“The idea that lithium deficiency could be a cause of Alzheimer’s disease is new and suggests a different therapeutic approach,” said senior author Bruce Yankner, professor of genetics and neurology in the Blavatnik Institute at HMS, who in the 1990s was the first to demonstrate that amyloid beta is toxic.
The study raises hopes that researchers could one day use lithium to treat the disease in its entirety rather than focusing on a single facet such as amyloid beta or tau, he said.
One of the main discoveries in the study is that as amyloid beta begins to form deposits in the early stages of dementia in both humans and mouse models, it binds to lithium, reducing lithium’s function in the brain. The lower lithium levels affect all major brain cell types and, in mice, give rise to changes recapitulating Alzheimer’s disease, including memory loss.
The authors identified a class of lithium compounds that can evade capture by amyloid beta. Treating mice with the most potent amyloid-evading compound, called lithium orotate, reversed Alzheimer’s disease pathology, prevented brain cell damage, and restored memory.
Although the findings need to be confirmed in humans through clinical trials, they suggest that measuring lithium levels could help screen for early Alzheimer’s. Moreover, the findings point to the importance of testing amyloid-evading lithium compounds for treatment or prevention.
Other lithium compounds are already used to treat bipolar disorder and major depressive disorder, but they are given at much higher concentrations that can be toxic, especially to older people. Yankner’s team found that lithium orotate is effective at one-thousandth that dose — enough to mimic the natural level of lithium in the brain. Mice treated for nearly their entire adult lives showed no evidence of toxicity.
“You have to be careful about extrapolating from mouse models, and you never know until you try it in a controlled human clinical trial,” Yankner said. “But so far the results are very encouraging.”
Lithium depletion is an early sign of Alzheimer’s
Yankner became interested in lithium while using it to study the neuroprotective protein REST. Finding out whether lithium is found in the human brain and whether its levels change as neurodegeneration develops and progresses, however, required access to brain tissue, which generally can’t be accessed in living people.
So the lab partnered with the Rush Memory and Aging Project in Chicago, which has a bank of postmortem brain tissue donated by thousands of study participants across the full spectrum of cognitive health and disease.
Having that range was critical because trying to study the brain in the late stages of Alzheimer’s is like looking at a battlefield after a war, said Yankner; there’s a lot of damage and it’s hard to tell how it all started. But in the early stages, “before the brain is badly damaged, you can get important clues,” he said.
Led by first author Liviu Aron, senior research associate in the Yankner Lab, the team used an advanced type of mass spectroscopy to measure trace levels of about 30 different metals in the brain and blood of cognitively healthy people, those in an early stage of dementia called mild cognitive impairment, and those with advanced Alzheimer’s.
Lithium was the only metal that had markedly different levels across groups and changed at the earliest stages of memory loss. Its levels were high in the cognitively healthy donors but greatly diminished in those with mild impairment or full-blown Alzheimer’s.
The team replicated its findings in samples obtained from multiple brain banks nationwide.
Lithium was the only metal that differed significantly between people with and without mild cognitive impairment, often a precursor to Alzheimer’s disease.
The observation aligned with previous population studies showing that higher lithium levels in the environment, including in drinking water, tracked with lower rates of dementia.
But the new study went beyond by directly observing lithium in the brains of people who hadn’t received lithium as a treatment, establishing a range that constitutes normal levels, and demonstrating that lithium plays an essential role in brain physiology.
“Lithium turns out to be like other nutrients we get from the environment, such as iron and vitamin C,” Yankner said. “It’s the first time anyone’s shown that lithium exists at a natural level that’s biologically meaningful without giving it as a drug.”
Then Yankner and colleagues took things a step further. They demonstrated in mice that lithium depletion isn’t merely linked to Alzheimer’s disease — it helps drive it.
Loss of lithium causes the range of Alzheimer’s-related changes
The researchers found that feeding healthy mice a lithium-restricted diet brought their brain lithium levels down to a level similar to that in patients with Alzheimer’s disease. This appeared to accelerate the aging process, giving rise to brain inflammation, loss of synaptic connections between neurons, and cognitive decline.
In Alzheimer’s mouse models, depleted lithium dramatically accelerated the formation of amyloid-beta plaques and structures that resemble neurofibrillary tangles. Lithium depletion also activated inflammatory cells in the brain called microglia, impairing their ability to degrade amyloid; caused the loss of synapses, axons, and neuron-protecting myelin; and accelerated cognitive decline and memory loss — all hallmarks of Alzheimer’s disease.
Lithium deficiency thinned the myelin that coats neurons (right) compared to normal mice (left). Images: Yankner Lab
The mouse experiments further revealed that lithium altered the activity of genes known to raise or lower risk of Alzheimer’s, including the most well-known, APOE.
Replenishing lithium by giving the mice lithium orotate in their water reversed the disease-related damage and restored memory function, even in older mice with advanced disease. Notably, maintaining stable lithium levels in early life prevented Alzheimer’s onset — a finding that confirmed that lithium fuels the disease process.
“What impresses me the most about lithium is the widespread effect it has on the various manifestations of Alzheimer’s. I really have not seen anything quite like it all my years of working on this disease,” said Yankner.
A promising avenue for Alzheimer’s treatment
A few limited clinical trials of lithium for Alzheimer’s disease have shown some efficacy, but the lithium compounds they used — such as the clinical standard, lithium carbonate — can be toxic to aging people at the high doses normally used in the clinic.
The new research explains why: Amyloid beta was sequestering these other lithium compounds before they could work. Yankner and colleagues found lithium orotate by developing a screening platform that searches a library of compounds for those that might bypass amyloid beta. Other researchers can now use the platform to seek additional amyloid-evading lithium compounds that might be even more effective.
“One of the most galvanizing findings for us was that there were profound effects at this exquisitely low dose,” Yankner said.
Treating mice with the amyloid-evading lithium orotate (top row) reduced amyloid beta (left) and tau (right) much more effectively than lithium carbonate (bottom row). Images: Yankner Lab
If replicated in further studies, the researchers say lithium screening through routine blood tests may one day offer a way to identify individuals at risk for Alzheimer’s who would benefit from treatment to prevent or delay disease onset.
Studying lithium levels in people who are resistant to Alzheimer’s as they age might help scientists establish a target level that they could help patients maintain to prevent onset of the disease, Yankner said.
Since lithium has not yet been shown to be safe or effective in protecting against neurodegeneration in humans, Yankner emphasizes that people should not take lithium compounds on their own. But he expressed cautious optimism that lithium orotate or a similar compound will move forward into clinical trials in the near future and could ultimately change the story of Alzheimer’s treatment.
“My hope is that lithium will do something more fundamental than anti-amyloid or anti-tau therapies, not just lessening but reversing cognitive decline and improving patients’ lives,” he said.