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61,005 resultsShowing papers similar to Nanoplastics Toxicity Specific to Liver in Inducing Metabolic Dysfunction—A Comprehensive Review
ClearImpact of microplastics and nanoplastics on liver health: Current understanding and future research directions
This review summarizes what scientists know about how micro- and nanoplastics affect the liver, which is one of the first organs exposed because it processes everything absorbed from the gut. The particles trigger oxidative stress, disrupt energy metabolism, cause cell death, and promote inflammation, and may contribute to conditions like fatty liver disease and liver fibrosis. The paper also highlights how plastics can disturb the gut microbiome, which communicates with the liver through the gut-liver axis and may amplify liver damage.
Nanoplastics and Microplastics May Be Damaging Our Livers
This systematic review summarizes research on how micro- and nanoplastics may damage the liver. Since the liver is the body's main detoxification organ, it plays a key role in processing plastic particles that enter the body through food, water, and air, and the evidence suggests these particles can cause inflammation, oxidative stress, and other liver problems.
Mechanisms of microplastics on gastrointestinal injury and liver metabolism disorder (Review)
This review summarizes how microplastics and nanoplastics can damage the gastrointestinal tract and disrupt liver metabolism when they enter the human body. The particles trigger oxidative stress, inflammation, and cell death in gut tissues, and can interfere with how the liver processes glucose and fats. As plastics continue to break down into ever-smaller particles, the potential for harm increases because nanoplastics can penetrate cells more easily.
Emerging threat of environmental microplastics: A comprehensive analysis of hepatic metabolic dysregulation and hepatocellular damage (Review)
This review summarizes existing research on how microplastics damage the liver, which is a key organ for filtering toxins from the body. Studies show that microplastics can cause liver tissue damage, trigger cell death, and disrupt fat metabolism, with smaller particles and longer exposure causing worse effects. The findings highlight the liver as a particularly vulnerable organ because it accumulates microplastics that enter the body through food and water.
Microplastics and nanoplastics: Emerging drivers of hepatic pathogenesis and metabolic dysfunction
This review examines emerging evidence linking micro- and nanoplastic exposure to liver disease, including metabolic dysfunction-associated liver disease, cirrhosis, and liver cancer. Researchers found that these particles may contribute to liver damage through oxidative stress, inflammation, and disruption of metabolic pathways. The study highlights the need for further research into how environmental plastic contamination may be influencing the rising rates of liver disease worldwide.
Microplastic-mediated new mechanism of liver damage: From the perspective of the gut-liver axis
This review describes how microplastics can damage the liver through the gut-liver axis: they first disrupt the gut's protective barrier and beneficial bacteria, allowing harmful substances to leak through the weakened intestinal wall into the bloodstream and travel to the liver. Once there, these substances cause inflammation, metabolic problems, and oxidative stress, offering a new explanation for how microplastic exposure could lead to liver disease.
Hepatotoxic Mechanisms of Micro- and Nanoplastics in Animal Models: A Scoping Review with Human Health Implications
This scoping review examines hepatotoxic mechanisms of micro- and nanoplastics in animal models, identifying oxidative stress, inflammation, lipid peroxidation, and epigenetic alterations as the primary pathways through which plastic particles damage liver tissue.
Microplastics in focus: a silent disruptor of liver health- a systematic review
This systematic review examines how micro- and nanoplastics affect liver health, based on 25 experimental and observational studies. The evidence shows that polystyrene particles can cause liver inflammation, oxidative stress, fat buildup, and disruption of metabolic pathways. These findings are concerning because the liver is the body's primary detoxification organ, and plastic-related damage could impair its ability to process other toxins.
Potential toxicity of microplastics on vertebrate liver: A systematic review and meta–analysis
This meta-analysis of 118 studies found that microplastics damage vertebrate livers by inducing oxidative stress and intracellular toxicity, altering biotransformation processes, and disrupting lipid metabolism. Organisms at earlier life stages, exposed to smaller particles, and for longer durations showed the greatest liver damage, with catalase, GST, reactive oxygen species, and alkaline phosphatase levels progressively increasing with microplastic concentration.
Are Ingested or Inhaled Microplastics Involved in Nonalcoholic Fatty Liver Disease?
This review explored the potential connection between microplastic exposure through ingestion and inhalation and nonalcoholic fatty liver disease, which has become a leading cause of chronic liver injury. The study discusses how dietary and environmental microplastic exposure could potentially influence liver health through mechanisms including inflammation and endocrine disruption, though further research is needed to establish definitive links.
Gut dysbiosis exacerbates inflammatory liver injury induced by environmentally relevant concentrations of nanoplastics via the gut-liver axis
This mouse study found that swallowing nanoplastics at levels found in the environment disrupted gut bacteria and damaged the intestinal barrier, allowing toxins to leak into the bloodstream and cause liver inflammation. When researchers transplanted gut bacteria from nanoplastic-exposed mice into healthy mice, those mice also developed liver damage. This demonstrates that nanoplastics may harm the liver indirectly by first disrupting the gut, a finding relevant to understanding how everyday plastic exposure could affect human health.
Integrating aggregate exposure pathway and adverse outcome pathway for micro/nanoplastics: A review on exposure, toxicokinetics, and toxicity studies
This review brings together research on how micro and nanoplastics enter the human body, where they go once inside, and what harm they may cause, using a framework that links exposure pathways to health outcomes. Studies show these tiny particles can be absorbed through the gut, lungs, and skin, and may accumulate in organs like the liver and kidneys. The paper highlights that micro and nanoplastics can trigger inflammation, oxidative stress, and disruption of hormones, though more research is needed to fully understand the long-term health risks.
