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61,005 resultsShowing papers similar to Effects of polymeric nanoparticles on fish : a multiparametric approach
ClearEcotoxicity of Petrogenic Plastic Particles in Fish: Implication for Human Health and Environmental Risk Assessment
This review examined the ecotoxicity of petrogenic (petroleum-derived) micro- and nanoplastics on fish, covering how polymer type, size, and associated contaminants influence toxic effects. The authors discuss implications for human health risk assessment given that petrogenic MNPs are among the most prevalent plastic types in aquatic environments.
Potential toxicity of nanoplastics to fish and aquatic invertebrates: Current understanding, mechanistic interpretation, and meta-analysis
Nanoplastics significantly reduced survival, behavior, and reproduction of fish and aquatic invertebrates by 56%, 24%, and 36% respectively, while increasing oxidative stress by 72% and decreasing antioxidant defenses by 24%, with effects influenced by particle size, functional groups, and concentration.
Plastic nanoparticles cause mild inflammation, disrupt metabolic pathways, change the gut microbiota and affect reproduction in zebrafish: A full generation multi-omics study.
Exposure of zebrafish to polystyrene nanoparticles throughout their entire first generation caused mild inflammation, disrupted metabolic pathways, altered gut microbiota, and impaired reproduction — even at environmentally relevant concentrations. This comprehensive multigenerational study demonstrates that nanoplastic exposure can have lasting biological effects across multiple body systems in fish.
Biological Effects and Implications of Micro- and Nanoplastics in the Aquatic Environment
This review summarizes what is known about the biological effects and implications of micro- and nanoplastics on aquatic organisms, covering a wide range of species from phytoplankton to fish. It highlights that while laboratory studies show harm at high concentrations, the effects at environmentally relevant levels are still poorly understood.
Effect of nanoplastics on fish health and performance: A review
Researchers reviewed studies on nanoplastics (particles smaller than 100 nm) in fish and found evidence of tissue accumulation, impaired locomotion and foraging, immune and growth disruption, altered lipid metabolism, and neurotoxicity, though mortality and developmental malformations had not yet been reported.
Investigation of the impact caused by different sizes of polyethylene plastics (nano, micro, and macro) in common carp juveniles, Cyprinus carpio L., using multi-biomarkers.
Common carp juveniles exposed to polyethylene plastics of three different sizes (nano, micro, and macro) all showed tissue damage, oxidative stress, and immune disruption, with nanoparticles causing the most severe effects. The size-dependent toxicity pattern suggests that as larger environmental plastics break down into smaller particles, their potential to harm fish — and ultimately people who eat them — may increase.
Effects of microplastics on the toxicity of co-existing pollutants to fish: A meta-analysis
Meta-analysis of 1,380 biological endpoints from 55 studies found that microplastics in co-existing pollutant solutions significantly increased toxicity to fish beyond what the pollutants caused alone, particularly elevating immune system damage, metabolic disruption, and oxidative stress. The effect depended on fish life stage and microplastic size, but not on pollutant or polymer type.
Toxicological review of micro- and nano-plastics in aquatic environments: Risks to ecosystems, food web dynamics and human health.
This review synthesized evidence on the toxicological effects of micro- and nanoplastics in aquatic ecosystems, covering risks to individual organisms, disruptions to food web dynamics, and pathways through which plastic exposure poses risks to human health via seafood consumption.
A systematic review of the effects of nanoplastics on fish
This systematic review examines how nanoplastics (extremely small plastic particles) affect fish, including their ability to cross biological barriers and accumulate in tissues. The findings are relevant to human health because fish are a major dietary protein source, and understanding how plastics move through aquatic food chains helps us assess our own exposure risks.
Meta-analysis of the effects of microplastic on fish: Insights into growth, survival, reproduction, oxidative stress, and gut microbiota diversity
A meta-analysis of 3,757 biological endpoints from 85 studies found that microplastic exposure significantly inhibits fish growth, survival, and reproduction while increasing oxidative damage, but does not significantly alter gut microbiota diversity. The severity of toxic effects depends on microplastic type, size, concentration, exposure pathway, and the fish's life stage.
Toxicity of nanoplastics to aquatic organisms: Genotoxicity, cytotoxicity, individual level and beyond individual level
This review examines the toxic effects of nanoplastics on aquatic organisms across multiple levels of the food chain, from bacteria and algae to fish. Researchers found that nanoplastics can cause cell damage, genetic harm, and reproductive problems, with toxicity influenced by particle size, concentration, and surface properties. The study also highlights how nanoplastic effects on individual organisms can cascade to disrupt broader ecosystem dynamics.
Ecotoxicological effects of polystyrene nanoplastics on common carp: Insights into blood parameters, DNA damage, and gene expression
Exposing common carp to polystyrene nanoplastics caused significant DNA damage in blood and brain cells, along with changes in genes related to immune function and stress response. Higher concentrations led to more severe effects, and the nanoplastics also disrupted liver antioxidant defenses. Since carp are widely consumed fish, these findings raise questions about the safety of fish from nanoplastic-contaminated waters for human consumption.
