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61,005 resultsShowing papers similar to The plastic brain part II: new insights into micro- and nanoplastics neurotoxicity
ClearA systematic review of the potential neurotoxicity of micro-and nanoplastics: the known and unknown
This critical review of 234 studies found that micro- and nanoplastics can reach the brain via olfactory translocation or by crossing the blood-brain barrier, where they may cause neuroinflammation, oxidative damage, and behavioral changes in animal models. The evidence raises significant concerns about potential neurotoxic effects of chronic microplastic exposure in humans, though major knowledge gaps remain.
Insights into the toxic effects of micro-nano-plastics on the human brain and their relationship with the onset of neurological diseases: A narrative review.
This review examined toxic effects of micro and nano-plastics (MNPs) on the human brain, linking MNP exposure to neuroinflammation, oxidative stress, disruption of the blood-brain barrier, and progression toward neurodegenerative diseases. The authors synthesized evidence from cell studies, animal models, and emerging human data.
The neurotoxic threat of micro- and nanoplastics: evidence from In Vitro and In Vivo models
This systematic review examined 26 studies showing that micro- and nanoplastics can cross into the brain, damage neurons, and trigger inflammation in lab and animal models. These findings raise concerns that long-term plastic exposure could contribute to neurological problems in humans, though more research is needed.
Neurotoxicityof Micro- and Nanoplastics: A ComprehensiveReview of Central Nervous System Impacts
This comprehensive review examines neurotoxicity of micro- and nanoplastics, synthesizing evidence that MNP exposure disrupts neural signaling, promotes neuroinflammation, crosses the blood-brain barrier, and may contribute to neurodegenerative and neurodevelopmental disorders.
Deciphering the Neurotoxic Burden of Micro- and Nanoplastics: From Multi-model Experimental Evidence to Therapeutic Innovation
This review summarizes research on how micro- and nanoplastics damage the brain and nervous system, covering evidence from cell studies, animal experiments, and clinical observations. Plastic particles can cross the blood-brain barrier, disrupt the gut-brain connection, cause oxidative stress, and trigger inflammation that leads to memory problems and cognitive decline. The review also discusses potential treatment strategies, making it a useful resource for understanding the brain health risks of plastic exposure.
A systematic review of the potential neurotoxicity of micro-and nanoplastics: the known and unknown
This systematic review summarizes 234 research studies on how micro- and nanoplastics may harm the brain and nervous system. Evidence from animal and lab studies suggests these particles can reach the brain through the nose or by crossing the blood-brain barrier, potentially causing inflammation, oxidative stress, and nerve cell damage.
Brain under siege: the role of micro and nanoplastics in neuroinflammation and oxidative stress
This review examines emerging evidence that micro- and nanoplastics can cross the blood-brain barrier and accumulate in nervous tissue, potentially triggering neuroinflammation and oxidative stress. Researchers summarized findings showing these particles may act as neurotoxicants that contribute to synaptic dysfunction and pathological changes in brain cells. The study highlights the need for further research into how chronic plastic particle exposure may affect central nervous system health over time.
Elucidating the Neurotoxicopathological Impact of Micro and Nanoplastics: Mechanistic Insights Into Oxidative Stress-mediated Neurodegeneration and Implications for Public Health in a Plastic Pervasive Era
Researchers reviewed the growing evidence linking micro- and nanoplastic exposure to neurodegenerative diseases, identifying oxidative stress, neuroinflammation, DNA damage, and protein misfolding as key mechanisms of harm to the brain. The review highlights critical knowledge gaps — especially around chronic low-dose exposure — and calls for better detection tools and public health policies to address the emerging neurological threat from plastic pollution.
Micro-nanoplastics in the central nervous system: Evidence, mechanisms and perspectives
This review examines evidence that micro- and nanoplastics can cross the blood-brain barrier and cause neurotoxicity through oxidative stress, neuroinflammation, and disruption of neurotransmitter signaling. While clinical studies have confirmed the presence of plastic particles in human brain tissue and cerebrospinal fluid, the authors note that methodological limitations and inconsistent quality controls currently prevent establishing a definitive causal link to neurological conditions.
The plastic brain: neurotoxicity of micro- and nanoplastics
This review examines the emerging evidence that micro- and nanoplastics can reach the brain in both aquatic animals and mammals, potentially causing neurotoxic effects. Researchers found that exposure to these particles induces oxidative stress, inhibits key enzymes involved in nerve signaling, and alters neurotransmitter levels, which may contribute to behavioral changes. The study highlights that systematic research comparing different particle types, sizes, and exposure conditions is urgently needed to understand the neurological risks.
A systematic review of the potential neurotoxicity of micro-and nanoplastics: the known and unknown
This systematic review summarizes 234 research studies on how micro- and nanoplastics may harm the brain and nervous system. Evidence from animal and lab studies suggests these particles can reach the brain, potentially through the nose or by crossing the blood-brain barrier, and may cause inflammation and damage to nerve cells.
The effects of micro- and nanoplastics on the central nervous system: A new threat to humanity?