Effects of micro-and-nano plastics on various organ systems in health
This review examines the toxicological effects of micro- and nanoplastics on multiple human organ systems—including the gut, liver, lungs, cardiovascular system, and brain—summarizing mechanisms of harm such as oxidative stress, inflammation, and endocrine disruption.
Chronic Nanoplastic Exposure Promotes the Development and Progression of Metabolic Dysfunction‐Associated Steatotic Liver Disease
This study found that chronic exposure to nanoplastics promotes the development and worsening of metabolic dysfunction-associated steatotic liver disease (formerly known as fatty liver disease). Nanoplastics appear to increase vulnerability to liver disease progression. The finding is concerning because fatty liver disease is already widespread, and everyday nanoplastic exposure through food and water could be making it worse.
Uptake and Effects of Micro‐, Submicro‐ and Nanoplastics Investigated on in vitro Models of the Intestinal Barrier and the Liver
Researchers investigated the uptake and toxic effects of micro-, submicro-, and nanoplastics using in vitro models of the intestinal barrier and liver to assess how plastic particles of different sizes interact with gastrointestinal and hepatic cells. The study examined cellular internalization, barrier integrity, and metabolic responses to characterize size-dependent toxicity mechanisms.
A digestive system microphysiological platform for assessment of internal-exposure risks and metabolic disease mechanisms induced by multi-size nano-plastics.
Researchers developed a digestive system organ-on-a-chip microphysiological platform to assess how nanoplastics (NPs) are absorbed, metabolized, and cause internal exposure risks. The system revealed size-dependent toxic effects of NPs on liver cells and lipid metabolism, providing mechanistic insights into NP-associated liver disease risk.
Nano‐plastics disrupt systemic metabolism by remodeling the bile acid–microbiota axis and driving hepatic–intestinal dysfunction
Mice were exposed to polyethylene terephthalate nanoparticles, and researchers used histopathology, metabolomics, and metagenomics to track downstream effects. Nanoplastic ingestion caused severe metabolic disruption—including weight loss, organ atrophy, and liver-intestinal dysfunction—by remodeling the bile acid–gut microbiota axis.
Exploring the impact of nanoplastics on human hepatic cells: dynamics of internalization and harmful effects in HuH-7 cells
Researchers investigated how nanoplastics are internalized by human liver cancer cells (HuH-7) and assessed the cellular damage that follows, characterizing the dynamics of particle uptake and the resulting cytotoxic effects relevant to hepatic health.
The hepatotoxicity assessment of micro/nanoplastics: A preliminary study to apply the adverse outcome pathways
Researchers reviewed the literature on how micro- and nanoplastics cause liver damage and organized the findings into an Adverse Outcome Pathway framework. They found that plastic particles can trigger oxidative stress, inflammation, and metabolic disruption in the liver, potentially leading to dysfunction. The study provides a structured way to understand the chain of events from plastic particle exposure to liver harm, highlighting potential health risks for humans.
Polystyrene nanoplastics induce intestinal and hepatic inflammation through activation of NF-κB/NLRP3 pathways and related gut-liver axis in mice
In a mouse study, ingested polystyrene nanoplastics accumulated in the gut and liver and triggered inflammation through specific immune pathways, damaging the intestinal lining and allowing bacterial toxins to leak into the liver. This gut-liver connection suggests that swallowing nanoplastics could set off a chain reaction of inflammation affecting multiple organs in the body.
Nano- and microplastics: a comprehensive review on their exposure routes, translocation, and fate in humans
This comprehensive review traces the journey of nano- and microplastics through the human body, covering how they enter through breathing, eating, drinking, and skin contact. Once inside, the smallest particles can cross the gut and lung barriers, enter the bloodstream, and accumulate in organs including the liver, kidneys, and placenta. The review highlights significant knowledge gaps about long-term health effects but notes that the evidence for internal accumulation in humans is growing.
Uncovering layer by layer the risk of nanoplastics to the environment and human health
This review examines how nanoplastics, plastic particles smaller than 100 nanometers, can cross biological barriers like the gut lining and accumulate in vital organs. Once inside the body, nanoplastics can trigger inflammation, oxidative stress, genetic damage, hormone disruption, and immune problems. The authors stress the need for standardized detection methods and long-term studies to fully understand the health risks these tiny particles pose to humans.
Molecular insights into physiological impact of micro- and nano-plastics on the digestive system and gut-brain axis
This review evaluates molecular-level evidence on how micro- and nanoplastics affect the digestive system and the gut-brain axis after ingestion through contaminated food and water. The study describes how these particles accumulate in the gastrointestinal tract, liver, and pancreas, causing oxidative stress, gut microbiota disruption, and compromised intestinal barriers, potentially allowing particles to reach the central nervous system and contribute to neuroinflammatory conditions.
Eco-toxicity of nano-plastics and its implication on human metabolism: Current and future perspective
This review examines the sources, bioaccumulation pathways, and potential health effects of nanoplastics on human metabolism. Researchers found that nanoplastics can enter the body primarily through ingestion of contaminated food and packaging, and evidence suggests they may interfere with metabolic pathways and contribute to organ dysfunction. The study highlights that significant knowledge gaps remain in assessing the human health risks of nanoplastic exposure.