{"id":376,"date":"2023-03-02T20:16:23","date_gmt":"2023-03-02T20:16:23","guid":{"rendered":"https:\/\/content.one.lumenlearning.com\/introductiontopsychology\/chapter\/stages-of-sleep\/"},"modified":"2023-09-15T14:07:37","modified_gmt":"2023-09-15T14:07:37","slug":"stages-of-sleep","status":"publish","type":"chapter","link":"https:\/\/content.one.lumenlearning.com\/introductiontopsychology\/chapter\/stages-of-sleep\/","title":{"raw":"Sleep: Learn It 4\u2014Stages of Sleep","rendered":"Sleep: Learn It 4\u2014Stages of Sleep"},"content":{"raw":"

Stages of Sleep<\/h2>\r\nSleep is not a uniform state of being. Instead, sleep is composed of several different stages that can be differentiated from one another by the patterns of brain wave activity that occur during each stage. These changes in brain wave activity can be visualized using an electroencephalogram (EEG) and are distinguished from one another by both the frequency and amplitude of brain waves. Sleep can be divided into two different general phases: REM sleep and non-REM (NREM) sleep. An electroencephalograph (EEG) measures electrical potentials across the surface of the scalp which are the result of neural activity within the brain.\r\n\r\n
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REM sleep and non-REM (NREM) sleep<\/h3>\r\nRapid eye movement (REM) sleep<\/strong> is characterized by darting movements of the eyes under closed eyelids. Brain waves during REM sleep appear very similar to brain waves during wakefulness.\r\n\r\n \r\n\r\nIn contrast, non-REM (NREM) sleep<\/strong> is subdivided into three\u00a0stages distinguished from each other and from wakefulness by characteristic patterns of brain waves.\r\n\r\n<\/section>The first three stages of sleep are NREM sleep, while the fourth and final stage of sleep is REM sleep.\r\n

