Could lithium explain — and treat — Alzheimer’s disease?

Study: Lithium loss ignites Alzheimer’s, but lithium compound can reverse disease in mice

Harvard Medical School

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Top row: In a mouse model of Alzheimer’s disease, lithium deficiency (right) dramatically increased amyloid beta deposits in the brain compared with mice that had normal physiological levels of lithium (left). Bottom row: The same was true for the Alzheimer’s neurofibrillary tangle protein tau.

Alt text: One pair of boxes shows fewer green amyloid clusters on the left and more on the right. Another pair of boxes shows a dim arc of purple and red tau on the left and a brighter arc on the right.

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Credit: Yankner Lab

At a glance:

• Study shows for the first time that lithium plays an essential role in normal brain function and can confer resistance to brain aging and Alzheimer’s disease.

• Scientists discovered that lithium is depleted in the brain by binding to toxic amyloid plaques — revealing a new way Alzheimer’s may begin.

• A new class of lithium-based compounds avoids plaque binding and reverses Alzheimer’s and brain aging in mice, without toxicity.

What is the earliest spark that ignites the memory-robbing march of Alzheimer’s disease? Why do some people with Alzheimer’s-like changes in the brain never go on to develop dementia? These questions have bedeviled neuroscientists for decades.

Now, a team of researchers at Harvard Medical School may have found an answer: lithium deficiency in the brain.

The work, published Aug. 6 in Nature, shows for the first time that lithium occurs naturally in the brain, shields it from neurodegeneration, and maintains the normal function of all major brain cell types. The findings — 10 years in the making — are based on a series of experiments in mice and on analyses of human brain tissue and blood samples from individuals in various stages of cognitive health.

The scientists found that lithium loss in the human brain is one of the earliest changes leading to Alzheimer’s, while in mice, similar lithium depletion accelerated brain pathology and memory decline. The team further found that reduced lithium levels stemmed from binding to amyloid plaques and impaired uptake in the brain. In a final set of experiments, the team found that a novel lithium compound that avoids capture by amyloid plaques restored memory in mice.

The results unify decades-long observations in patients, providing a new theory of the disease and a new strategy for early diagnosis, prevention, and treatment.

Affecting an estimated 400 million people worldwide, Alzheimer’s disease involves an array of brain abnormalities — such as clumps of the protein amyloid beta, neurofibrillary tangles of the protein tau, and loss of a protective protein called REST — but these never explained the full story of the disease. For instance, some people with such abnormalities show no signs of cognitive decline. And recently developed treatments that target amyloid beta typically don’t reverse memory loss and only modestly reduce the rate of decline.

It’s also clear that genetic and environmental factors affect risk of Alzheimer’s, but scientists haven’t figured out why some people with the same risk factors develop the disease while others don’t.

Lithium, the study authors said, may be a critical missing link.

“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.

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.

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.

If replicated in further studies, the researchers say lithium screening through routine blood tests may one day may 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.

Authorship, funding, disclosures

Additional authors are Zhen Kai Ngian, Chenxi Qiu, Jaejoon Choi, Marianna Liang, Derek M. Drake, Sara E. Hamplova, Ella Lacey, Perle Roche, Monlan Yuan, and Saba S. Hazaveh of HMS; Eunjung A. Lee of Boston Children’s Hospital; and David A. Bennett of the Rush Alzheimer’s Disease Center at Rush University Medical Center in Chicago.

Yankner is co-director of the Paul F. Glenn Center for Biology of Aging Research at HMS.

This work was supported by the National Institutes of Health (grants R01AG046174, R01AG069042, K01AG051791, DP2AG072437, P30AG10161, P30AG72975, R01AG15819, R01AG17917, U01AG46152, and U01AG61356), the Ludwig Family Foundation, the Glenn Foundation for Medical Research, and the Aging Mind Foundation.

Lithium deficiency thinned the myelin that coats neurons (right) compared to normal mice (left).  Alt text: side-by-side grayscale electron microscopy images show thicker cell borders on the left and thinner borders on the right.

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). 

Alt text: Stacked boxes on the left show significantly fewer green amyloid-beta clumps for mice treated with lithium orotate. Stacked boxes on the right show a similar drop in red tau tangles.

Credit

Yankner Lab

Lithium was the only metal that differed significantly between people with and without mild cognitive impairment, often a precursor to Alzheimer’s disease.

Alt text: a scatter plot of different metals shows one main cluster and then an outlier, labeled “lithium.”

