People with Alzheimer’s disease are known to have disturbances in their internal body clocks that affect the sleep/wake cycle and may increase risk of developing the disorder. Now research at Washington University School of Medicine in St. Louis indicates that such circadian rhythm disruptions also occur much earlier in people whose memories are intact but whose brain scans show early, preclinical evidence of Alzheimer’s.
The findings potentially could help doctors identify people at risk of Alzheimer’s earlier than currently is possible. That’s important because Alzheimer’s damage can take root in the brain 15 to 20 years before clinical symptoms appear.
The research is published Jan. 29 in the journal JAMA Neurology.
“It wasn’t that the people in the study were sleep-deprived,” says first author Erik S. Musiek, MD, PhD, an assistant professor of neurology, in a release. “But their sleep tended to be fragmented. Sleeping for 8 hours at night is very different from getting 8 hours of sleep in one-hour increments during daytime naps.”
The researchers also conducted a separate study in mice, to be published Jan 30 in The Journal of Experimental Medicine (titled, “Regulation of amyloid-beta dynamics and pathology by the circadian clock.”) showing that similar circadian disruptions accelerate the development of amyloid plaques in the brain, which are linked to Alzheimer’s.
Previous studies at Washington University, conducted in people and in animals, have found that levels of amyloid fluctuate in predictable ways during the day and night. Amyloid levels decrease during sleep, and several studies have shown that levels increase when sleep is disrupted or when people don’t get enough deep sleep, according to research by senior author, Yo-El Ju, MD.
“In this new study, we found that people with preclinical Alzheimer’s disease had more fragmentation in their circadian activity patterns, with more periods of inactivity or sleep during the day and more periods of activity at night,” says Ju, an assistant professor of neurology.
The researchers tracked circadian rhythms in 189 cognitively normal, older adults with an average age of 66. Some had positron emission tomography (PET) scans to look for Alzheimer’s-related amyloid plaques in their brains. Others had their cerebrospinal fluid tested for Alzheimer’s-related proteins. And some had both scans and spinal fluid testing.
Of the participants, 139 had no evidence of the amyloid protein that signifies preclinical Alzheimer’s. Most had normal sleep/wake cycles, although several had circadian disruptions that were linked to advanced age, sleep apnea or other causes.
But among the other 50 subjects—who either had abnormal brain scans or abnormal cerebrospinal fluid—all experienced significant disruptions in their internal body clocks, determined by how much rest they got at night and how active they were during the day. Disruptions in the sleep/wake cycle remained even after the researchers statistically controlled for sleep apnea, age, and other factors.
The study subjects, from Washington University’s Knight Alzheimer’s Disease Research Center, all wore devices similar to exercise trackers for one to two weeks. Each also completed a detailed sleep diary every morning.
By tracking activity during the day and night, the researchers could tell how scattered rest and activity were throughout 24-hour periods. Subjects who experienced short spurts of activity and rest during the day and night were more likely to have evidence of amyloid buildup in their brains.
These findings in people reinforce the mouse research from Musiek’s lab. In that study, working with first author Geraldine J. Kress, PhD, an assistant professor of neurology, Musiek studied circadian rhythm disruptions in a mouse model of Alzheimer’s. To disrupt the animals’ circadian rhythms, his team disabled genes that control the circadian clock.
“Over two months, mice with disrupted circadian rhythms developed considerably more amyloid plaques than mice with normal rhythms,” Musiek says. “The mice also had changes in the normal, daily rhythms of amyloid protein in the brain. It’s the first data demonstrating that the disruption of circadian rhythms could be accelerating the deposition of plaques.”
Both Musiek and Ju said it’s too early to answer the chicken-and-egg question of whether disrupted circadian rhythms put people at risk for Alzheimer’s disease or whether Alzheimer’s-related changes in the brain disrupt circadian rhythms.
“At the very least, these disruptions in circadian rhythms may serve as a biomarker for preclinical disease,” says Ju. “We want to bring back these subjects in the future to learn more about whether their sleep and circadian rhythm problems lead to increased Alzheimer’s risk or whether the Alzheimer’s disease brain changes cause sleep/wake cycle and circadian problems.”