Alzheimer's patients frequently suffer from sleep disorders, mostly even before they become forgetful, and it is known that sleep plays a very important role in memory formation. Researchers have now been able to show for the first time how the pathological changes in the brain act on the information-storing processes during sleep. Using animal models, they were able to decode the exact mechanism and alleviate the impairment with medicinal agents. The study was published in Nature Neuroscience.
The sleep slow waves, also known as slow oscillations, which our brain generates at night, have a particular role in consolidating what we have learned and in shifting memories into long-term storage. These waves are formed via a network of nerve cells in the brain's cortex, and then spread out into other parts of the brain, such as the hippocampus.
The study used mouse models, which form the same protein deposits, known as β-amyloid plaques, that are visible in human patients. The scientists were able to show that these plaques directly impair the slow wave activity. The scientists also succeeded in decoding this defect at the molecular level: correct spread of the waves requires a precise balance to be maintained between the excitation and inhibition of nerve cells. In the Alzheimer models, this balance was disturbed by the protein deposits, so that inhibition was reduced.
The researchers used this knowledge to treat the defect with medication. One group of sleep-inducing drugs, benzodiazepines, is known to boost inhibitory influences in the brain. If the scientists gave small amounts of this sleep medication to the mice (approximately one-tenth of the standard dose), the sleep slow waves were able to spread out correctly again. In subsequent behavioral experiments, they were able to demonstrate that learning performance had improved as well.
Source: Technical University of Munich