Thursday, May 4, 2023

Deep sleep may buffer against Alzheimer’s memory loss

An older man with a white beard sleeps soundly in bed.

Deep sleep might help buffer against memory loss for older adults facing a heightened burden of Alzheimer’s disease, new research suggests.

Deep sleep, also known as non-REM slow-wave sleep, can act as a “cognitive reserve factor” that may increase resilience against a protein in the brain called beta-amyloid that is linked to memory loss caused by dementia. Disrupted sleep has previously been associated with faster accumulation of beta-amyloid protein in the brain.

“Think of deep sleep almost like a life raft that keeps memory afloat…”

However, the new research reveals that superior amounts of deep, slow-wave sleep can act as a protective factor against memory decline in those with existing high amounts of Alzheimer’s disease pathology—a potentially significant advance that experts say could help alleviate some of dementia’s most devastating outcomes.

“With a certain level of brain pathology, you’re not destined for cognitive symptoms or memory issues,” says Zsófia Zavecz, a postdoctoral researcher at the University of California, Berkeley’s Center for Human Sleep Science. “People should be aware that, despite having a certain level of pathology, there are certain lifestyle factors that will help moderate and decrease the effects.

“One of those factors is sleep and, specifically, deep sleep.”

Cognitive reserve factors

The research in the journal BMC Medicine is the latest in a large body of work aimed at finding a cure for Alzheimer’s disease and preventing it altogether.

As the most prevalent form of dementia, Alzheimer’s disease destroys memory pathways and, in advanced forms, interferes with a person’s ability to perform basic daily tasks. Roughly one in nine people over age 65 have the progressive disease—a proportion that is expected to grow rapidly as the baby boomer generation ages.

In recent years, scientists have probed the ways that deposits of beta-amyloid associate with Alzheimer’s disease and how such deposits also affect memory more generally. In addition to sleep being a foundational part of memory retention, the researchers previously discovered that the declining amount of a person’s deep sleep could act as a “crystal ball” to forecast a faster rate of future beta-amyloid buildup in the brain, after which dementia is more likely set in.

Years of education, physical activity, and social engagement are widely believed to shore up a person’s resilience to severe brain pathology—essentially keeping the mind sharp, despite the decreased brain health. These are called cognitive reserve factors. However, most of them, such as past years of education or the size of one’s social network, cannot be easily changed or modified retroactively.

That idea of cognitive reserve became a compelling target for sleep researchers, says Matthew Walker, a professor of neuroscience and psychology and senior author of the study.

“If we believe that sleep is so critical for memory,” Walker says, “could sleep be one of those missing pieces in the explanatory puzzle that would tell us exactly why two people with the same amounts of vicious, severe amyloid pathology have very different memory?”

“If the findings supported the hypothesis, it would be thrilling, because sleep is something we can change,” he adds. “It is a modifiable factor.”

Filling in a missing puzzle piece

To test that question, the researchers recruited 62 older adults from the Berkeley Aging Cohort Study. Participants, who were healthy adults and not diagnosed with dementia, slept in a lab while researchers monitored their sleep waves with an electroencephalography (EEG) machine. Researchers also used a positron emission tomography (PET) scan to measure the amount of beta-amyloid deposits in the participants’ brains. Half of the participants had high amounts of amyloid deposits; the other half did not.

After they slept, the participants completed a memory task involving matching names to faces.

Those with high amounts of beta-amyloid deposits in their brain who also experienced higher levels of deep sleep performed better on the memory test than those with the same amount of deposits but who slept worse. This compensatory boost was limited to the group with amyloid deposits. In the group without pathology, deep sleep had no additional supportive effect on memory, which was understandable as there was no demand for resilience factors in otherwise intact cognitive function.

In other words, deep sleep bent the arrow of cognition upward, blunting the otherwise detrimental effects of beta-amyloid pathology on memory.

In their analysis, the researchers went on to control for other cognitive reserve factors, including education and physical activity, and still sleep demonstrated a marked benefit. This suggests that sleep, independent of these other factors, contributes to salvaging memory function in the face of brain pathology. These new discoveries, they says, indicate the importance of non-REM slow-wave sleep in counteracting some of the memory-impairing effects of beta-amyloid deposits.

Walker likened deep sleep to a rescue effort.

“Think of deep sleep almost like a life raft that keeps memory afloat, rather than memory getting dragged down by the weight of Alzheimer’s disease pathology,” Walker says. “It now seems that deep NREM sleep may be a new, missing piece in the explanatory puzzle of cognitive reserve. This is especially exciting because we can do something about it. There are ways we can improve sleep, even in older adults.”

Chief among those areas for improvement? Stick to a regular sleep schedule, stay mentally and physically active during the day, create a cool and dark sleep environment and minimize things like coffee late in the day and screen time before bed. A warm shower before turning in for the night has also been shown to increase the quality of deep, slow-wave sleep, Zavecz says.

With a small sample size of healthy participants, the study is simply an early step in understanding the precise ways sleep may forestall memory loss and the advance of Alzheimer’s, Zavecz says.

Still, it opens the door for potential longer-term experiments examining sleep-enhancement treatments that could have far-reaching implications.

“One of the advantages of this result is the application to a huge population right above the age of 65,” Zavecz says. “By sleeping better and doing your best to practice good sleep hygiene, which is easy to research online, you can gain the benefit of this compensatory function against this type of Alzheimer’s pathology.”

Source: UC Berkeley

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