This review summarizes growing evidence that micro- and nanoplastics can cross the blood-brain barrier and damage the central nervous system through inflammation, oxidative stress, and disruption of brain chemicals. The authors note that microplastic exposure has been linked to memory and behavior changes in animals and may contribute to neurodegenerative diseases like Parkinson's, though direct human evidence is still limited.
Micro- and nanoplastics in neurological dysfunction
This review examines growing evidence that micro- and nanoplastic particles can interfere with the nervous system across multiple species, including humans. Researchers found that plastic particles may disrupt cellular metabolism, affect brain development, and increase vulnerability to neurodevelopmental disorders and neurodegeneration. The authors highlight significant knowledge gaps that need to be addressed to understand the long-term neurological impacts of plastic particle exposure.
Neurotoxicity of nanoplastics: A review
This review examines the growing body of evidence on how nanoplastics may affect the nervous system. Researchers summarized findings showing that nanoplastics can cross biological barriers, accumulate in brain tissue, and trigger oxidative stress and inflammation in nerve cells. The evidence indicates that nanoplastic exposure may contribute to neurotoxic effects, though more research is needed to fully understand the risks to human brain health.
Neurotoxicities induced by micro/nanoplastics: A review focusing on the risks of neurological diseases
This review summarizes evidence that micro- and nanoplastics can reach the brain through the bloodstream and nerve pathways, where they trigger oxidative stress, inflammation, and cell damage that may contribute to neurodegenerative diseases. The particles are found in air, water, soil, and food, meaning humans are constantly exposed through breathing, eating, and skin contact, making brain effects a serious long-term concern.
From exposure to neurotoxicity induced by micro-nanoplastics with brain accumulation and cognitive decline
This review synthesizes evidence that micro- and nanoplastics can reach the brain by crossing the blood-brain barrier or traveling along nerve pathways, accumulating in regions critical for memory and thinking. Animal studies show that chronic exposure leads to cognitive problems, behavioral changes, and brain changes resembling neurodegenerative diseases, driven by oxidative stress, inflammation, and disruption of the gut-brain connection. The findings raise concern that long-term human exposure to nanoplastics through food and air could contribute to cognitive decline and neurological disease.
Microplastics/nanoplastics and neurological health: An overview of neurological defects and mechanisms
This review summarizes evidence that micro and nanoplastics can harm the nervous system, causing developmental abnormalities, brain cell death, neurological inflammation, and potentially contributing to neurodegenerative diseases. Animal studies show that these tiny plastics can cross the blood-brain barrier and accumulate in brain tissue, where they trigger oxidative stress and disrupt normal brain function. While direct evidence in humans is still limited, the findings suggest that chronic microplastic exposure could be a risk factor for neurological health problems.
Neurotoxicity of microplastic particles in the human brain: a systematic review
This systematic review examines how microplastic particles may affect the human brain and nervous system. The research found that microplastics can reach the brain and cause changes in behavior and thinking, though more studies are needed to understand the long-term effects. This is an early but important signal that plastic pollution could impact brain health.
Micro- and Nanoplastics in the Brain: A Scoping Review Protocol on Their Presence, Neurotoxic Effects, and Implications for Human Health
This scoping review protocol outlines a systematic approach to mapping scientific evidence on the presence of micro- and nanoplastics in the brain, their neurotoxic effects, and potential implications for human health. The review will chart findings from both human studies and experimental models to identify key mechanisms, affected brain regions, and knowledge gaps in this emerging field.
Micro- and Nanoplastics in the Brain: A Scoping Review Protocol on Their Presence, Neurotoxic Effects, and Implications for Human Health
This scoping review protocol maps scientific evidence on the presence of micro- and nanoplastics in the brain, their neurotoxic effects, and implications for human health, drawing from both human studies and experimental models. The protocol follows JBI methodology to systematically chart available evidence.
Additional file 1 of A systematic review of the potential neurotoxicity of micro-and nanoplastics: the known and unknown
This is supplementary data supporting a systematic review on the potential brain and nerve damage caused by micro- and nanoplastics. The main study analyzed 234 research articles and found concerning evidence of neurotoxic effects from plastic particle exposure.
Additional file 1 of A systematic review of the potential neurotoxicity of micro-and nanoplastics: the known and unknown
This is supplementary data supporting a systematic review on the potential brain and nerve damage caused by micro- and nanoplastics. The main study analyzed 234 research articles and found concerning evidence of neurotoxic effects from plastic particle exposure.
From environment to brain: the role of microplastics in neurobehavioral disorders
This review examines how microplastics enter the human body and cross the blood-brain barrier, linking their presence in neural tissue to neurobehavioral disorders through mechanisms including neuroinflammation, oxidative stress, and disruption of neurotransmitter systems.
Additional file 2 of A systematic review of the potential neurotoxicity of micro-and nanoplastics: the known and unknown
This is supplementary data supporting a systematic review on the potential brain and nerve damage caused by micro- and nanoplastics. The main study found evidence that these particles may reach the brain and cause neurotoxic effects in animal models.