Toxicological assessment of nanoparticles and microplastics
This review examines the toxicological effects of nanoparticles and microplastics on aquatic organisms, summarizing mechanisms of harm including oxidative stress, inflammatory responses, DNA damage, tissue injury, and neurological disruption in fish. It highlights that secondary nanoplastics formed from macro- and microplastic degradation are more heterogeneous than primary particles, and that combined exposure with chemical pollutants amplifies toxicity, including the capacity to cross the blood-brain barrier in fish.
The Potential for Toxicity to Fishes from Micro- and Nanoplastics, and Their Additives
This review examines the potential toxicity of micro- and nanoplastics and their chemical additives to freshwater and marine fish species. Evidence indicates that exposure to these particles may cause physical harm, oxidative stress, and disruption of normal biological functions in fish, with the diverse range of plastic sizes, shapes, polymer types, and associated chemicals making comprehensive risk assessment particularly challenging.
Ecotoxicological effects of emerging pollutants (nanomaterials and microplastics) on fish biology
This review compiles current knowledge on how emerging pollutants including nanomaterials and microplastics affect fish biology, covering impacts on physiology, behavior, and molecular function. Researchers highlight that advanced methods like genomics and micro-CT imaging are revealing new details about how these pollutants damage fish at the cellular and tissue level. The study underscores the growing threat these contaminants pose to aquatic ecosystems and the fish species within them.
Impacts of Polystyrene Nanoplastics on Fisheries Biology and Prospective Remediation Approaches in Aquatic Ecosystems
This review examines how polystyrene nanoplastics affect fish biology, including physiology, behavior, and reproductive health. The study highlights that nanoplastics cause oxidative stress, inflammation, endocrine disruption, and bioaccumulation in fish species, and that these effects can be amplified when nanoplastics interact with other environmental stressors such as pesticides and heavy metals.
Sub-chronic nanoplastic toxicity in Etroplus suratensis (Pisces, Cichilidae): Insights into tissue accumulation, stress and metabolic disruption
Researchers exposed pearl spot fish to polystyrene nanoplastics at different concentrations for 14 days and found that the particles accumulated in multiple organs with concentration-dependent distribution patterns. The nanoplastics caused elevated glucose and cholesterol levels, suppressed antioxidant defenses, and increased markers of oxidative damage and stress. Gene expression changes in stress response and growth-related genes suggest that nanoplastic exposure may impair both immune function and normal development in fish.
Nanoplastics are bioaccumulated in fish liver and muscle and cause DNA damage after a chronic exposure
Researchers chronically exposed fish to nanoplastics and, for the first time, quantified nanoplastic accumulation in liver and muscle tissue. They found that nanoplastics bioaccumulated in these organs and caused DNA damage in the exposed fish. The study provides important evidence that long-term nanoplastic exposure can lead to measurable tissue contamination and genetic harm in aquatic organisms.
Neurological effects induced by micro- and nanoplastics in fish: a systematic review and meta-analysis
This meta-analysis pooled data from 59 controlled studies and found that micro- and nanoplastics cause significant neurological effects in fish, including reduced brain antioxidant defenses and altered behavior. These findings are concerning because they suggest plastic pollution may disrupt nervous system function across species, and contaminated fish is a major part of the human diet.
Biotransport and toxic effects of micro- and nanoplastics in fish model and their potential risk to humans: A review
This review examines how micro- and nanoplastics enter fish through ingestion, inhalation, and skin contact, causing damage to multiple organ systems including the brain, heart, and reproductive organs. The particles trigger harmful cellular responses such as oxidative stress, DNA damage, and mitochondrial dysfunction. The study emphasizes that these pollutants can also reach humans through the food chain, highlighting the need for strategies to reduce plastic contamination in aquatic environments.
Effects of Virgin Micro- and Nanoplastics on Fish: Trends, Meta-Analysis, and Perspectives
This meta-analysis pools data from many studies on how micro- and nanoplastics affect fish, finding evidence of harmful effects on growth, reproduction, and behavior. Since fish are a major protein source for billions of people, understanding how plastic pollution affects fish health has direct implications for human nutrition and food safety.
Impacts of microplastic accumulation in aquatic environment: Physiological, eco-toxicological, immunological, and neurotoxic effects
This review summarizes how microplastics build up in fish and other aquatic life, causing damage to their immune systems, nervous systems, and overall health. When fish eat microplastics, the particles move up the food chain and can eventually reach humans through seafood consumption. The authors also discuss strategies for removing microplastics from water and reducing plastic pollution.
Toxic effects of microplastic and nanoplastic on the reproduction of teleost fish in aquatic environments
This review summarizes research on how microplastics and nanoplastics harm the reproductive systems of fish, covering effects on fertility, sperm quality, egg development, and offspring abnormalities. The tiny plastic particles enter fish through their digestive tract, gills, and skin, causing oxidative damage that disrupts reproduction at the molecular and cellular level. Since fish are a major protein source for humans, reproductive damage to fish populations could affect both food security and the transfer of microplastics through the food chain.
Effects of micro- and nanoplastics on aquatic ecosystems: Current research trends and perspectives
This review covers 83 studies on the distribution and toxic effects of micro- and nanoplastics in both marine and freshwater ecosystems worldwide. Researchers found that these tiny particles affected the growth, development, behavior, reproduction, and survival of a wide range of aquatic organisms. The paper identifies key research gaps and suggests future directions for understanding the full ecological impact of plastic pollution in aquatic environments.