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Papers
61,005 resultsShowing papers similar to Exploring the Impact of Microplastics and Nanoplastics on Macromolecular Structure and Functions
ClearMolecular and Cellular Effects of Microplastics and Nanoplastics: Focus on Inflammation and Senescence
This review summarizes research showing that micro- and nanoplastics trigger oxidative stress, inflammation, and premature cell aging across many experimental models. These are the same biological processes linked to heart disease, brain disorders, and other age-related conditions. Particularly concerning, studies in animals show that plastic-related damage can be passed from parents to offspring, suggesting potential long-term generational health effects.
Mechanistic Insights into Cellular and Molecular Basis of Protein‐Nanoplastic Interactions
This review examines how nanoplastic particles interact with proteins at the cellular and molecular level, disrupting normal protein function and triggering oxidative stress, DNA damage, and cell death. Researchers found that nanoplastics alter the structural shape of important proteins, which helps explain their toxic effects on living organisms. The study also covers how understanding these protein-plastic interactions could inform both toxicity assessment and potential enzymatic plastic degradation strategies.
Research progress on the cellular toxicity caused by microplastics and nanoplastics
This review summarizes current research on how microplastics and nanoplastics cause damage at the cellular level. Researchers identified four main ways these particles harm cells: triggering oxidative stress, damaging cell membranes and organelles, causing inflammation, and disrupting DNA. The findings highlight growing evidence that plastic particles small enough to enter cells can interfere with fundamental biological processes.
Nanoplastics: An emerging environmental concern in age-related diseases
This review examines the growing body of evidence linking nanoplastics to aging and age-related conditions. Researchers found that nanoplastics can disrupt key molecular pathways involved in inflammation, oxidative stress, and cellular damage that are central to the aging process. The study suggests that chronic nanoplastic exposure may accelerate biological aging, raising concerns about long-term health effects as environmental plastic pollution continues to increase.
Interfacial Interactions between Nanoplastics and Biological Systems: toward an Atomic and Molecular Understanding of Plastics-Driven Biological Dyshomeostasis
This study investigated how nanoplastics interact with biological molecules at the atomic level, finding that polystyrene nanoplastics can destroy the structure of proteins, disrupt cell membranes, and damage DNA. The nanoplastics essentially unfolded a milk protein, punched holes in cell membranes, and broke DNA strands. These findings help explain at a fundamental level how nanoplastics found in human blood, milk, and tissues could cause the inflammation and disease seen in other studies.
Cellular Impact of Micro(nano)plastics on Human Health: A Review.
This review examined how micro(nano)plastics (MNPs) entering the human body through ingestion, inhalation, and skin contact affect cells and tissues. It synthesized evidence of oxidative stress, inflammation, DNA damage, and endocrine disruption associated with MNP exposure.
Nanoplastic–Biomolecular Interactions
This review examines how nanoplastics interact with the biomolecules of living organisms — including proteins, DNA, lipids, and cellular membranes — and how these interactions drive biological harm at the molecular level. Understanding nanoplastic-biomolecule interactions is foundational to explaining why plastic particles at the nanoscale may pose greater health risks than larger microplastics, since they can penetrate cell membranes and reach intracellular targets.
Microplastics/nanoplastics contribute to aging and age-related diseases: Mitochondrial dysfunction as a crucial role
This review examines how microplastics and nanoplastics may contribute to aging and age-related conditions by damaging mitochondria, the energy-producing structures inside cells. Researchers describe how these tiny plastic particles enter the body through food, water, and air, and accumulate in various organs where they can disrupt normal mitochondrial function. The study suggests that microplastic-driven mitochondrial damage could be an underappreciated factor in the aging process and related health decline.
Plastic pollution and its pathophysiological impacts on mammalian cells
This review examines the pathophysiological impacts of microplastics and nanoplastics on mammalian cells, discussing how environmental degradation of larger plastics generates micro- and nano-scale fragments that enter organisms through ingestion, accumulate via trophic transfer, and cause cellular toxicity. The authors synthesize laboratory evidence on MP and NP interactions with mammalian cells including membrane disruption, inflammation, and genotoxicity.
Genotoxicity and Genomic Instability Induced by Micro- and Nanoplastics: A Comprehensive Multi-Taxa Mechanistic Review.
This review of existing research found that tiny plastic particles (microplastics and nanoplastics) can damage DNA in many different living things, from fish to human cells. The plastic particles cause this damage by creating harmful molecules called free radicals, disrupting the body's ability to repair DNA, and triggering inflammation. These findings suggest that the growing amount of plastic pollution in our environment could pose serious health risks to humans and wildlife.
Nanoplastics as a Potential Environmental Health Factor: From Molecular Interaction to Altered Cellular Function and Human Diseases
This review examined how nanoplastics — particularly polystyrene — interact with cells at the molecular level, potentially causing lasting changes that could contribute to developmental problems and degenerative disease. The study highlights growing concerns about nanoplastics as an emerging environmental health risk given their widespread presence in food, water, and air.
