A new model of vascular dementia reveals hidden disease processes and raises urgent questions about the role of microplastics in brain health
Vascular dementia, a form of cognitive decline caused by disease in the brain’s small blood vessels, is common but has been studied less intensively than Alzheimer’s disease, which is marked by abnormal plaques and protein tangles in neural tissue.
A University of New Mexico researcher aims to change that.
In a recent paper highlighted by the editors of the American Journal of Pathology, Elaine Bearer, MD, PhD, the Harvey Family Endowed and Distinguished Professor in the UNM School of Medicine’s Department of Pathology, introduces a framework to define and classify different types of vascular dementia.
She hopes the approach will help researchers better understand the disease’s variants and speed the development of effective treatments.
Multiple Risk Factors and New Concerns
Conditions like hypertension, atherosclerosis and diabetes have been linked to vascular dementia, but other contributing causes, including the recent discovery of significant quantities of nano– and microplastics in human brains, remain poorly understood, Bearer said.
“We have been flying blind,” she said. “The various vascular pathologies have not been comprehensively defined, so we haven’t known what we’re treating. And we didn’t know that nano– and microplastics were in the picture, because we couldn’t see them.”
Bearer identified 10 different disease processes that contribute to vascular-based brain injury, typically by causing oxygen or nutrient deficiency, leakage of blood serum, and inflammation or decreased waste elimination. These cause tiny strokes that harm neurons. She lists new and existing experimental techniques, including special stains and novel microscopy, to detect them.
For the paper, Bearer used a specialized microscope to meticulously study tissue from a repository of brains donated by the families of New Mexicans who had died with dementia, employing stains that highlighted the damaged blood vessels. Surprisingly, many patients diagnosed with Alzheimer’s disease also had disease in the small blood vessels of the brain.
“We suspect that in New Mexico maybe a half of our Alzheimer’s people also have vascular disease,” she said.
Bearer contends a methodical approach to identifying different forms of vascular dementia will help neurologists and neuropathologists more accurately score the severity of the disease in both living and deceased patients and advance the search for potential treatments — and even cures. To make that happen, the National Institutes of Health (NIH) has raised the possibility of forming a consensus group of leading neuropathologists to work out a new classification and scoring system, she said.
Meanwhile, a fresh area of concern is the unknown health consequences of nano– and microplastics in the brain, Bearer said.
“Nanoplastics in the brain represent a new player on the field of brain pathology,” she said. “All our current thinking about Alzheimer’s disease and other dementias needs to be revised in light of this discovery.”
“What I’m finding is that there’s a lot more plastics in demented people than in normal subjects,” she said. “It seems to correlate with the degree and type of dementia.”
The quantity of plastics also was associated with higher levels of inflammation, she said.
Bearer’s work builds on years of collaboration with Gary Rosenberg, MD, professor of Neurology and director of the UNM Alzheimer’s Disease Research Center (ADRC), which won a five-year $21.7 million NIH grant in 2024 that supported Bearer’s research. Rosenberg, a longtime chair of the UNM Department of Neurology and also director of the UNM Center for Memory & Aging, has published extensively on the association of vascular disease with dementia symptoms.
“When we started thinking about putting this ADRC together, I thought one of the things I should look at is the vasculature, because nobody’s done it systematically and comprehensively, and we have a world’s expert here at UNM,” Bearer said.
“Describing the pathological changes in this comprehensive way is really new. What I’m hoping will come out of this paper is working with other neuropathology ADRC cores across the country to develop consensus guidelines for classifying vascular changes and the impact of nano– and microplastics on the brain.”
Reference: “Exploring Vascular Contributions to Cognitive Impairment” by Elaine L. Bearer, 8 August 2025, The American Journal of Pathology.
DOI: 10.1016/j.ajpath.2025.07.007
Ya Libnan research:
Ya Libnan conducted a research on the above and here are the results
How Microplastics Enter the Human Brain
1. Through the lungs (inhalation)
When we breathe, especially in polluted cities or indoors with synthetic materials, we inhale microscopic plastic particles.
What happens next:
- These particles can travel deep into the lungs.
- The smallest ones (nanoplastics) can cross the lung–blood barrier.
- Once in the bloodstream, they circulate and can reach the brain.
2. Through the digestive system (eating and drinking)
We consume microplastics every day, mainly from:
- Bottled water
- Plastic food packaging
- Seafood
- Processed foods
- Household dust that falls on plates
What happens next:
- The tiniest particles can cross the gut lining into the bloodstream.
- From the bloodstream they travel to many organs, including the brain.
- 3. Crossing the blood–brain barrier
- The brain is usually protected by the blood–brain barrier (BBB), which blocks harmful substances.
- However, nanoplastics are so small that they can:
- Slip through weakened or inflamed BBB tissue
- Enter using “Trojan horse” mechanisms (hitchhiking on fats or proteins)
- Be taken up by immune cells that accidentally carry them inside
- Once past the BBB, microplastics may cause:
- Inflammation
- Oxidative stress
- Disruption of normal brain cell functions
- This is why recent studies have detected microplastics in:
- Human brain tissue
- The placenta
- Blood
- Lymph nodes
- Liver
4. Through the nose (olfactory nerve)
This is one of the most direct pathways.
When breathing in plastic dust:
- Some particles deposit on the inside of the nose.
- The olfactory nerve (responsible for smell) connects directly to the brain.
- Nanoplastics can travel along this nerve, bypassing the blood–brain barrier entirely.
This is the same pathway used by some viruses and chemicals.
5. Medical procedures (recent research)
New studies in 2024–2025 suggest:
- Microplastics in IV bags
- Plastic tubing
- Surgical devices
…may release particles that enter the bloodstream and eventually accumulate in organs, including the brain.