Credit

Aron et al, 'Lithium deficiency and the onset of Alzheimer’s disease', Nature

Journal

Nature

DOI

10.1038/s41586-025-09335-x 

Method of Research

Experimental study

Subject of Research

Human tissue samples

Article Title

Lithium deficiency and the onset of Alzheimer’s disease

Article Publication Date

6-Aug-2025

BAN DEEP SEA MINING

MBARI researchers deploy new imaging system to study the movement of deep-sea octopus

3D visual data collected by MBARI’s groundbreaking EyeRIS camera system could contribute to the design of bioinspired robots in the future.

Monterey Bay Aquarium Research Institute

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MBARI’s innovative EyeRIS camera system collects near real-time three-dimensional visual data about the structure and biomechanics of marine life. Filming deep-sea pearl octopus (Muusoctopus robustus) with this system has provided new insight into octopus locomotion that can contribute to the design of bioinspired robots in the future. Image: © 2022 MBARI

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Credit: © 2022 MBARI

MBARI researchers have developed an innovative imaging system that can be deployed at great depths underwater to study the movement of marine life. The team used the system to study deep-sea octopus and shared their findings in the scientific journal Nature.

EyeRIS (Remote Imaging System) can capture detailed three-dimensional visual data about the structures and movement of marine life in their natural deep-sea habitat. MBARI researchers integrated EyeRIS on board a remotely operated vehicle to observe deep-sea pearl octopus (Muusoctopus robustus) at the famous Octopus Garden offshore of Central California.

“In MBARI’s Bioinspiration Lab, we look to nature to find inspiration for tackling fundamental engineering challenges,” said Principal Engineer Kakani Katija. “Octopuses are fascinating subjects as they have no bones yet are able to move across complex underwater terrain with ease. Until now, it has been difficult to study their biomechanics in the field, but EyeRIS is a game changer for us.” 

“EyeRIS allowed us to follow several individuals as they moved, completely unconstrained, in their natural environment,” said Senior Research Specialist Crissy Huffard. “Our team was able to get 3D measurements of their arms in real-time as they crawled over the rough terrain of the deep seafloor.”

EyeRIS uses a specialized, high-resolution camera with a dense array of microlenses that collects simultaneous views of any object in its sight. Software uses that data to create imagery where every pixel in an image is in focus. EyeRIS can create a three-dimensional reconstruction of an animal's movements so researchers can observe individual features in stunning detail. MBARI researchers used EyeRIS to track the movements of specific points on an octopus’s arm, identifying areas of curvature and strain in real time as the animal crawled over the rugged seafloor.

“EyeRIS data showed that pearl octopus use temporary muscular joints in their arms when crawling, with strain and bend concentrated above and below the joint. This allows them to have simple, but sophisticated, control of their arms,” said Huffard. “The mechanisms of this simplified control could be valuable for designing octopus-inspired robots and other bioinspired technologies in the future.” 

EyeRIS is the latest example of how technology can help us better understand ocean life. This versatile new imaging system can study marine animals that live on the seafloor and in the water column.

“There is still so much to learn about marine life. EyeRIS will allow us to continue to study the movement and behavior of octopuses and other deep-sea animals in their natural environment using non-invasive techniques. I’m excited to see how this growing body of research and new technology sparks future bioinspired engineering innovation,” said Katija. 

The development of EyeRIS was made possible by the David and Lucile Packard Foundation and the Gordon and Betty Moore Foundation.

 

About MBARI
MBARI (Monterey Bay Aquarium Research Institute) is a non-profit oceanographic research center founded in 1987 by the late Silicon Valley innovator and philanthropist David Packard. Our mission is to advance marine science and engineering to understand our changing ocean. Learn more at mbari.org. 

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Journal

Nature

DOI

10.1038/s41586-025-09379-z 

Subject of Research

Animals

Article Title

In situ light-field imaging of octopus locomotion reveals simplified control

Article Publication Date

6-Aug-2025

 

Big heart, acute senses key to explosive radiation of early fishes

Digital reconstruction of tiny, 400-million-year-old fish shows how anatomy geared toward evading predators equipped it to become the hunter once jaws evolved

University of Chicago

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Reconstruction of Norselapsis glacialis in their aquatic environment

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Credit: Kristen Tietjin

An international team led by scientists from the Canadian Museum of Nature and the University of Chicago reconstructed the brain, heart, and fins of an extinct fish called Norselaspis glacialis from a tiny fossil the size of fingernail and found evidence of change toward a fast-swimming, sensorily attuned lifestyle well before jaws and teeth were invented to better capture food.

“These are the opening acts for a key episode in our own deep evolutionary history,” said Tetsuto Miyashita, who is a research scientist with the museum and lead author of the new study published in the journal Nature this week.

