Microplastics Found in US Brains: What's the Risk?

Plastic traces were discovered in the brains of 54 individuals in the United States. However, specialists indicate that not enough information exists regarding the health impacts or prevalence of microplastics within the brain.

A recent study has revealed that micro- and nanoplastics detected in human brains and livers have risen from 2016 to 2024.

The study, published in Nature Medicine, Discovered that brain tissue taken from human corpses in 2016 had significantly greater amounts of plastic particles compared to both liver and kidney samples.

Micro and nanoplastics are minuscule — usually measuring around 200 nanometers in length, and significantly smaller than a human cell.

An analysis performed on cadavers from 2024 found even higher amounts in brain and liver tissues compared to 2016.

"We hypothesize that most of these plastics are not from recent exposure, but are extremely old degradation products. [This] highlights the need for more comprehensive strategies encompassing environmental policy and human health," study author Marcus Garcia at the University of New Mexico, US, told .

However, there is "as yet no strong evidence of any health effects [of nanoplastics in the brain]," said Oliver Jones, an expert in biological chemistry at the University of Melbourne, Australia, who was not involved in the study.

"The authors only [tested] 52 samples in total. There is not enough data to make firm conclusions on the occurrence of microplastics in New Mexico, let alone globally," Jones said.

Researchers are unclear about how microplastics negatively impact brain health.

Plastics inundate our planet — found in households, the very air we inhale, the meals we consume, and the containers we use for drinking.

Microplastics are bits of broken-down plastic. Most often, the Plastics get into our bodies via consumption or breathing. They have been present in human organs for many years, however, their impact on health is only now starting to be recorded.

Some findings suggest that the buildup of microplastics, particularly within vital organs such as the liver, may disrupt typical physiological processes.

The data from the research also revealed that the concentration of microplastics was greater in the brains of 12 individuals suffering from dementia.

The authors, however, state that this connection is merely correlational and does not establish that microplastics lead to dementia. Further investigation is necessary to determine whether, or in what manner, the buildup of microplastics in the brain adversely affects health—similarly to the way more research is required for the rest of the body.

"Concrete proof connecting the buildup of microplastics to particular human illnesses or health effects is not yet available," Garcia stated.

Determining a cause-and-effect link with dementia would necessitate comprehensive studies to discern whether or how microplastics play a role in the onset or advancement of such neurologic disorders.

Research might exaggerate the buildup of microplastics.

Jones likewise advised being cautious when drawing conclusions from the findings of the research.

He mentioned that it's not feasible to generalize the findings from this limited study to populations worldwide. The research might have exaggerated the levels of microplastics found in the brain tissues of the deceased individuals as well.

Jones additionally mentioned that the primary analytical technique employed to quantify plastics tends to produce inaccurate outcomes since “fats [a major component of the brain] yield identical compounds as polyethylene [the predominant type of plastic reportedly found],” and he raised doubts about potential plastic contamination originating either from the lab or during the initial autopsy process.

" Plastic pollution can be found virtually anywhere. ", how can we ensure that any detected particles truly indicate that plastics are penetrating membranes within the human body, rather than being mere contaminants?" Jones stated.

In what ways can microplastics enter or exit the brain?

The researchers suggest that their study introduces new queries regarding the possible effects of microplastics on brain health and whether these particles can be eliminated.

"The primary question revolves around comprehending the processes responsible for microplastic buildup in the brain — how these particles infiltrate it and which biological pathways they engage," explained Garcia.

Scientists have not yet determined whether our bodies can naturally eliminate microplastics from the brain and other organs. Additionally, it remains uncertain if there are processes that could assist in breaking down these microplastics within the body.

"Definitely, additional research would be necessary to determine whether this is feasible at all. It remains unclear if microplastics or any other particles could persist within the brain or if they might be eliminated by the body. Once again, further investigation would be required to explore this," stated Jones.

Edited by: Matthew Ward Agius

Primary source:

Accumulation of Microplastics in Deceased Individuals' Brains, Nature Medicine, February 2025 https://www.nature.com/articles/s41591-024-03453-1

Author: Fred Schwaller

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Ancient Creatures Show Alarming Behavior: Scientists Warn of Potential Dangers

Small sea organisms are delivering a critical warning about the heating oceans, and we should pay attention, as indicated by a recent study conducted in collaboration with the Max Planck Institute for Chemistry .

