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20 resultsShowing papers similar to Microplastic accumulation and oxidative stress in sweet pepper (Capsicum annuum Linn.): Role of the size effect
ClearMechanistic insights into the size-dependent bioaccumulation and phytotoxicity of polyethylene microplastics in tomato seedlings
Researchers investigated how polyethylene microplastics of different sizes affect tomato seedlings and found that the smallest particles (1-50 micrometers) caused the most severe damage, reducing shoot weight by 42.3% and root length by 55.1%. The study revealed that microplastic uptake and toxicity are strongly size-dependent, with smaller particles more easily absorbed and translocated through plant tissues, triggering significant oxidative stress.
Risks of microplastics on germination and growth of pepper (Capsicum annuum L.) depending on the type, concentration, and particle size
Researchers tested how different types, concentrations, and sizes of microplastics affect pepper seed germination and seedling growth. They found that most microplastic treatments inhibited germination and that polyethylene terephthalate (PET) particles were generally the most harmful to seedling development. The study also revealed that larger microplastic particles tended to cause more oxidative stress in the plants, suggesting particle size plays an important role in toxicity.
Impact of microplastics on plant physiology: A meta-analysis of dose, particle size, and crop type interactions in agricultural ecosystems
This meta-analysis of 37 studies found that microplastics significantly decrease plant biomass by 13% and chlorophyll content by 28%, while increasing oxidative stress by 20%. Higher doses and smaller particle sizes caused more damage, with particle size having a greater impact than concentration — and root activity was particularly sensitive to microplastic exposure.
Mechanistic insights into the effects of micro- and nano-plastics on cherry radish physiology and organic compound distribution at the soil-root interface.
Researchers exposed cherry radish to polyethylene microplastics (2 µm) and nanoplastics (200 nm) at varying concentrations and measured effects on plant physiology and organic compound distribution at the soil-root interface. Smaller nanoplastic particles caused greater disruption to root exudate chemistry and plant metabolism than the larger microplastics, pointing to a size-dependent toxicity mechanism.
Occurrence and distribution of micro/nanoplastics in soils and their phytotoxic effects: A review
This review examined how micro- and nanoplastics distribute across different soil types and get taken up by plant roots, finding that smaller, spherical particles are absorbed more easily. Researchers found that these plastic particles accumulate in plants and trigger oxidative stress, which disrupts gene expression and metabolic pathways important for plant growth and biomass production.
Plants and microplastics: Growing impacts in the terrestrial environment
This review examines how microplastics affect plant growth and food crops, finding that exposure generally reduces plant size, chlorophyll content, and photosynthesis, though low concentrations can sometimes stimulate root growth. Plants can take up plastic particles smaller than 1 micrometer through their roots and move them to other tissues. These findings raise concerns that microplastics in soil, which can occur at higher levels than in water, could affect the health and nutritional quality of the food crops that people depend on.
Accumulation of plastics in terrestrial crop plants and its impact on the plant growth
This review examines how small plastic particles accumulate in crop plants and affect plant growth, finding that microplastics can enter plant tissues and disrupt physiological processes. Crops grown in microplastic-contaminated soil could carry plastic particles into the food supply, raising concerns about dietary exposure.
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.
Assessment of physiological stress on plants grown in soil contaminated with microplastics
Researchers tested how three types of microplastics (PET, HDPE, and polyester) affect the growth and health of spring onion and okra plants. They found that all microplastic types reduced chlorophyll levels, increased oxidative stress, and stunted plant growth, with HDPE and polyester causing the most damage. The study highlights the potential ecological risks microplastics pose to vegetable crops grown in contaminated soil.
Unraveling the impact of nano-microscale polyethylene and polypropylene plastics on Nicotiana tabacum: Physiological responses and molecular mechanisms
Researchers exposed tobacco plants to polyethylene and polypropylene microplastics of different sizes and found that both types suppressed plant growth in a dose-dependent manner, with polypropylene being more toxic. The microplastics disrupted photosynthesis, triggered oxidative stress, and altered hormone signaling and defense pathways in the plants. These findings demonstrate that microplastic contamination in soil can impair crop growth at the molecular level, potentially affecting agricultural productivity.
