• Microplastics disrupt bone cell function — In laboratory studies, exposure to microplastics reduced cell viability, accelerated cell aging, and interfered with how stem cells in the bone marrow differentiate into specialized cells. These changes included promoting the formation of osteoclasts, the multinucleated cells that break down bone tissue through a process called bone resorption.

• Inflammation and oxidative stress drive damage — Microplastic exposure triggered inflammatory signaling and increased production of reactive oxygen species (ROS), which damage proteins, lipids, and DNA. This oxidative and inflammatory stress disturbed the normal equilibrium between bone formation and bone loss, undermining bone density and structural integrity.

• Animal studies confirm skeletal disruption — In animal experiments, microplastics were detected within bone tissue and bone marrow following exposure. The animals developed altered bone microstructures, including reduced growth and impaired trabecular formation, the lattice-like framework that provides strength and flexibility.

Some studies also reported disrupted gut microbiota and lowered white blood cell counts, suggesting a link between microplastic exposure, immune imbalance, and bone marrow dysfunction.

• Accelerated osteoclast aging leads to deformities — One of the researchers, Rodrigo Bueno de Oliveira, explained that in these studies, excessive osteoclast activity and premature aging of these cells led to bone deformities, dysplasia, and in some cases, halted skeletal growth.

Although the precise mechanical effects remain unclear, the evidence suggests that microplastics circulating in blood and bone marrow interfere with bone metabolism and regeneration.

• Researchers are now investigating microplastics’ role in the growing burden of bone disease — Using animal models, the team has set out to examine how microplastic exposure affects bone strength and integrity, focusing on the femur as a key site for assessing mechanical resilience.

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• Bloodstream — A 2022 study published in Environment International provided the first quantitative evidence that plastic particles circulate in the human bloodstream.⁷ Further analysis confirmed the presence of polyethylene and polypropylene — plastics commonly used in packaging and textiles — in human blood.⁸

These findings show that everyday environmental exposure is enough for plastic fragments to cross tissue barriers and reach systemic circulation. And once microplastics enter your body, they circulate freely and reach every organ and tissue.

• Brain — Microplastics have been identified in human brain tissue, confirming that these particles are capable of breaching the blood-brain barrier, which normally restricts the entry of foreign substances.⁹ A 2024 analysis of postmortem samples reported that the brain contained a higher concentration of polyethylene than other organs.¹⁰

The particles were nanosized, shard-like fragments embedded in neural tissue, blood vessel walls, and immune cells. The highest levels were observed in individuals diagnosed with dementia, suggesting a possible association between plastic accumulation and neurodegenerative disease.¹¹

• Placenta and breast milk — Microplastics have been detected in human placental tissue, marking one of the first confirmations of prenatal exposure. Fragments were found on both the maternal and fetal sides of the placenta, as well as in the amniotic membranes, showing that these particles can pass from a mother’s bloodstream into the fetal environment.¹²

They’ve also been identified in breast milk, indicating continued exposure after birth. The polymers detected are the same types commonly used in food packaging and household products, linking maternal diet and environmental contact to contamination of early life nourishment.¹³

These exposures occur during important stages of development, when organ systems, immune defenses, and metabolic control are still forming. At this stage, even small disruptions can affect growth, development, and long-term health.¹⁴

• Heart and arteries — In 2023, researchers in China examined samples collected during open-heart surgery and confirmed the presence of multiple types of microplastics within cardiac tissue and the pericardium (the membrane surrounding the heart). The most frequently detected polymers were polypropylene (PP), polyethylene terephthalate (PET), and polyvinyl chloride (PVC).¹⁵

Another study published in the New England Journal of Medicine found microplastics and nanoplastics embedded in atheromas, the fatty plaques that develop inside arteries and contribute to cardiovascular disease. Their presence was linked to greater inflammation in arterial walls and a higher risk of major cardiovascular events, including stroke, heart attack, and death.¹⁶

• Lungs, kidneys, and liver — Inhaled microplastics have been found in human lung tissue, embedded in the alveoli where gas exchange takes place. The thin membranes and constant airflow make the lungs especially vulnerable to particle buildup. Once lodged, these fragments can trigger inflammation and oxidative stress, damaging airway lining cells and impairing function over time.¹⁷

Microplastics also infiltrate the kidneys and liver as they’re filtered by the body’s detoxification and waste-removal systems. In the kidneys, they may interfere with filtration processes and burden renal tissue with oxidative stress. In the liver, where toxins are metabolized, their presence could disrupt enzyme activity, lipid metabolism, and bile secretion.¹⁸

• Testicles and sperm — Microplastics have been found in human testicular tissue and sperm, confirming their ability to cross the blood-testis barrier, a highly selective barrier meant to protect developing sperm from harmful substances.