What's happening?

The ocean's planktonic foraminifera Microscopic creatures encased in calcareous shells are finding it difficult to endure due to the changing conditions. waters heat up and become more acidic.

A recent study published in the journal Nature examined nearly 200,000 data sets ranging from 1910 to monitor how these creatures adapt to shifting marine environments. The results reveal a troubling trend: their numbers have decreased by 25% over the past eight decades.

The information we have indicates that planktonic foraminifera, essential components of the ocean's carbon cycle, are finding it difficult to endure as the climate changes at an accelerated pace, said Sonia Chaabane, the lead researcher from the European Centre for Research and Teaching in Environmental Geosciences and the Max Planck Institute for Chemistry, stated, "These creatures act as sentinels, signaling severe impacts caused by rising temperatures and ocean acidification on marine environments."

These little animals are doing everything they can to stay alive. Many species are moving toward cooler waters near the poles at speeds up to 10 kilometers per year. Others are swimming deeper into the ocean to escape rising surface temperatures.

However, these survival tactics may prove insufficient. Various experts caution that numerous species might encounter circumstances too extreme for them to endure by the year 2100.

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What makes planktonic foraminifera so significant?

These seafood items act as preliminary indicators of larger concerns regarding the overall condition of the oceans.

These organisms significantly contribute to carbon dioxide storage; upon their death, their shells descend to the seafloor, effectively extracting CO2 from seawater. However, ocean acidification complicates their ability to construct these protective coverings, thus disrupting this natural mechanism for carbon capture.

The most significant declines are occurring in tropical regions, where severe heating interferes with their reproductive capabilities. This poses problems not only for the foraminifera but also for all marine creatures that rely on them.

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How can we contribute to assist?

Choosing wise energy consumption practices and endorsing clean energy sources can aid in reducing the pace of ocean warming and acidification.

Basic toggles like utilizing energy-efficient appliances , choosing public transportation and reducing unnecessary consumption All these elements combine to create an impact on ocean health.

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Researchers voice worries following alarming actions displayed by prehistoric beings: 'Acting as sentinels, cautioning us.' first appeared on The Cool Down .

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How to Prevent Microplastics from Entering Your Body: Experts Share Vital Tips

Plastic fragments are ubiquitous—found in natural environments as well as within the human body. As three scientists articulate in the journal Brain Medicine, microplastics permeate the food we consume, the water we drink, and even the air we inhale. commentary on several previous studies.

They highlight potential risks – however, their main focus is explaining ways to decrease exposure to these particles: steer clear of plastic bottles, opt for ceramic containers when microwaving food, and choose plastic-free teabags instead.

A recent study conducted by another team discovered substantially greater amounts of microscopic plastic particles in liver and brain tissue samples taken posthumously from individuals in 2024 compared to those collected back in 2016. The researchers, headed by Matthew Campen at the University of New Mexico, noted that these plastics were most concentrated in the brains as opposed to the livers or kidneys. This finding was published in February in the scientific journal Nature Medicine.

The significant rise in plastic concentration in the brain over merely eight years is deeply concerning, stated Nicholas Fabiano, the lead commentator from the University of Ottawa.

Small plastic fragments in the brain

Especially tiny particles were identified within the brain, with sizes under 0.2 micrometres. These primarily comprised polyethylene, a material common in various daily use items.

Because of their minuscule dimensions, they have the ability to penetrate what is known as the blood-brain barrier; however, the consequences of this remain uncertain.

Microplastics consist of particles ranging from 1 micrometer (0.001 millimeter) to 5 millimeters in size. Particles that are even tinier fall into the category of nanoplastics.

The three scientists clarify that each individual has the ability to decrease their consumption of nano- and microplastics.

• According to the researchers, if a person consumes solely bottled water, they may ingest over 20 times more microplastics compared to someone who exclusively drinks tap water, citing previous findings. study Even water from glass bottles contains more plastic particles than tap water, according to researchers who report this in their study. analysis Of the 21 studies, this might be due to the bottling process, amongst other factors.

• An additional source of micro- and nanoplastics is plastic tea bags According to the analysis by these three researchers, steeping a plastic teabag at 95 degrees Celsius might result in substantial amounts of plastic leaching out. Consider choosing brands that do not utilize plastic teabags or opt for using loose-leaf tea instead.

