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Papers
20 resultsShowing papers similar to Unveiling the impact of microplastics and nanoplastics on vascular plants: A cellular metabolomic and transcriptomic review
ClearMicro (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.
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.
Impact of nanoplastics uptake on modulation of plant metabolism and stress responses: a multi-omics perspective on remediation and tolerance mechanisms
Researchers reviewed how nanoplastics accumulate in plant tissues and disrupt metabolism, finding that these particles impair nutrient uptake, trigger reactive oxygen species overproduction, and alter gene and protein expression, while multi-omics approaches are revealing the molecular stress-response networks that plants use to tolerate or remediate nanoplastic contamination.
Microplastic/nanoplastic toxicity in plants: an imminent concern
This review examines the growing body of research on how microplastics and nanoplastics affect terrestrial plants, from root uptake to changes in growth and gene expression. Researchers found that these particles can alter plant physiology and biochemistry at varying degrees depending on particle size and concentration. The study calls for more research on how plastic contamination in soil may ultimately affect food crop quality and human health through the food chain.
Micro and nanoplastics pollution: Sources, distribution, uptake in plants, toxicological effects, and innovative remediation strategies for environmental sustainability
This review examines how microplastics and nanoplastics enter plants through roots, disrupt growth and photosynthesis, and cause oxidative stress that reduces crop yields. Because these plastic particles can move through plant tissues and into edible parts, they represent a potential pathway for microplastics to enter the human food supply.
Exploring omics solutions to reduce micro/nanoplastic toxicity in plants: A comprehensive overview
This review summarizes how advanced biological analysis techniques are being used to understand how micro- and nanoplastics harm crops by disrupting water uptake, nutrient absorption, and photosynthesis. Since these tiny plastic particles accumulate in agricultural soil and can enter the food chain, the research highlights a potential pathway for microplastics to reach humans through the food we eat.
Assessing the impact of micro and nanoplastics on the productivity of vegetable crops in terrestrial horticulture: a comprehensive review
This review summarizes research on how micro and nanoplastics accumulate in farmland and get absorbed by vegetable crops through their roots, building up in the edible parts of the plants. The plastic particles cause toxic effects that stunt plant growth by disrupting cellular processes and gene activity. This means the vegetables people eat may contain microplastics picked up from contaminated soil.
Unveiling the mechanism of micro-and-nano plastic phytotoxicity on terrestrial plants: A comprehensive review of omics approaches.
This comprehensive review examined how micro-and-nano plastics (MNPs) in terrestrial soils damage plant health by inhibiting water and nutrient uptake, reducing seed germination, impairing photosynthesis, and inducing oxidative stress. The review identified key knowledge gaps in understanding MNP phytotoxicity mechanisms and their implications for food security.
Microplastics: toxicity and tolerance in plants
Researchers reviewed how microplastics harm both land plants and water plants by disrupting their growth, nutrient uptake, and genetic function, while also triggering the plants' own defense systems in response. Understanding how plants tolerate microplastic exposure is important because contaminated crops could eventually affect human health through the food chain.
Microplastics and plant health: A comprehensive analysis of entry pathways, physiological impacts, and remediation strategies
This comprehensive review examines how microplastics enter plant systems, the physiological and biochemical impacts on plant health, and the implications for crop productivity and food safety, synthesizing evidence that MPs can reduce germination, growth, and nutritional quality in agricultural plants.
How do nanoplastics hijack crop physiology: A review of uptake pathways and agricultural sustainability implications
This research review summarizes how tiny plastic particles called nanoplastics can get inside crop plants through their roots and leaves, potentially harming how plants grow and produce food. These ultra-small plastic pieces interfere with how plants absorb nutrients and respond to stress, which could threaten our food supply. Since we eat these crops, understanding how nanoplastics affect plant health is important for protecting both agriculture and human health.
Threats to Terrestrial Plants from Emerging Nanoplastics
This meta-analysis examines how nanoplastics affect terrestrial plants, finding impacts on growth, nutrient uptake, and cellular function. The research matters for human health because plants that absorb nanoplastics from contaminated soil could transfer these particles into fruits and vegetables that end up on our plates.
Impacts of Plastics on Plant Development: Recent Advances and Future Research Directions
This review summarizes how microplastics and nanoplastics affect plant growth, from blocking seed germination and root development to causing oxidative stress and DNA damage in plant cells. Nanoplastics are small enough to be absorbed by roots and transported to stems, leaves, and even fruits. These findings are concerning for human health because they show that microplastics can enter the food supply through crops, creating a direct pathway for human exposure through plant-based foods.
Micro- and nanoplastics-induced stress in plants: uptake, physiological disruption, and toxicity mechanisms
This review paper summarizes existing research on how tiny plastic particles (called microplastics and nanoplastics) are absorbed by plants and damage their health. These plastic particles can build up in plant tissues and disrupt how plants grow and function, which matters because we eat these plants. Since plastic pollution keeps breaking down into smaller pieces that plants absorb, this could eventually affect the safety and quality of our food supply.
The Role of Omics Technology in Evaluating Plastic Pollution’s Effects on Plants: A Comprehensive Review
This comprehensive review examines how omics technologies (genomics, proteomics, metabolomics, transcriptomics) are being applied to understand the molecular mechanisms by which micro- and nanoplastics damage plants, including oxidative stress, stunted growth, and disrupted soil microbiomes.
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.
Interactions between microplastics/nanoplastics and vascular plants
This review examines how microplastics and nanoplastics interact with vascular plants, covering both how plants affect the fate of plastic particles and how the particles affect plant health. Researchers found that plants can act as sinks for micro- and nanoplastics, accumulating them from soil and water, while exposure to these particles can inhibit seed germination, root growth, and photosynthesis. The study highlights the importance of understanding these interactions for assessing risks to agricultural productivity and food safety.
Adsorption, uptake and toxicity of micro- and nanoplastics: Effects on terrestrial plants and aquatic macrophytes
This review summarizes research on how micro- and nanoplastics interact with terrestrial plants and aquatic macrophytes, finding that many species can absorb or take up plastic particles. Both short-term and long-term plastic exposure triggered stress responses in plants, and since plants are at the base of food chains and a major part of the human diet, there is concern about plastics moving up through the food web. The findings suggest that plastic pollution could potentially affect plant productivity and broader ecosystem function.
Uptake, transport and accumulation of micro- and nano-plastics in terrestrial plants and health risk associated with their transfer to food chain - A mini review.
This review examines how micro- and nano-plastics (MNPs) are taken up, transported, and accumulated in terrestrial plants, and assesses the associated health risks as MNPs transfer through the food chain from contaminated soil and water environments.
Understanding the possible cellular responses in plants under micro(nano)-plastic (MNPs): Balancing the structural harmony with functions.
This review summarizes current understanding of how micro- and nano-plastics affect plant physiology, covering uptake pathways, effects on cell walls and chloroplasts, and responses to oxidative stress. The findings highlight that plants are exposed to and affected by microplastics through both soil and aerial routes.