Fish have been around for half a billion years. The earliest species lived close to the seafloor, but when they evolved jaws and teeth, everything changed; by 400 million years ago, jawed fishes dominated the water column. Ultimately, limbed animals--including humans—also originated from this radiation of vertebrates.

It has long been a mystery, however, how this pivotal event occurred. The standard theory holds that jaws evolved first, and other body parts underwent changes to sustain a new predatory lifestyle. “But there is a large data gap beneath this transformation,” said Michael Coates, Professor and Chair of Organismal Biology and Anatomy at UChicago and a senior author of the study. “We’ve been missing snapshots from the fossil record that would help us order the key events to reconstruct the pattern and direction of change.”

The new study flips the “jaws-first” idea on its head. “We found features in a jawless fish, Norselaspis, that we thought were unique to jawed forms,” said Miyashita, who was formerly a postdoc in Coates’ lab in Chicago. “This fossil from the Devonian Period more than 400 million years ago shows that acute senses and a powerful heart evolved well before jaws and teeth.”

The fossil of Norselaspis the team studied is so exquisitely preserved in a fragment of rock that they were able to scan it and see impressions of its heart, blood vessels, brain, nerves, inner ears, and even the tiny muscles that moved the eyeball. The fossil was hidden in one of thousands of sandstone blocks collected during a French paleontological expedition to Spitsbergen, Norway’s Arctic archipelago, in 1969. Sorting through these rocks 40 years later, the study’s coauthors Philippe Janvier and Pierre Gueriau split one open, revealing a perfectly preserved cranium of Norselaspis barely half an inch long. The team took the fossil to a particle accelerator at the Paul Scherrer Institute in Switzerland to scan it with high-energy X-ray beams.

The result was jaw-dropping. Slice by slice, the X-ray images revealed delicate films of bone that enclosed the fish’s organs with astonishing detail. At a hundredth of a millimetre wide, these tissue-thin bones capture the ghosts of organs formerly held by the skeleton. Back in Chicago, digital imaging specialist Kristen Tietjen (now at the Biodiversity Institute at the University of Kansas) worked with Miyashita and Coates to digitally dissect and stitch together the fish’s anatomy through thousands of screen hours.

“With this exquisite digital atlas, we now know Norselaspis in greater anatomical detail than many living fishes,” Miyashita said. For example, the fish had seven tiny muscles to move its eyeballs, whereas humans have six. It had outsized inner ears, an enormous heart, and vessels arranged like highway bypasses to carry more blood. Miyashita draws comparisons to fruit. “If Norselaspis was to our scale, its inner ears would be each the size of an avocado, and its heart would be as large as a cantaloupe melon,” he said.

Fish use their inner ears in much the same way that we use ours, to sense vibration, orientation, and acceleration. The capacious heart and greater blood flow provides more horsepower for the animal. “One might even say Norselaspis had the heart of a shark under the skin of a lamprey,” Miyashita said.

The fish also sported a pair of tilted, paddle-like fins behind the gills, which Coates explained would have been useful for making sudden stops, bursts and turns. These anatomical innovations made Norselaspis something of a sportscar among the generally sluggish jawless fishes of its time.

Such “action-packed” anatomy likely evolved for evading predators rather than for chasing prey. But what triggers rapid escape responses in jawless fish would in turn give jawed fish an advantage to do the opposite, detecting and capturing food efficiently. “When jaws evolved against this background, it brought about a pivotal combination of sensory, swimming, and feeding systems, eventually leading to the extraordinary variety and abundance of Devonian fishes,” Coates said.

The earliest jaws were probably better adapted for sucking up food along with water and mud than for snapping at passing prey, however. “It wasn’t as simple as marching straight from a bottom feeder to an apex predator,” Miyashita said.

The new study also challenges the idea that shoulders and arms in modern tetrapods evolved from modified gill structures. The team traced the nerve going to the shoulder in Norselaspis and saw that it was separate from the nerves going to the gills—clear evidence that one did not come from the other. Instead, the team argues that the shoulder evolved as a wholly new structure with a new domain, the neck, separating the head the from the torso.

“A lot of these evolutionary changes have to do with how the head is attached to the trunk,” Miyashita said. In primitive jawless fishes, the head is continuous from the torso, while jawed vertebrates have a neck and throat to separate the two regions. Norselaspis is in the middle; Its head is directly attached to the shoulder without a neck, almost as if our arms were sticking out behind the cheeks. But the organs at this interface, like inner ears, shoulders and a heart, are enhanced or reorganized for greater abilities to navigate its environment.

