We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Papers
61,005 resultsShowing papers similar to Interfacial Interactions between Nanoplastics and Biological Systems: toward an Atomic and Molecular Understanding of Plastics-Driven Biological Dyshomeostasis
ClearNanoplastics 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.
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.
Perturbation of Nanoplastics on Biomembranes: Molecular Insights from Neutron Scattering
Using neutron scattering, researchers found that polystyrene nanoplastics — with and without surface modifications — perturb the structure and dynamics of both simple and complex bacterial-model biomembranes, suggesting nanoplastics can physically disrupt cell membrane function.
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.
Polystyrene and polyethylene perturb the structure of membrane: An experimental and computational study
Researchers combined cell experiments, molecular dynamics simulations, and toxicogenomic analysis to show that polystyrene and polyethylene nanoplastics — individually and as a mixture — physically penetrate cell membranes and form pores, with the mixture producing stronger disruption than either polymer alone.
Interfacial interactions between PMMA nanoplastics and a model globular protein: towards a molecular understanding of nanoplastic-driven biological dyshomeostasis
Researchers investigated the molecular interactions between PMMA nanoplastics and a model globular protein to understand how nanoplastics disrupt normal protein function. They found that PMMA nanoplastics bind to and alter the structural conformation of the protein, potentially contributing to cellular protein dysfunction.
Nanoplastic-Induced Disruption of DPPC and Palmitic Acid Films: Implications for Membrane Integrity
Researchers studied how nanoplastics interact with lung and cell membrane lipids at the molecular level. They found that polystyrene nanoplastics can physically insert themselves into lipid films that mimic cell membranes, with greater disruption at higher concentrations. These findings help explain how nanoplastics may penetrate cellular barriers, potentially affecting lung function and allowing the particles to accumulate in biological tissues.
Cellular interactions with polystyrene nanoplastics—The role of particle size and protein corona
Researchers investigated how polystyrene nanoplastics interact with mammalian cells, finding that particle size and the protein corona that forms around particles in biological fluids strongly influence cellular uptake and toxicity. Smaller nanoplastics penetrated cell membranes more readily and caused greater disruption, suggesting that the tiniest plastic particles may pose the greatest biological risk.
Nanoplastics Alter DNA
Researchers demonstrated that positively charged polystyrene chains can bind directly to DNA helices through electrostatic interactions with phosphate groups, inducing structural changes in the DNA. The findings suggest nanoplastics with charged surfaces could interfere with DNA structure and function at the molecular level.
Perturbation of Nanoplastics on Biomembranes: Molecular Insights from Neutron Scattering
Researchers used neutron scattering to study how polystyrene nanoplastics with and without surface modifications interact with model lipid bilayers. They found that nanoplastics disrupt membrane structure through physical insertion and bilayer thinning, with surface modifications significantly altering the degree of membrane perturbation.
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.
Polystyrene-InducedDehydration of Lipid Membranes:Insights from Atomistic Simulations
Researchers used atomistic molecular dynamics simulations to investigate how polystyrene nanoplastics interact with lipid bilayer membranes after penetrating them, focusing specifically on whether and how such particles induce membrane dehydration. They found that polystyrene nanoplastics cause significant dehydration of lipid membranes, providing new mechanistic insight into nanoplastic-induced cellular disruption.
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.
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.
Polystyrene-InducedDehydration of Lipid Membranes:Insights from Atomistic Simulations
Researchers conducted atomistic simulations to examine how polystyrene nanoplastics induce dehydration in lipid bilayer membranes after penetrating the membrane interior. The simulation results provided molecular-level evidence that nanoplastic-membrane interactions cause lipid dehydration, offering mechanistic insight into how nanoplastics may disrupt cellular membrane function.
Polystyrene-Induced Dehydration of Lipid Membranes: Insights from Atomistic Simulations
Atomistic molecular dynamics simulations revealed that polystyrene nanoplastics cause dehydration of lipid membranes upon contact, extracting water molecules from the bilayer interface in ways that could alter membrane structure and function relevant to cellular uptake of nanoplastic particles.
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.
Perturbation of Nanoplastics on Biomembranes: Molecular Insights from Neutron Scattering
Scientists found that tiny plastic particles called nanoplastics can seriously damage cell membranes, which are the protective barriers around our cells. The plastic particles caused membranes to break apart and get thinner, though some natural cell types were more resistant to damage than others. This research helps us understand why the growing amount of plastic pollution in our environment and food could pose health risks to humans.
Interaction of polyethylene nanoplastics with the plasma, endoplasmic reticulum, Golgi apparatus, lysosome and endosome membranes: A molecular dynamics study
Researchers used computer simulations to study how polyethylene nanoplastics interact with five types of cell membranes in the human body, finding that the plastic particles spontaneously insert themselves into the fatty inner layer of membranes and disrupt normal membrane flexibility. These atomic-level findings help explain how nanoplastics may cause cell damage from the inside.
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.
Unmasking the Invisible Threat: Biological Impacts and Mechanisms of Polystyrene Nanoplastics on Cells
This review summarizes how polystyrene nanoplastics, tiny plastic particles found throughout the environment, damage cells through multiple pathways including oxidative stress, DNA damage, inflammation, and mitochondrial dysfunction. Nanoplastics can trigger several forms of cell death and disrupt normal cell processes like autophagy (the cell's recycling system). The findings raise concerns about long-term human health effects from chronic exposure to these nearly invisible plastic particles.
Intracellular Protein Adsorption Behavior and Biological Effects of Polystyrene Nanoplastics in THP-1 Cells
Researchers discovered that polystyrene nanoplastics enter human immune cells and adsorb hundreds of intracellular proteins, disrupting important cellular processes including energy metabolism and protein folding. The nanoplastics were taken into cells through a specific pathway called clathrin-mediated endocytosis and interfered with normal protein function once inside. This study provides new molecular-level evidence for how nanoplastics could harm human health by disrupting the internal machinery of immune cells.
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.
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.