・Avoiding plastic food containers Heating food in plastic containers—particularly in the microwave—may lead to significant releases of micro- and nanoparticles, cautions co-commentator Brandon Luu from the University of Toronto.

According to the researchers, even storing something for a long time at room temperature or in the fridge can result in a considerable discharge of particles.

"Luu suggests that opting for glass or stainless-steel containers over plastic can be a minor yet important step in reducing exposure." She adds that food stored in cans might include compounds derived from plastics like Bisphenol-A (BPA).

In one study During the experiment, participants consumed canned soup for five consecutive days, resulting in a significant increase in their urinary BPA levels. However, the team of researchers points out: "The extent and health effects of these increases in BPA levels are still unknown and require additional investigation."

Another US study has demonstrated that highly processed foods have considerably higher levels of microplastics compared to minimally processed foods.

The group observes at least one encouraging outcome: "Among the most promising elements of the discoveries made so far is the absence of a link between age and the buildup of microplastics."

This implies that even with continuous exposure to environmental elements, the body possesses processes to eliminate these substances gradually via perspiration, urine, and feces.

Several potential outcomes for the body

The commentators mention that evidence from cell cultures and animal studies suggests plastic particles might lead to inflammation, immune system disruptions, changes in metabolic processes, irregular organ growth, and increased risk of cancer. Nonetheless, the body of research remains somewhat constrained.

Extensive human trials are necessary to assess the potential health hazards associated with microplastics. Concurrently, additional investigations should be conducted to more accurately gauge the efficacy of different mitigation approaches.

Only a limited number of studies have explored the impact of microplastics on the brain. Campen’s group found higher concentrations in another dozen brain samples taken from individuals diagnosed with dementia. Nonetheless, the scientists noted that this research doesn’t establish a clear causal link.

The three writers suggest it's possible that dementia can compromise the integrity of the blood-brain barrier, thereby enabling greater ingress of microplastics.

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Alien Hunt Gets Easier: New Oxygen Reaction Discovery Could Be Key

'Just as oxygen is essential for the lungs, hope is vital to giving purpose to one’s life.'

This quote comes from the book "Eternal Hope" written by Emil Brunner, who was a Swiss theologian.

The man actually intended to convey that oxygen is the key to discovering life outside of our planet.

Oxygen is considered essential for life on Earth because it is primarily generated by living organisms.

However, researchers have found a novel method for oxygen to develop in planetary atmospheres dense with carbon dioxide, eliminating the requirement for living organisms.

Researchers told Space.com How they searched for innovative methods to generate molecular oxygen by colliding CO2 with helium.

This method of producing oxygen is termed an 'abiotic' process, which means it does not entail living organisms.

The enrichment of Earth’s atmosphere with oxygen, occurring approximately between 2.1 to 2.4 billion years ago, remains one of the greatest enigmas in history. Prior to this event, which geologists refer to as the Great Oxidation Event, much of our planet was enveloped in the pungent greenhouse gas CO2.

The presence of oxygen became noticeable in the atmosphere once ancient marine microorganisms developed the capability for photosynthesis. Following their exposure to sunlight, these organisms released oxygen into the environment.

Much of this oxygen did not persist for an extended period. Given the numerous volcanoes active back then, hydrogen likely consumed most of it.

However, after several hundreds of millions of years, as the Earth started to cool down, it provided an opportunity for our unusually oxygen-abundant atmosphere to develop.

Shan Xi Tian and Jie Hu from the University of Science and Technology of China chose to investigate how helium produced through interactions between solar winds and a planet's atmosphere might generate oxygen.

In this process, helium forms ions—charged particles that behave akin to wrecking balls, colliding with CO2 and causing it to smash into other molecules.

'This phenomenon can be observed in Mars' upper atmosphere as it contains numerous He+ ions (from solar winds) along with CO2,' explained Hu.

However, despite the formation of O+, O2+, and CO2+, O2 does not appear, at least not on Mars.

Tian and Hu employed three methods from their toolkit to put their concept to the test.

The initial method is time-of-flight (TOF) mass spectrometry, where particles become ions and are accelerated to achieve equal kinetic energy. The duration taken for them to cover the same distance is utilized to determine their mass.

