The “why” of sleep is considered by many scientists to be one of the most enduring mysteries and important questions in the neurosciences. Sleep appears to be as vital to our existence as water and food, we spend ~ 1/3 of our lives sleeping, and all animals sleep, yet we still do not understand, at least not fully, the why of sleep. Underscoring our fascination with sleep, it has been the topic of writings since the beginning of the recorded history. For example, the ancient Hindu textbook Upanishad (~ 1000 BC) described four states of “vigilance,” two of which correspond to the sleeping state, that is, non-rapid eye movement sleep and rapid eye movement sleep. The ancient philosopher Aristotle wrote an entire essay on sleep that he titled “On sleep and sleeplessness” in 350 BC. And Hippocrates, the famous ancient physician, was the first to emphasize the importance of sleep to health, as he writes in aphorism that “bad sleep and insomnolence, when immoderate, are bad.” And as one prominent sleep scientist, Allan Rechtschaffen, remarked, “If sleep doesn’t serve an absolutely vital function, it is the biggest mistake evolution ever made.” In short, the adaptive advantage of having our brains go “off-line” for any extended period of time remains unclear. After all, the time spent in the sleep state is a time of heightened vulnerability and represents “downtime” with respect to pursuing biological imperatives like eating and drinking and, certainly from the standpoint of ones’ genes, procreating. On the flip side of this, if an animal, be that a human or a mouse, could go without sleep, this would appear highly adaptive, in particular given that there would be more time to find food, mate, exploit the environment, conquer territory, learn, and so forth. Our present understanding is that sleep does many things, which may include synaptic remodeling, clearing out wake-accumulated toxins from the brain, and ensuring that memories are formed, but these processes, even collectively, are likely only a partial and somewhat unsatisfactory answer.

Over the course of a typical 24 hour day, the brain cycles through three behavioral states, each of which is operationally defined by the level of behavioral arousal and electrocortical activity. Sleep, for example, is a behavioral state characterized by a decreased sensitivity to stimuli, stereotypic posture, a reduction in motor activity (as measured by the electromyogram, EMG), and a distinctive cortical electroencephalogram (EEG; see Fig. 5.1). The rapid reversibility and self-regulating aspect of sleep are two key features that differentiate the sleep state from other states of altered consciousness, such as coma and anesthesia (Rechtschaffen & Kales, 1968). On the other hand, the behavioral state of wake is characterized by a high level of alertness or vigilance, often occurring concurrently with motor behaviors, and a more “active” cortical EEG.