NREM Sleep<\/h2>\r\n
The first stage of NREM sleep is known as stage 1 sleep.
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Stage 1 sleep<\/h3>\r\nStage 1 sleep<\/strong> is a transitional phase that occurs between wakefulness and sleep.\u00a0This corresponds to the period during which we drift off to sleep. During this time, respiration and heart rates slow. In addition, stage 1 sleep involves a marked decrease in both overall muscle tension and core body temperature.\r\n\r\n \r\n\r\nIn terms of brain wave activity, stage 1 sleep is associated with both alpha and theta waves. The early portion of stage 1 sleep produces alpha waves<\/strong>, which are relatively low frequency (8\u201313Hz), high amplitude patterns of electrical activity (waves) that become synchronized. This pattern of brain wave activity resembles that of someone who is very relaxed, yet awake. As an individual continues through stage 1 sleep there is an increase in theta wave activity. Theta waves<\/strong> have an even lower frequency (4\u20137 Hz) and higher amplitude\u00a0than alpha waves.\r\n\r\n \r\n\r\nIt is relatively easy to wake someone from stage 1 sleep. In fact, if people are awoken during stage 1 sleep, they often report that they have not been asleep at all.\r\n\r\n[caption id=\"attachment_4348\" align=\"aligncenter\" width=\"586\"]\"EEG<\/a> Figure 1<\/strong>. Brainwave activity changes dramatically across the different stages of sleep.[\/caption]\r\n\r\n<\/section>
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Stage 2 sleep<\/h3>\r\nAs we move into stage 2 sleep<\/strong>, the body goes into a state of deep relaxation. Theta waves still dominate the activity of the brain, but they are interrupted by brief bursts of activity known as sleep spindles (Figure 3). A sleep spindle<\/strong> is a rapid burst of higher frequency brain waves that may be important for learning and memory (Fogel & Smith, 2011; Poe, Walsh, & Bjorness, 2010). In addition, the appearance of K-complexes is often associated with stage 2 sleep. A K-complex<\/strong> is a very high amplitude pattern of brain activity that may in some cases occur in response to environmental stimuli. Thus, K-complexes might serve as a bridge to higher levels of arousal in response to what is going on in our environments (Hal\u00e1sz, 1993; Steriade & Amzica, 1998).\r\n
\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"487\"]\"A Figure 3<\/strong>. Stage 2 sleep is characterized by the appearance of both sleep spindles and K-complexes.[\/caption]<\/figure>\r\n \r\n\r\n<\/section>
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Stage 3 sleep<\/h3>\r\n
Stage 3\u00a0sleep<\/strong> is often referred to as deep sleep or slow-wave sleep because\u00a0it is characterized by low frequency (less than 3 Hz), high amplitude delta waves<\/strong> (Figure 4). During this time, an individual\u2019s heart rate and respiration slow dramatically. It is much more difficult to awaken someone from sleep during stage 3 than during earlier stages. Interestingly, individuals who have increased levels of alpha brain wave activity (more often associated with wakefulness and the transition into stage 1 sleep) during stage 3 often report that they do not feel refreshed upon waking, regardless of how long they slept (Stone, Taylor, McCrae, Kalsekar, & Lichstein, 2008).\r\n\r\n[caption id=\"attachment_4350\" align=\"aligncenter\" width=\"396\"]\"Polysonograph<\/a> Figure 4<\/strong>. Delta waves, which are low frequency and high amplitude, characterize slow-wave stage 3 sleep.[\/caption]\r\n
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[ohm2_question height=\"550\"]3966[\/ohm2_question]<\/section><\/section>
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REM Sleep<\/h2>\r\n
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REM sleep<\/h3>\r\nREM sleep<\/strong> is marked by rapid movements of the eyes. The brain waves associated with this stage of sleep are very similar to those observed when a person is awake, as shown in Figure 5, and this is the period of sleep in which dreaming occurs. It is also associated with paralysis of muscle systems in the body with the exception of those that make circulation and respiration possible. Therefore, no movement of voluntary muscles occurs during REM sleep in a normal individual. REM sleep is often referred to as paradoxical sleep because of this combination of high brain activity and\u00a0muscular paralysis.\u00a0Like NREM sleep, REM has been implicated in various aspects of learning and memory (Wagner, Gais, & Born, 2001), although there is disagreement within the scientific community about how important both NREM and REM sleep are for normal learning and memory (Siegel, 2001).\r\n\r\n[caption id=\"attachment_4351\" align=\"aligncenter\" width=\"456\"]\"Polysonograph<\/a> Figure 5<\/strong>. A period of rapid eye movement is marked by the short red line segment. The brain waves associated with REM sleep, outlined in the red box, look very similar to those seen during wakefulness.[\/caption]\r\n\r\n<\/section>\r\n
<\/figure>\r\nIf people are deprived of\u00a0REM sleep<\/span>\u00a0and then allowed to\u00a0sleep<\/span>\u00a0without disturbance, they will spend more time in\u00a0REM sleep<\/span> in what appears to be an effort to recoup the lost time in REM<\/span>. This is known as the\u00a0REM rebound<\/span>, and it suggests that\u00a0REM sleep<\/span>\u00a0is also homeostatically regulated.\r\n\r\nAside from the role that\u00a0REM sleep<\/span>\u00a0may play in processes related to learning and memory,\u00a0REM sleep<\/span>\u00a0may also be involved in emotional processing and regulation. In such instances,\u00a0REM rebound<\/span> may actually represent an adaptive response to stress in nondepressed individuals by suppressing the emotional salience of stressful events that happened during the day (Suchecki, Tiba, & Machado, 2012). Though sleep<\/span> deprivation in general is associated with a number of negative consequences (Brown, 2012), there is a correlation between more REM sleep and psychiatric disorders, particularly depression. In fact, antidepressents often disrupt REM sleep and some studies show that REM sleep deprivation can improve symptoms of depression.[footnote]Cri\u0219an, C. A., Milhem, Z., Stretea, R., \u021aa\u021ba, I., Chereche\u0219, R. M., & Miclu\u021bia, I. V. (2023). A Narrative Review on REM Sleep Deprivation: A Promising Non-Pharmaceutical Alternative for Treating Endogenous Depression. Journal of Personalized Medicine, 13(2), 306. https:\/\/doi.org\/10.3390\/jpm13020306[\/footnote]\r\n\r\n[caption id=\"attachment_4988\" align=\"aligncenter\" width=\"849\"]\"This Figure 6<\/strong>. This hypnogram illustrates how an individual moves through the various stages of sleep. Deeper NREM sleep occurs early on in the night, while the duration of REM sleep increases as the night progresses. The amount of time spent in each stage varies, but generally Stage 1 sleep is only 5% of the night, while Stage 2 is roughly 50% of sleep, and Stage 3 and REM sleep are each approximately 20-25% of the night.\u00a0[\/caption]\r\n\r\n
[ohm2_question height=\"950\"]3967[\/ohm2_question]<\/section><\/section>","rendered":"

