from agricultural films affect the microbial communities in crop root zones (rhizosphere), finding shifts in bacterial diversity and function. Disrupting soil microbiomes through microplastic contamination could have downstream effects on soil fertility and crop health.
Polystyrene nanoplastics' accumulation in roots induces adverse physiological and molecular effects in water spinach Ipomoea aquatica Forsk
Researchers exposed water spinach to polystyrene nanoplastics in a hydroponic experiment and tracked where the particles accumulated in the plant. They found that nanoplastics built up primarily in the roots, causing reduced growth, impaired photosynthesis, and disrupted antioxidant defense systems. The study raises concerns about nanoplastic uptake by edible aquatic vegetables and the potential implications for food safety.
Impact of Nanoplastic Contamination on Rhizosphere Microbiome and Plant Phenotype
This study examined how nanoplastic contamination affects the rhizosphere microbiome (soil bacteria around plant roots) and plant growth. Nanoplastic exposure altered soil microbial communities and reduced plant growth, suggesting these tiny plastic particles could disrupt the soil ecosystems that support food production.
Soil microorganisms play an important role in the detrimental impact of biodegradable microplastics on plants
Researchers found that biodegradable microplastics harmed vegetable crop growth by disrupting the soil microbial community rather than through direct contact with the plants. When soil microorganisms were suppressed, the negative effects of the biodegradable microplastics on plant growth were also reduced. The study suggests that soil bacteria and fungi play a key role in mediating the harmful impacts of biodegradable plastics on agricultural crops.
Effects of microplastics on common bean rhizosphere bacterial communities
Researchers studied how polyethylene and biodegradable microplastics affect bacterial communities in the root zone of common beans. Both types of microplastics significantly altered the diversity and composition of rhizosphere bacteria, with biodegradable microplastics inducing more distinctive changes than conventional polyethylene at higher concentrations.
Potential impacts of polyethylene microplastics and heavy metals on Bidens pilosa L. growth: Shifts in root-associated endophyte microbial communities
Researchers found that polyethylene microplastics in soil contaminated with heavy metals significantly stunted plant growth, reducing root length by nearly 49% and increasing harmful reactive oxygen species in plant tissues. The microplastics also shifted the soil's microbial communities toward stress-resistant species, demonstrating how plastic pollution can disrupt the soil ecosystem that supports our food supply.
Effects of Microplastics on Endophytes in Different Niches of Chinese Flowering Cabbage (Brassica campestris)
Researchers studied how microplastics of different sizes and concentrations affect the microbial communities living inside Chinese flowering cabbage tissues. They found that microplastic exposure significantly altered the endophytic bacteria in roots and stems, increasing the abundance of potentially harmful bacterial species. The study suggests that microplastic contamination in agricultural soils may compromise plant health by disrupting the beneficial microorganisms that naturally reside within crop tissues.
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.
Multifaceted effects of microplastics on soil-plant systems: Exploring the role of particle type and plant species
Researchers tested how three different types of microplastics — fibers, fragments, and spheres — affect soil properties and vegetable growth. The effects varied significantly depending on both the type of plastic and the plant species, with some microplastics actually promoting root growth in certain vegetables. These mixed results highlight that the impact of microplastic contamination on food crops is complex and depends on the specific conditions in each field.
Accumulation modes and effects of differentially charged polystyrene nano/microplastics in water spinach (Ipomoea aquatica F.)
Researchers investigated how water spinach plants absorb nano and microplastics of different sizes and electrical charges. They found that smaller, positively charged particles were absorbed more readily by roots and could travel to the leaves, while larger particles tended to stay on root surfaces. This matters because leafy vegetables like water spinach could be delivering nanoplastics directly to people who eat them.
Microplastics from agricultural mulch films: a threat to growth promoting abilities of bacteria?
Researchers tested how microplastics shed from agricultural plastic mulch films affect soil bacteria that promote plant growth, finding that mulch-derived microplastics reduced the abundance and activity of key plant growth-promoting bacteria. The results suggest agricultural plastic use could undermine soil health and crop productivity.
Microplastics contamination on spinach (Spinacia oleracea): influence of plastic polymers, growing media, and copper co-exposure
A pot experiment tested how different microplastic polymers (LDPE, PBAT, starch-based) and copper co-contamination affected spinach grown in two soil types, finding that microplastic effects on plant growth and copper uptake varied significantly by polymer type and soil characteristics.
Investigation of the effects of polyethylene microplastics at environmentally relevant concentrations on the plant-soil-microbiota system: A two-year field trial
Researchers conducted a two-year field trial to study how polyethylene microplastics at environmentally relevant concentrations affect crops, soil, and microbial communities in a rice-wheat rotation system. They found that microplastics did not harm wheat growth but actually increased rice grain weight and plant height, while reducing soil nutrient levels including nitrogen and phosphorus. The study reveals that microplastics can alter soil bacterial communities and disrupt metabolic processes in ways that differ between crop seasons.
Nanoplastics indirectly compromise lettuce growth in hydroponic systems via microbial extracellular vesicles derived from Curvibacter fontanus
Researchers found that nanoplastics in hydroponic irrigation water did not directly harm lettuce but caused significant shifts in microbial communities, particularly increasing the abundance of the bacterium Curvibacter fontanus. Extracellular vesicles produced by this bacterium under nanoplastic exposure suppressed lettuce growth, antioxidant defenses, and survival. The study reveals an indirect pathway by which nanoplastic contamination can harm crop production through microbial disruption.
Polyethylene microplastics alter soil microbial community assembly and ecosystem multifunctionality
Researchers studied how polyethylene microplastics at different concentrations affect soil microbial communities and overall ecosystem function in a maize growing system. They found that higher concentrations of microplastics shifted microbial community composition, reduced beneficial bacteria involved in nutrient cycling, and impaired multiple soil ecosystem functions simultaneously. The study suggests that microplastic contamination in agricultural soils can undermine the biological processes that support healthy crop growth.
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.
Negative effects of poly (butylene adipate-co-terephthalate) microplastics on Arabidopsis and its root-associated microbiome
Researchers investigated the effects of poly(butylene adipate-co-terephthalate) (PBAT) biodegradable microplastics on Arabidopsis thaliana and its root-associated microbiome, finding that PBAT-MPs at tested concentrations in agricultural soil caused negative impacts on plant growth and altered the composition of root-zone microbial communities.