We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
The Effects of Nanoplastics on the Dopamine System of Cerebrocortical Neurons
Summary
Researchers studied how nanoplastics affect the dopamine system in brain neurons grown in the lab. They found that nanoplastics accumulated inside neurons in a dose-dependent manner and altered the levels of proteins involved in dopamine signaling. These results suggest that nanoplastic exposure could potentially interfere with brain chemistry, though more research is needed to understand what this means for human health.
Nanoplastics (NPx) can enter living organisms, including humans, through ecosystems, inhalation, and dermal contact and can be found from the intestine to the brain. However, it is unclear whether NPx accumulates and affects the dopamine system. In this study, we investigated the effects of NPx on the dopamine system in cultured murine cerebral cortex neurons. Cultured cerebrocortical neurons were treated with 100 nm NPx at the following concentrations for 24 h: 1.896 × 105, 3.791 × 106, 7.583 × 107, 1.571 × 109, 3.033 × 1010, and 3.033 × 1011 particles/mL. Dopamine-associated proteins were analyzed using immunofluorescence staining. NPx treatment induced its accumulation in neurons in a dose-dependent manner and increased the levels of dopamine receptors D1 and D2 and their co-expression. However, NPx treatment did not affect the levels of other dopamine receptors, dopamine transporters, tyrosine hydroxylase, and microtubule-associated protein 2, or synaptophysin in neuronal structures. This study demonstrated that NPx is a potential modulator of the dopamine system via its receptors rather than its synthesis and reuptake in neurons and may be associated with dopamine-based psychiatric disorders.
Sign in to start a discussion.
More Papers Like This
Direct Quantification of Nanoplastics Neurotoxicity by Single‐Vesicle Electrochemistry
Using single-vesicle electrochemistry, this study provides the first direct measurement of how nanoplastics disrupt neurotransmitter release at the level of individual nerve cells. Polystyrene nanoplastics taken up by neurons disrupted the cellular machinery controlling how vesicles fuse and release catecholamines (like dopamine and norepinephrine), reducing both the amount of neurotransmitter released and the frequency of release events. These findings are concerning because they suggest nanoplastic exposure could interfere with normal brain signaling at concentrations that don't immediately kill 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.
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.
Direct Quantification of Nanoplastics Neurotoxicity by Single‐Vesicle Electrochemistry
Using a precise electrochemical technique to measure individual brain cell vesicles, researchers provided the first direct evidence that nanoplastics disrupt how neurons store and release chemical messengers. Nanoplastic exposure reduced the amount of neurotransmitters in cell vesicles and impaired the process of releasing them during signaling. The study offers a detailed molecular-level look at how nanoplastics may interfere with brain cell communication.
Effect of nanoplastic intake on the dopamine system during the development of male mice
Male mice exposed to nanoplastics during specific developmental windows, particularly late pregnancy and adulthood, showed disrupted dopamine signaling in the brain and reduced social behavior. The nanoplastics altered brain activity in regions controlling reward, decision-making, and social interaction. This study suggests that nanoplastic exposure during critical periods of brain development could affect cognitive and social function, raising concerns about the impact on human brain health.