Once inside, they may disrupt the function of Sertoli and Leydig cells, which are essential for sperm maturation and testosterone synthesis. Research suggests that continued exposure could lower sperm count, alter sperm shape and mobility, and interfere with hormonal balance, raising concerns about long-term effects on male fertility.¹⁹

• Because of their minute size, they dominate the air you breathe — UFPs account for over 90% of airborne particles even though they contribute little to total mass.²¹ Urban air typically contains 10,000 to 14,000 UFPs per cubic centimeter, with concentrations near highways spiking to 160,000 particles in the same volume of air. With every breath, you inhale thousands to hundreds of thousands of these particles.

• Exposure far exceeds that of microplastics — Total yearly exposure to microplastics and nanoplastics through air and food ranges from 39,000 to 121,000 particles.^22,23 In contrast, UFP exposure occurs continuously and at levels millions to billions of times higher. Over a single year, this amounts to trillions of particle contacts with the lungs and bloodstream.

• Microplastics and nanoplastics share mechanisms but differ in scale — Nanoplastics overlap in size with UFPs and can cross biological barriers such as the placenta and blood-brain barrier. However, their exposure levels are far lower, and their accumulation is slower. UFPs cause far greater total body burden because they are inhaled constantly and in enormous numbers.

• UFPs penetrate deeper and persist longer — Because they are smaller than 100 nanometers, UFPs reach deep into the alveoli of the lungs, cross into circulation, and spread throughout the body. Once inside, they are not easily removed and linger longer than larger fine particles. Their vast surface area relative to mass allows them to carry and release toxic chemicals and metals that generate reactive oxygen species.

• Health evidence is strongest for UFPs — The oxidative stress triggered by UFPs sets off widespread inflammation, weakens blood vessel linings, and alters coagulation, increasing the risk of hypertension and cardiovascular disease.²⁴ The relationship between UFP exposure and vascular damage is well documented in air pollution research, whereas evidence for micro- and nanoplastics is still emerging.

• Overlap amplifies toxicity — Nanoplastics that fall within the ultrafine range interact with combustion particles in air or inside the body. This overlap could intensify toxicity, since both serve as carriers for environmental chemicals and enhance oxidative stress responses.

• Regulation lags far behind risk — Despite their abundance and clear health effects, UFPs remain largely unregulated. Air quality standards typically address PM2.5 and PM10, which exclude ultrafine particles entirely. This gap leaves the most numerous and reactive pollutants unmonitored.

• Cross-linked psyllium could aid in the removal of microplastics — The gut is one of the body’s main routes for eliminating ingested particles. In 2024, researchers found that acrylamide cross-linked psyllium (PLP-AM) was able to extract more than 92% of common plastics, including polystyrene, PVC, and PET, from water.

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• Chitosan, a natural fiber sourced from shellfish, may also help your body clear microplastics — In a recent animal study published in Scientific Reports, rats fed a chitosan-enriched diet excreted about 115% of the polyethylene microplastics they were given, compared to 84% in the control group.

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• Certain probiotic strains help in clearing microplastics from the gut — In a 2025 animal study, two strains, Lacticaseibacillus paracasei DT66 and Lactiplantibacillus plantarum DT88, were shown to bind to and remove small polystyrene particles in laboratory experiments.²⁷

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• The liver also plays a vital role in removing microplastics from circulation — Specialized immune cells known as Kupffer cells capture these foreign particles and direct them into bile, allowing elimination through the intestines. However, while this process is effective for smaller particles, larger ones linger and accumulate, especially when liver function is impaired.

To enhance this natural detoxification pathway, researchers are investigating compounds such as ursodeoxycholic acid (UDCA) and its derivative tauroursodeoxycholic acid (TUDCA), which increase bile flow and improve the movement of trapped particles out of the liver.

• Researchers are also exploring ways to enhance autophagy to eliminate microplastics — Autophagy is your body’s built-in cellular recycling system. Two compounds, rapamycin and spermidine, have received particular attention for their ability to stimulate this pathway.

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Via https://articles.mercola.com/sites/articles/archive/2025/12/24/microplastics-and-bone-health.aspx