Paleontologists are still investigating what ignited this transformation. Some, like Christian Klug of the University of Zurich, Switzerland, who was not involved in the study, believe the lineage of Norselaspis arose in the time of the so-called Nekton Revolution, when marine organisms were beginning to move up in the water column. The game then was about getting faster, smarter, and more manoeuvrable.

“For a historical event, we often emphasize one or two symbolic moments to the point of becoming a cliché. In this sense, the evolution of jaws is like a gunshot in Sarajevo starting World War I in 1914,” Miyashita said. “But it is imperative we understand the context. With Norselaspis, we can really find it in its heart.”

Reconstruction of Norselapsis glacialis



Credit

Kristen Tietjin







The tiny 400-million-year-old fossil of Norselapsis studied by the research team








Digital 3D image of the Norselaspis skull cut away from side

Digital 3D image of the Norselaspis skull showing the brain and inner ear



Credit

Michael Coates, University of Chicago

Research scientist Tetsuto Miyashita holds an enlarged 3D reconstruction of the brain and sensory organs of Norselapsis

Credit

Pierre Poirier, Canadian Museum of Nature

Journal

Nature

DOI

10.1038/s41586-025-09329-9 

Method of Research

Imaging analysis

Subject of Research

Animal tissue samples

Article Title

Novel assembly of a head–trunk interface in sister group of jawed vertebrates

Article Publication Date

6-Aug-2025

 

Archaeologists find oldest evidence of humans on ‘Hobbit’s’ island neighbor – who they were remains a mystery

Griffith University

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Stone tools were excavated from Calio, Sulawesi, and dated to over 1.04 million years ago. The scale bars are 10 mm.

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Credit: Credit: M.W. Moore/University of New England

Recent findings, made by Griffith University researchers, show that early hominins made a major deep-sea crossing to reach the Indonesian island of Sulawesi much earlier than previously established, based on the discovery of stone tools dating to at least 1.04 million years ago at the Early Pleistocene (or ‘Ice Age’) site of Calio.

Budianto Hakim from the National Research and Innovation Agency of Indonesia (BRIN) and Professor Adam Brumm from the Australian Research Centre for Human Evolution at Griffith University led the research published today in Nature.

A field team led by Hakim excavated a total of seven stone artefacts from the sedimentary layers of a sandstone outcrop in a modern corn field at the southern Sulawesi location.

In the Early Pleistocene, this would have been the site of hominin tool-making and other activities such as hunting, in the vicinity of a river channel.

The Calio artefacts consist of small, sharp-edged fragments of stones (flakes) that the early human tool-makers struck from larger pebbles that had most likely been obtained from nearby riverbeds.

The Griffith-led team used palaeomagnetic dating of the sandstone itself and direct-dating of an excavated pig fossil, to confirm an age of at least 1.04 million years for the artefacts.

Previously, Professor Brumm’s team had revealed evidence for hominin occupation in this archipelago, known as Wallacea, from at least 1.02 million years ago, based on the presence of stone tools at Wolo Sege on the island of Flores, and by around 194 thousand years ago at Talepu on Sulawesi.

The island of Luzon in the Philippines, to the north of Wallacea, had also yielded evidence of hominins from around 700,000 years ago.

“This discovery adds to our understanding of the movement of extinct humans across the Wallace Line, a transitional zone beyond which unique and often quite peculiar animal species evolved in isolation,” Professor Brumm said.

“It’s a significant piece of the puzzle, but the Calio site has yet to yield any hominin fossils; so while we now know there were tool-makers on Sulawesi a million years ago, their identity remains a mystery.”

The original discovery of Homo floresiensis (the ‘hobbit’) and subsequent 700,000-year-old fossils of a similar small-bodied hominin on Flores, also led by Professor Brumm’s team, suggested that it could have been Homo erectus that breached the formidable marine barrier between mainland Southeast Asia to inhabit this small Wallacean island, and, over hundreds of thousands of years, underwent island dwarfism.

Professor Brumm said his team’s recent find on Sulawesi has led him to wonder what might have happened to Homo erectus on an island more than 12 times the size of Flores?

“Sulawesi is a wild card – it’s like a mini-continent in itself,” he said.

“If hominins were cut off on this huge and ecologically rich island for a million years, would they have undergone the same evolutionary changes as the Flores hobbits? Or would something totally different have happened?”

The study ‘Hominins on Sulawesi during the Early Pleistocene’ has been published in Nature.

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Journal

Nature

Article Title

Hominins on Sulawesi during the Early Pleistocene