Recent consequences of micro-nanaoplastics (MNPLs) in subcellular/molecular environmental pollution toxicity on human and animals
This review examines the subcellular and molecular mechanisms by which micro- and nanoplastics cause toxicity in humans and animals, focusing on oxidative stress, inflammation, cell death pathways, and endocrine disruption at the cellular level.
Micro- and nanoplastic induced cellular toxicity in mammals: A review
This review examines research on how micro- and nanoplastics cause cellular damage in mammalian systems, covering both laboratory and animal studies. Evidence indicates that these particles can trigger oxidative stress, inflammation, and DNA damage in cells, with smaller nanoplastics generally showing greater toxicity due to their ability to penetrate cell membranes more readily.
Cellular and Systemic Impacts of Microplastics and Nanoplastics
This review synthesized evidence on how micro- and nanoplastics cause cellular and systemic harm through inflammation, oxidative stress, mitochondrial dysfunction, and endocrine disruption across multiple organ systems. The authors emphasize that exposure is ubiquitous and that health impacts are no longer speculative.
Cellular and Molecular Mechanisms of Micro- and Nanoplastics Driving Adverse Human Health Effects
This review examines the biological mechanisms by which micro- and nanoplastics may cause harm in humans, including oxidative stress, inflammation, disruption of protective barriers, and immune system problems. Evidence from lab and animal studies suggests these particles can affect the gut, heart, brain, and reproductive systems, though human data is still limited to detecting plastics in tissues rather than proving they cause specific diseases. The authors highlight that most studies use higher doses than people actually encounter, making it important to develop research models that better reflect real-world chronic exposure.
Microplastics and Nanoplastics in Health Concerning Cellular Toxicity Mechanisms, Exposure Pathways, and Global Mitigation Strategies
This review synthesizes current knowledge on how micro- and nanoplastics cause cellular damage in the human body, covering mechanisms like oxidative stress, inflammation, DNA damage, and disruption of cell signaling pathways. Researchers note that exposure occurs through multiple routes including ingestion and inhalation, allowing particles to reach organs throughout the body. The study highlights significant gaps in understanding long-term and low-dose exposure effects that are most relevant to everyday human contact with these particles.
Exploring toxicological pathways of microplastics and nanoplastics: Insights from animal and cellular models
This review examines what animal and cell studies have revealed about how microplastics and nanoplastics cause harm at the molecular level, including promoting inflammation, oxidative stress, and cell death. Most research has focused on reproductive toxicity and polystyrene particles, while effects on the gut, brain, and heart remain understudied. The authors note that many experiments use unrealistic concentrations and synthetic particles, making it difficult to apply the results to real-world human exposure.
Cellular and Systemic Effects of Micro- and Nanoplastics in Mammals—What We Know So Far
This review summarized known cellular and systemic effects of micro- and nanoplastics in mammals, finding that while ingestion is common, knowledge of health impacts remains limited, with oxidative stress and inflammation as the most reported biological responses.
Interactions of Micro- and Nanoplastics with Biomolecules: From Public Health to Protein Corona Effect and Beyond
This review summarizes how micro- and nanoplastics interact with biological molecules in the body, including cell membranes and proteins. These particles can cause membranes to thicken and form pores, and they attract a coating of proteins (called a protein corona) that changes how the body responds to them, potentially increasing inflammation, oxidative stress, and disruption of hormone systems.
Effects of Micro‐ and Nanoplastics on Human Genome
This review examines the emerging evidence on how micro- and nanoplastics may interact with human genetic material, including potential effects on DNA integrity and gene expression. Researchers surveyed laboratory studies showing that these particles can induce oxidative stress and inflammatory responses in human cells, which are known pathways for genetic damage. The study highlights significant knowledge gaps and calls for more research into the long-term genomic effects of chronic microplastic exposure.
Nanoplastics can change the secondary structure of proteins
Researchers found that nanoplastic particles interact directly with proteins and fundamentally alter their secondary structure, effectively denaturing them in a manner that could cause cellular and ecological damage. The study presents the first direct evidence that plastic-protein interactions represent a distinct and potentially serious biological hazard beyond the previously studied effects of microplastic ingestion.
Mechanisms of Cell Toxicity Caused by Degraded Microplastics
This review examined the molecular and cellular mechanisms by which degraded microplastics cause toxicity, focusing on how physical and chemical changes during environmental weathering alter plastic particle biological activity. The paper discussed oxidative stress, membrane disruption, and inflammatory pathways as key toxicity mechanisms of degraded microplastic fragments.
Microplastics and human health: unraveling the toxicological pathways and implications for public health
This review pulls together recent research on how microplastics enter the human body and cause cellular damage through inflammation, oxidative stress, and direct cell injury. The authors highlight that microplastics can also amplify the harmful effects of other environmental pollutants they carry, creating combined health risks that are greater than either threat alone.
Recent insights into uptake, toxicity, and molecular targets of microplastics and nanoplastics relevant to human health impacts
This review summarizes what scientists know about how tiny plastic particles enter the human body and cause harm at the cellular level, including through inflammation, oxidative stress, and disruption of important cell signaling pathways. Americans are estimated to consume tens of thousands to millions of micro- and nanoplastic particles per year, and these particles can penetrate cells and tissues throughout the body.