As the new school year begins, it is important to review some recent research about sleep and cognition. New information makes it even more clear how important sleep is to learning and memory, brain health, alertness and much more.
One misconception about sleep is that our brains essentially go offline and simply get a break from the work we ask them to do during the day. Far from going offline, our brains are very active during sleep, cleaning up the toxins and waste that have accumulated during the day, and actively working to consolidate memory. And sleep also affects post-sleep cognitive functioning.
During the day as our brains are hard at work, proteins and protein fragments (such as beta-amyloid, implicated in Alzheimer’s disease) build up in the spaces between the neurons. During sleep, the brain flushes those spaces out with cerebral-spinal fluid. This daily cleaning process is critical for a healthy brain and takes too much energy for the brain take care of while it is awake and working.
Sleep is also when our brains strengthen recently learned information and consolidate it, or make it resistant to interference from material learned later and to degradation. Scientists have known for some time that a small structure in the brain called the hippocampus plays a critical role in the formation of new memories. The hippocampus is responsible for activating recent memories, but eventually, as those new memories are consolidated in the cortex, the hippocampus is no longer required to retrieve them. As new memories are being formed, the hippocampus seems to activate patterns across the cortex which result in the strengthening of the synapses (connections between neurons) that were involved in the initial learning experience. This kind of activity is pronounced during sleep.
When we are awake and the brain is taking in new sensory input, it doesn’t have time to practice recently learned information, so practicing (consolidation of memory) happens during sleep.
You’ve probably heard that there are different stages of sleep. Researchers differentiate between deep sleep (also called Slow Wave Sleep, SWS, or NREM (non-REM) sleep), and REM sleep (Rapid Eye Movement)). It now appears that different types of memory creation processes are taking place in non-REM and REM sleep.
According to the latest research, in NREM sleep, the neurons in our brains neurons are actively forming new connections, so at this stage plasticity is enhanced. In REM sleep, the neural networks where new information has been learned enter a stabilization process. During stabilization (also often called consolidation), important connections are strengthened and unimportant connections are pruned, resulted in stronger memory and more efficient processing.
We cycle between NREM and REM sleep several times during the course of a night, and while these cycles are typically about 90 minutes long, the amount of time we spend in NREM vs. REM changes, with more time spent in deep sleep earlier in the night and more time spent in REM later on. In either case, if we spend an insufficient amount of time asleep, learning and memory consolidation will be impacted. (If you really want to learn something, forget the all-nighter. Study, then sleep well.)
When we are sleep-deprived, not only have we impaired memory consolidation, we will also typically experience other types of deficits in cognitive functioning. These deficits are seen in domains including working memory, verbal learning, sustained attention, divided attention, inhibitory control, decision-making and emotional responses. Thus, without enough sleep, we are likely to struggle more with problem-solving, retaining information we hear, and staying on task. We are likely to make riskier decisions, and we will less able to form memories attached to positive emotions than negative emotions.
It is interesting to note that individuals whose inhibitory control was greater when well-rested were better able to engage those areas of the brain when they were sleep-deprived than individuals who performed more poorly when rested. This suggests that not only is it an advantage to develop our executive functions (including inhibitory control) under normal circumstances, it may especially heighten that advantage when we are tired. (Click here for more information on training cognitive skills, including executive functions.)
About the authors
Betsy Hill is President of BrainWare Learning Company, a company that builds learning capacity through the practical application of neuroscience. She is an experienced educator and has studied the connection between neuroscience and education with Dr. Patricia Wolfe (author of Brain Matters) and other experts. She is a former chair of the board of trustees at Chicago State University and teaches strategic thinking in the MBA program at Lake Forest Graduate School of Management where she received a Contribution to Learning Excellence Award. She received a Nepris Trailblazer Award for sharing her knowledge, skills and passion for the neuroscience of learning in classrooms around the country. She holds a Master of Arts in Teaching and an MBA from Northwestern University.
Roger Stark is Co-founder and CEO of the BrainWare Learning Company. Over the past decade, he championed efforts to bring comprehensive cognitive literacy skills training and cognitive assessment within reach of every person, and it all started with one very basic question: What do we know about the brain? From that initial question, Roger Stark pioneered the effort to build an effective and affordable cognitive literacy skills training tool, based on over 50 years of trial and error through clinical collaboration. He also led the team that developed BrainWare SAFARI, which has become the most researched comprehensive, integrated cognitive literacy training tool delivered online anywhere in the world. For more, follow BrainWare Learning on Twitter @BrainWareSafari