Stages of Sleep<\/h2>\n

Sleep is not a uniform state of being. Instead, sleep is composed of several different stages that can be differentiated from one another by the patterns of brain wave activity that occur during each stage. These changes in brain wave activity can be visualized using an electroencephalogram (EEG) and are distinguished from one another by both the frequency and amplitude of brain waves. Sleep can be divided into two different general phases: REM sleep and non-REM (NREM) sleep. An electroencephalograph (EEG) measures electrical potentials across the surface of the scalp which are the result of neural activity within the brain.<\/p>\n

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REM sleep and non-REM (NREM) sleep<\/h3>\n

Rapid eye movement (REM) sleep<\/strong> is characterized by darting movements of the eyes under closed eyelids. Brain waves during REM sleep appear very similar to brain waves during wakefulness.<\/p>\n

 <\/p>\n

In contrast, non-REM (NREM) sleep<\/strong> is subdivided into three\u00a0stages distinguished from each other and from wakefulness by characteristic patterns of brain waves.<\/p>\n<\/section>\n

The first three stages of sleep are NREM sleep, while the fourth and final stage of sleep is REM sleep.<\/p>\n

NREM Sleep<\/h2>\n
The first stage of NREM sleep is known as stage 1 sleep.<\/p>\n
\n

Stage 1 sleep<\/h3>\n

Stage 1 sleep<\/strong> is a transitional phase that occurs between wakefulness and sleep.\u00a0This corresponds to the period during which we drift off to sleep. During this time, respiration and heart rates slow. In addition, stage 1 sleep involves a marked decrease in both overall muscle tension and core body temperature.<\/p>\n

 <\/p>\n

In terms of brain wave activity, stage 1 sleep is associated with both alpha and theta waves. The early portion of stage 1 sleep produces alpha waves<\/strong>, which are relatively low frequency (8\u201313Hz), high amplitude patterns of electrical activity (waves) that become synchronized. This pattern of brain wave activity resembles that of someone who is very relaxed, yet awake. As an individual continues through stage 1 sleep there is an increase in theta wave activity. Theta waves<\/strong> have an even lower frequency (4\u20137 Hz) and higher amplitude\u00a0than alpha waves.<\/p>\n

 <\/p>\n

It is relatively easy to wake someone from stage 1 sleep. In fact, if people are awoken during stage 1 sleep, they often report that they have not been asleep at all.<\/p>\n

\"EEG<\/a>
Figure 1<\/strong>. Brainwave activity changes dramatically across the different stages of sleep.<\/figcaption><\/figure>\n<\/section>\n
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Stage 2 sleep<\/h3>\n

As we move into stage 2 sleep<\/strong>, the body goes into a state of deep relaxation. Theta waves still dominate the activity of the brain, but they are interrupted by brief bursts of activity known as sleep spindles (Figure 3). A sleep spindle<\/strong> is a rapid burst of higher frequency brain waves that may be important for learning and memory (Fogel & Smith, 2011; Poe, Walsh, & Bjorness, 2010). In addition, the appearance of K-complexes is often associated with stage 2 sleep. A K-complex<\/strong> is a very high amplitude pattern of brain activity that may in some cases occur in response to environmental stimuli. Thus, K-complexes might serve as a bridge to higher levels of arousal in response to what is going on in our environments (Hal\u00e1sz, 1993; Steriade & Amzica, 1998).<\/p>\n

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\"A
Figure 3<\/strong>. Stage 2 sleep is characterized by the appearance of both sleep spindles and K-complexes.<\/figcaption><\/figure>\n<\/figure>\n

 <\/p>\n<\/section>\n

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Stage 3 sleep<\/h3>\n
Stage 3\u00a0sleep<\/strong> is often referred to as deep sleep or slow-wave sleep because\u00a0it is characterized by low frequency (less than 3 Hz), high amplitude delta waves<\/strong> (Figure 4). During this time, an individual\u2019s heart rate and respiration slow dramatically. It is much more difficult to awaken someone from sleep during stage 3 than during earlier stages. Interestingly, individuals who have increased levels of alpha brain wave activity (more often associated with wakefulness and the transition into stage 1 sleep) during stage 3 often report that they do not feel refreshed upon waking, regardless of how long they slept (Stone, Taylor, McCrae, Kalsekar, & Lichstein, 2008).<\/p>\n
\"Polysonograph<\/a>
Figure 4<\/strong>. Delta waves, which are low frequency and high amplitude, characterize slow-wave stage 3 sleep.<\/figcaption><\/figure>\n
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