Microplastic stress in plants: effects on plant growth and their remediations
This review examines how microplastic contamination in soil affects plant growth through multiple pathways, including blocking water and nutrient absorption through roots, triggering harmful levels of reactive oxygen species, and disrupting hormone regulation. The effects vary depending on the type, size, and amount of microplastic present. Since plants are the foundation of our food supply, understanding how microplastics impair crop health is directly relevant to food safety and human nutrition.
Impact of microplastic particle size on physiological and biochemical properties and rhizosphere metabolism of Zea mays L.: Comparison in different soil types
Researchers found that smaller microplastics caused more harm to corn plant growth than larger ones, and that soil type affected how toxic the microplastics were. The microplastics disrupted root metabolism and weakened the plants' ability to produce lignin, a structural compound important for healthy roots. This matters for food safety because microplastic contamination in farm soil could reduce crop yields and potentially affect the nutritional quality of food.
Micro and nanoplastics as emerging stressors influencing plant metabolism and nutrient dynamics
This review of existing research shows that tiny plastic particles in farm soil can get inside plants and change how they grow and absorb nutrients. When plants take up these microplastics, it could affect the nutritional quality of the fruits and vegetables we eat, potentially impacting our food safety. However, scientists still need more long-term studies to fully understand how serious this threat is to our food supply and health.
The dosage- and size-dependent effects of micro- and nanoplastics in lettuce roots and leaves at the growth, photosynthetic, and metabolomics levels
Researchers studied the effects of polyethylene micro- and nanoplastics on lettuce plants, varying both particle size and concentration. They found that particle size played a pivotal role in influencing plant growth, photosynthetic activity, and metabolic processes, with nanoplastics generally causing more pronounced effects than larger microplastics. The study suggests that the smallest plastic particles pose the greatest risk to crop health by disrupting plant physiology at multiple levels.
Physiological response of cucumber (Cucumis sativus L.) leaves to polystyrene nanoplastics pollution
Researchers exposed cucumber plants to polystyrene nanoplastics of four different sizes and found significant effects on photosynthesis, antioxidant systems, and sugar metabolism in the leaves. Smaller particles tended to reduce chlorophyll and photosynthetic activity, while larger particles triggered stronger oxidative stress responses. The study suggests that nanoplastic contamination in farmland soils could impair crop growth through multiple biochemical pathways.
Particle size-dependent biomolecular footprints of interactive microplastics in maize
Researchers tested how five common types of microplastics at different particle sizes affect maize seedlings at the molecular and physiological level. The study found that smaller microplastic particles (75-150 micrometers) caused more cellular damage than larger ones, disrupting cell membranes, reducing photosynthetic pigments, and triggering stress responses. Mixtures of multiple plastic types were especially harmful, suggesting that real-world combinations of microplastic pollution may pose greater risks to crops than individual plastic types.
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.
Microplastics and nanoplastics in the soil-plant nexus: Sources, uptake, and toxicity
This review examines how microplastics and nanoplastics accumulate in agricultural soils from plastic products and affect the soil-plant system. Researchers found that nanoplastics can be taken up by plant roots, cause oxidative stress, and negatively affect crop growth. The findings raise concerns about food safety since these particles may carry co-contaminants into the food chain.
Impacts of Micro/Nanoplastics on Crop Physiology and Soil Ecosystems: A Review
This review synthesized evidence on how micro- and nanoplastics affect crop physiology and soil ecosystems, covering how plastic particles enter plants via roots, disrupt soil microbiota, and impair crop growth through oxidative stress, nutrient cycling disruption, and physical root interference. The authors found that nanoplastics pose greater plant risks than microplastics due to their ability to cross cell membranes.
Micro (nano) plastics uptake, toxicity and detoxification in plants: Challenges and prospects
This review examines how micro and nanoplastics are taken up by plants, covering their toxic effects on growth and gene expression as well as potential detoxification strategies. Smaller nanoplastics can penetrate plant cell walls and accumulate in tissues, causing oxidative stress and genetic damage. The findings are important for human health because contaminated crops could transfer microplastics directly into the food supply.