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61,005 resultsShowing papers similar to Nanoplastic–Biomolecular Interactions
ClearMechanistic 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.
Nanoplastics as a return to the prebiotic dimensional regime: A dimensional perspective on interactions with biological membranes
This paper offers a dimensional perspective on nanoplastic-membrane interactions, arguing that nanoplastics occupy the same size range as early prebiotic structures and can physically integrate with or disrupt lipid bilayers. The framework suggests that physical membrane perturbation — independent of chemical toxicity — is central to nanoplastic health risks.
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.
Nanoplastics as a return to the prebiotic dimensional regime: A dimensional perspective on interactions with biological membranes
This conceptual paper argues that nanoplastics are environmentally significant not primarily because of chemical toxicity, but because their nanoscale dimensions place them in the same physical regime as prebiotic structures that interact directly with biological membranes. The author proposes that membrane disruption, rather than chemical toxicity, is the key mechanism of nanoplastic harm.
Pollution caused by nanoplastics: adverse effects and mechanisms of interaction via molecular simulation
This review used molecular simulation techniques to examine how nanoplastics interact with biological membranes and proteins, finding that NPs alter lipid membrane organization and protein secondary structure, potentially disrupting digestion and nutrient absorption in the gastrointestinal system. The review synthesized evidence that NPs can also adsorb environmental contaminants and potentiate their toxicity through synergistic mechanisms.
Nanoplastics and Human Health: Hazard Identification and Biointerface
This review covers what we know about nanoplastics and their potential effects on human health, including how they enter the body and what happens when they get inside cells. Nanoplastics can penetrate cell membranes and damage internal structures like mitochondria, which are responsible for producing energy in cells. The review also discusses strategies to reduce nanoplastic levels in the environment to protect human health.
The Environmental Impacts of Nanoplastics in Marine Ecosystems
This review examined how nanoplastics—generated by degradation of larger plastics—penetrate biological barriers, accumulate in tissues, contribute to biomagnification, and disrupt marine food chains, highlighting their distinct ecotoxicological mechanisms compared to larger microplastics.
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.
Membrane fusion as a team effort
This paper discusses nanoplastics as an emerging environmental concern with key knowledge gaps, noting that nanoplastics are believed to be more toxic than larger microplastics because of their ability to penetrate biological barriers. Better analytical methods are needed to understand the true scale of nanoplastic contamination and its health implications.
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.
Exploring the Impact of Microplastics and Nanoplastics on Macromolecular Structure and Functions
This review explores how micro- and nanoplastics interact with the building blocks of our cells, including proteins, fats, and DNA. The plastics can cause oxidative stress, disrupt hormones, damage genetic material, cause proteins to misfold, and destabilize cell membranes. The authors propose that these effects are interconnected through feedback loops that could accelerate cellular aging and potentially pass harmful changes to future generations.
Toxicological impact of microplastics and nanoplastics on humans: understanding the mechanistic aspect of the interaction
This review explains the different ways microplastics and nanoplastics cause harm in the human body, including triggering oxidative stress, inflammation, DNA damage, and disruption of gut bacteria. The smaller the plastic particle, the more easily it crosses biological barriers like the gut wall and blood-brain barrier, potentially reaching organs throughout the body. The authors highlight that the COVID-19 pandemic significantly increased plastic waste, adding to the growing burden of human microplastic exposure.
Impact of Nanoplastics on Marine Life: A Review
This review summarizes current knowledge about the effects of nanoplastics on marine organisms, including impacts on feeding, reproduction, growth, and cellular-level toxicity. Evidence indicates that nanoplastics can be more harmful than larger microplastics due to their ability to cross biological barriers and accumulate in tissues, though more research is needed on real-world exposure levels.
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.
Key mechanisms of micro- and nanoplastic (MNP) toxicity across taxonomic groups
This review examines the key ways micro- and nanoplastics cause biological harm across different types of organisms, from bacteria to humans. Researchers identified several common toxicity mechanisms including cell membrane damage, reactive oxygen species generation, DNA damage, and disruption of cellular structures like lysosomes and mitochondria. The study found that toxicity depends heavily on particle size, surface characteristics, and polymer type, and that human cell studies provide especially valuable insights into potential health risks.
Microplásticos y nanoplásticos: mecanismos de bioacumulación y toxicidad
This systematic review summarizes current scientific evidence on how micro- and nanoplastics interact with living systems. It found that these tiny particles can accumulate in biological tissues and trigger toxic responses, underscoring growing concerns about their potential effects on human health.
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.
Assessing toxicological risk of nanoplastics contaminants in food and feed from ingestion pathway to human diseases
This review examines how nanoplastics, which are tiny fragments smaller than 0.1 micrometers, enter the human food chain and may pose health risks. Evidence indicates that nanoplastics can cross biological membranes more easily than larger microplastics, potentially reaching organs and accumulating over time. The study highlights the need for better detection methods and risk assessments to understand the long-term health implications of nanoplastic ingestion through food and beverages.
Nanoplastics in the Environment: Sources, Fate, Toxicity, Challenges and Mitigation Strategies
This review covers the formation, environmental fate, and health risks of nanoplastics, emphasizing their capacity to penetrate biological barriers and cause oxidative stress, inflammation, DNA damage, and endocrine disruption, alongside current strategies for mitigation.
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.
Molecular insights into nanoplastics-peptides binding and their interactions with the lipid membrane
Using computer simulations, researchers studied how nanoplastics interact with small protein fragments and cell membranes at the molecular level. They found that nanoplastics readily bind to proteins, forming a coating called a protein corona, which changes how the plastics behave when they encounter cell membranes. This research helps explain how nanoplastics might enter human cells, since the protein coating could either help or hinder the particles from crossing biological barriers.
Toxicological considerations of nano-sized plastics
This review examined the toxicological considerations specific to nanoplastics, focusing on how particle deposition in different biological compartments, physical properties (size, shape, surface chemistry), and chemical additives interact to determine biological effects. The authors argue that understanding nanoplastic toxicology requires shifting focus from exposure characterization to mechanistic biological relevance at the tissue and organ level.
Molecular toxicity of nanoplastics involving in oxidative stress and desoxyribonucleic acid damage
This review examines the molecular mechanisms by which nanoplastics induce oxidative stress and DNA damage in biological systems, synthesizing findings from cell culture and animal studies. The evidence suggests that nanoplastics can cause genotoxic effects at the cellular level, which is relevant to understanding potential long-term health risks of chronic nanoplastic exposure.
Biological hazards of micro- and nanoplastic with adsorbents and additives
This review summarizes a decade of research on the biological hazards of microplastics and nanoplastics, including how their size, type, and adsorbed chemicals affect living organisms. Researchers found that smaller nanoplastics pose heightened risks because they are more easily absorbed by cells and tissues through ingestion, inhalation, and skin contact. The study emphasizes the need for further research into the long-term health effects of accumulating plastic particles in the environment and in the body.