An international team of researchers has
reported a striking Alzheimer's breakthrough in mice using specially
engineered nanoparticles that do much more than deliver medicine. These
microscopic particles act as drugs themselves, helping the brain restore
its own natural cleaning system and dramatically reducing toxic protein
buildup linked to Alzheimer's disease.
The work was led by scientists from
the Institute for Bioengineering of Catalonia (IBEC) and West China
Hospital Sichuan University (WCHSU), together with collaborators in the
United Kingdom. Their findings were published in Signal Transduction and Targeted Therapy.
Instead of focusing directly on damaged neurons, the scientists
targeted the blood-brain barrier (BBB), a protective network of cells
and blood vessels that controls what enters and leaves the brain. In
Alzheimer's disease, this system gradually breaks down, allowing harmful
proteins to accumulate and damaging brain function over time.
The researchers designed bioactive nanoparticles called
"supramolecular drugs" to help restore this barrier and restart the
brain's ability to remove waste.
Repairing the Brain's Cleanup System
The human brain uses enormous amounts of energy. In adults, it
consumes around 20% of the body's total energy supply, and in children
the figure can reach 60%. To meet those demands, the brain depends on an
extremely dense network of blood vessels. Scientists estimate the brain
contains roughly one billion capillaries, with nearly every neuron
connected to its own blood supply.
Growing evidence suggests these blood vessels play a far larger role
in dementia than previously thought. Many researchers now believe
vascular damage is not simply a side effect of Alzheimer's disease but
may actively drive its progression. Recent studies have also linked
blood-brain barrier breakdown to early cognitive decline and increased
buildup of toxic proteins.
Under healthy conditions, the blood-brain barrier helps clear waste
products from the brain while blocking harmful substances such as toxins
and pathogens. One of the most important waste proteins is amyloid-β
(Aβ), the sticky material that forms plaques associated with Alzheimer's
disease.
In Alzheimer's patients, the brain's waste disposal system begins to
fail. As amyloid-β accumulates, neurons become damaged and memory
problems worsen.
Alzheimer's Plaques Dropped Within Hours
To test the new therapy, researchers used genetically engineered mice
that develop high levels of amyloid-β and progressive cognitive decline
similar to Alzheimer's disease in humans.
The animals received only 3 doses of the nanoparticles. The effects appeared quickly.
"Only 1h after the injection we observed a reduction of 50-60% in Aβ
amount inside the brain," explains Junyang Chen, first co-author of the
study, researcher at the West China Hospital of Sichuan University and
PhD student at the University College London (UCL).
The long-term results were even more dramatic. Scientists tracked the
animals for months using behavioral and memory tests covering different
stages of disease progression.
In one experiment, researchers treated a 12-month-old mouse
(equivalent to a 60-year-old human) and evaluated it six months later.
By that point, the animal was roughly comparable to a 90-year-old human.
Despite its age, the mouse behaved similarly to a healthy animal with
no signs of Alzheimer's-related decline.
"The long-term effect comes from restoring the brain's vasculature.
We think it works like a cascade: when toxic species such as
amyloid-beta (Aβ) accumulate, disease progresses. But once the
vasculature is able to function again, it starts clearing Aβ and other
harmful molecules, allowing the whole system to recover its balance.
What's remarkable is that our nanoparticles act as a drug and seem to
activate a feedback mechanism that brings this clearance pathway back to
normal levels," said Giuseppe Battaglia, ICREA Research Professor at
IBEC, Principal Investigator of the Molecular Bionics Group and leader
of the study.
How the Nanoparticles Work
A major focus of the study was a protein called LRP1, which acts like
a molecular transport system at the blood-brain barrier. Normally, LRP1
recognizes amyloid-β, binds to it, and moves it out of the brain and
into the bloodstream for disposal.
But the process is delicate. If LRP1 binds amyloid-β too strongly,
the transport machinery becomes overloaded and breaks down. If the
interaction is too weak, waste removal does not occur efficiently
enough. Either way, amyloid-β starts piling up in the brain.
The supramolecular nanoparticles
were engineered to mimic the natural molecules that interact with LRP1.
By doing this, the particles appear to "reset" the transport system,
allowing amyloid-β to move out of the brain again.
Researchers say this strategy differs from many traditional
Alzheimer's therapies because it focuses on repairing the brain's own
infrastructure instead of simply attacking plaques directly.
That idea has gained momentum in recent years. Scientists
increasingly view Alzheimer's as both a neurological and vascular
disease, with disrupted blood flow and blood-brain barrier damage
contributing to the spread of toxic proteins.
A Different Kind of Nanomedicine
Most nanomedicine approaches use nanoparticles as delivery vehicles
to carry drugs into the body. In this case, the nanoparticles themselves
are the therapy.
The research team created the particles using a bottom-up molecular
engineering process that allowed them to precisely control their size
and the number of ligands on their surface. This precision helped the
particles interact with receptors on cell membranes in highly specific
ways.
By influencing how these receptors move and function, the
nanoparticles improved amyloid-β clearance and helped restore healthier
blood vessel activity in the brain.
Researchers say this approach could eventually complement other
Alzheimer's treatments, including anti-amyloid antibody drugs. One of
the biggest problems facing current therapies is getting enough medicine
across the blood-brain barrier safely and efficiently.
Other experimental technologies are also exploring ways to overcome this challenge,
including ultrasound-based delivery systems, "brain shuttle" molecules,
and additional nanoparticle platforms designed to cross the barrier
more effectively.
What Happens Next
Although the findings are
promising, the research remains in the animal-testing stage. Many
Alzheimer's therapies that worked in mice have later failed in human
clinical trials.
Still, experts say the study highlights an increasingly important
area of Alzheimer's research: restoring the health of the brain's blood
vessels and waste-removal systems.
"Our study demonstrated remarkable efficacy in achieving rapid Aβ
clearance, restoring healthy function in the blood-brain barrier and
leading to a striking reversal of Alzheimer's pathology," concludes
Lorena Ruiz Perez, researcher at the Molecular Bionics group from the
Institute for Bioengineering of Catalonia (IBEC) and Serra Hunter
Assistant Professor at the University of Barcelona (UB).
The project involved researchers from the Institute for
Bioengineering of Catalunya (IBEC), West China Hospital of Sichuan
University, West China Xiamen Hospital of Sichuan University, University
College London, the Xiamen Key Laboratory of Psychoradiology and
Neuromodulation, the University of Barcelona, the Chinese Academy of
Medical Sciences, and the Catalan Institution for Research and Advanced
Studies (ICREA).
Journal Reference:
- Junyang Chen, Pan Xiang, Aroa Duro-Castano, Huawei Cai, Bin Guo,
Xiqin Liu, Yifan Yu, Su Lui, Kui Luo, Bowen Ke, Lorena Ruiz-Pérez,
Qiyong Gong, Xiaohe Tian, Giuseppe Battaglia. Rapid amyloid-β clearance and cognitive recovery through multivalent modulation of blood–brain barrier transport. Signal Transduction and Targeted Therapy, 2025; 10 (1) DOI: 10.1038/s41392-025-02426-1
Courtesy:
Institute for Bioengineering of Catalonia (IBEC). "Scientists reverse
Alzheimer’s in mice with breakthrough nanotechnology." ScienceDaily.
ScienceDaily, 17 May 2026. <www.sciencedaily.com/releases/2026/05/260517030326.htm>.
