New Alzheimer’s research suggests that enhanced light sensitivity may contribute to ‘sundowning’, which is the worsening of symptoms late in the day, thereby spurring sleep disruptions thought to contribute to the disease’s progression.
Published in Frontiers in Aging Neuroscience, these new insights from UVA Health into the disruptions of the biological clock seen in Alzheimer’s could lead to new treatments and symptom management, the researchers say. For example, caregivers often struggle with the erratic sleep patterns caused by Alzheimer’s patients’ altered circadian rhythms. Light therapy, the new research suggests, might be an effective tool to help manage that.
Better understanding Alzheimer’s effects on circadian rhythms could have implications for prevention. Poor sleep quality in adulthood is a risk factor for Alzheimer’s, as brains at rest naturally cleanse themselves of amyloid beta proteins that are thought to form harmful tangles in Alzheimer’s.
“Circadian disruptions have been recognised in Alzheimer’s disease for a long time, but we’ve never had a very good understanding of what causes them,” said researcher Thaddeus Weigel, a graduate student working with Heather Ferris, MD, PhD. “This research points to changes in light sensitivity as a new, interesting possible explanation for some of those circadian symptoms.”
Alzheimer’s hallmark is progressive memory loss, to the point that patients can forget their own loved ones, but there can be many other symptoms, such as restlessness, aggression, poor judgment and endless searching. These symptoms often worsen in the evening and at night.
Ferris and her collaborators used a mouse model of Alzheimer’s to better understand what happens to the biological clock in Alzheimer’s disease. They essentially gave the mice “jet lag” by altering their exposure to light, then examined how it affected their behaviour. The Alzheimer’s mice reacted very differently to control mice.
The Alzheimer’s mice, the scientists found, adapted to a six-hour time change significantly more quickly than the control mice. This, the scientists suspect, is the result of a heightened sensitivity to changes in light. While our biological clocks normally take cues from light, this adjustment happens gradually – thus, jet lag when we travel great distances. Our bodies need time to adapt. But for the Alzheimer’s mice, this change happened abnormally fast.
The researchers initially thought this might be because of neuroinflammation. So they looked at immune cells called microglia that have become promising targets in developing better Alzheimer’s treatments. But the scientists ultimately ruled out this hypothesis, determining that microglia did not make a difference in how quickly mice adapted. (Though targeting microglia might be beneficial for other reasons.)
Notably, the UVA scientists also ruled out another potential culprit: “mutant tau,” an abnormal protein that forms tangles in the Alzheimer’s brain. The presence of these tangles also did not make a difference in how the mice adapted.
The researchers’ results ultimately suggest there is an important role for the retina in the enhanced light sensitivity in Alzheimer’s, and that gives researchers a promising avenue to pursue as they work to develop new ways to treat, manage and prevent the disease.
“These data suggest that controlling the kind of light and the timing of the light could be key to reducing circadian disruptions in Alzheimer’s disease,” Ferris said. “We hope that this research will help us to develop light therapies that people can use to reduce the progression of Alzheimer’s disease.”
Do you expose them to more or less light. And is it white light,warm light or blue light(computers and iPads ). And when,in the evening .
According to the journal article, the study so far has only been done with lab mice. Dim light seemed to have an effect on the Alzheimer-model mice, disrupting their circadian rhythms, while normal mice were not strongly affected by it (lab mice are nocturnal, so light makes them sleep). They did not try the effect of different light wavelengths. Perhaps a future study could investigate this effect in humans.