The duo utilized a 'crossed-beam apparatus' for colliding two molecules, along with 'ion velocity maps' to document the paths and speeds of the resulting ions.

'We discovered a significantly different mechanism for producing O2 from molecular CO2,' Tian stated. 'Specifically, via the interaction between helium ions [He+] and CO2.'

To put it simply, Tian and Hu’s research discovered that life-supporting oxygen might develop on planets with CO2-heavy atmospheres before any living organisms have appeared there.

David Benoit, who serves as a senior lecturer in Molecular Physics and Astrochemistry at the University of Hull’s EA Milne Centre for Astrophysics, now indicates that the quest is underway to locate planets where this might plausibly occur.

'This innovative mechanism is expected to be included in upcoming models designed to forecast the atmospheres of other planets,' Benoit stated to Space.com. 'It will assist us in more accurately explaining the levels of oxygen we may discover.'

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Magnetic Meltdown: Could the Earth's Field Reverse in Our Lifetimes?

The Unmatched Pace of Previous Reversals

Research conducted by geophysicists from UC Berkeley alongside their counterparts from Italy and France has illuminated details about Earth’s most recent significant magnetic field reversal. This event took place approximately 786,000 years ago and was remarkably swift, completing within just one hundred years or even quicker.

Earlier, researchers thought these reversals occurred over millennia. Courtney Sprain, a UC Berkeley doctoral student, commented, "The paleomagnetic data have been executed very well."

Possible Effects of an Abrupt Reversal

Although previous reversals of the Earth’s magnetic field haven’t been associated with any major disasters, a rapid change could pose considerable consequences for us nowadays. Our planet’s magnetic shield plays a crucial role in protecting living organisms from dangerous solar and cosmic rays.

Weakening of this field might boost genetic mutations, possibly increasing cancer occurrences. Furthermore, should a reversal occur, it could disturb the electricity supply network, resulting in extensive blackouts.

Paul Renne, who directs the Berkeley Geochronology Center, pointed out, "We ought to consider more closely what biological impacts might occur."

The Function of Old Lake Deposits

The latest discoveries stem from the magnetic orientation observed in old lake deposits located within Italy’s Sulmona basin. These sedimentary layers, interspersed with volcanic ash strata, offer a detailed chronology of historical shifts in magnetism.

Using argon-argon dating of the ash layers, scientists narrowed down the reversal to around 786,000 years ago. This new timeline is more precise compared to earlier estimations, which differed by up to 25,000 years.

Grasping the Process of Magnetic Reversal

The magnetic data shows that the abrupt 180-degree reversal was foreshadowed by an unstable period spanning more than 6,000 years. During this time, there were two instances of diminished magnetic field intensity.

These variations indicate that swift shifts in the direction of the field might have taken place during those periods. Grasping these trends could assist researchers in forecasting upcoming reversals and their possible consequences.

Cooperative Initiatives in Magnetism Studies

Led by Leonardo Sagnotti from Rome’s National Institute of Geophysics and Volcanology, the research team adopted a cooperative methodology. Combining paleomagnetic analysis with sophisticated dating methods, they attained pioneering findings.

The partnership among Italian, French, and American researchers underscores the significance of global teamwork in scientific investigations.

Implications for Modern Civilization

Although it remains unclear if an upcoming geomagnetic reversal could occur as swiftly as the previous one, this prospect prompts numerous queries for contemporary civilization. Given our heavy dependence on electronic gadgets and power systems, we find ourselves particularly susceptible to disruptions caused by changes in magnetism.

Gaining insight into how these reversals occur is essential for getting ready to face possible difficulties.

Future Research Directions

Paul Renne and his colleagues are further investigating the connection between magnetic field reversals and climatic shifts. Through synchronizing lake sediment archives with weather statistics, their objective is to reveal fresh perspectives on our planet’s magnetic past.

This continuing study might offer crucial data for forecasting upcoming magnetic trends.

Conclusion

Studying Earth’s magnetic field and the possibility of it flipping during a person’s lifetime provides an intriguing look at our planet's ever-changing past. As researchers keep decoding the enigmas surrounding these reversals, their discoveries might greatly impact our comprehension of what lies ahead for Earth.

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