Our bodies require sleep in order to maintain proper
function and health. In
fact, we are programmed to sleep each night as a means of
restoring our
bodies and minds. Two interacting systems—the internal
biological clock
and the sleep-wake
homeostat—largely determine the timing
of our
transitions from wakefulness to sleep and vice versa. These
two factors
also explain why, under normal conditions, we typically stay
awake during
the day and sleep at night. But what exactly happens when we
drift off to
sleep?
regarded sleep as an inactive brain state. It was generally
accepted that as
night fell and sensory inputs from the environment
diminished, so too did
brain function. In essence, scientists thought that the
brain simply shut
down during sleep, only to restart again when morning came.
In 1929, an invention that enabled scientists to record
brain activity
challenged this way of thinking. From recordings known as
electroencephalograms (EEGs), researchers could see that
sleep was a
dynamic behavior, one in which the brain was highly active
at times, and
not turned off at all. Over time, sleep studies using EEGs
and other
instruments that measured eye movements and muscle activity
would
reveal two main types of sleep. These were defined by
characteristic
electrical patterns in a sleeping person's brain, as well as
the presence or
absence of eye movements.
The two main types of sleep are rapid-eye-movement (REM)
sleep and
non-rapid-eye-movement (NREM) sleep. On an EEG, REM sleep,
often
called "active sleep," is identifiable by its
characteristic low- amplitude
(small), high-frequency (fast) waves and alpha rhythm, as
well as the eye
movements for which it is named. Many sleep experts think
that these eye
movements are in some way related to dreams. Typically, when
people are
awakened from REM sleep, they report that they had been
dreaming, often
extremely vivid and sometimes bizarre dreams. In contrast,
people report
dreaming far less frequently when awakened from NREM sleep.
Interestingly, during REM sleep muscles in the arms and legs
are
temporarily paralyzed. This is thought to be a neurological
barrier that
prevents us from "acting out" our dreams.
NREM sleep can be broken down into three distinct stages:
N1, N2, and
N3. In the progression from stage N1 to N3, brain waves
become slower
and more synchronized, and the eyes remain still. In stage
N3, the deepest
stage of NREM, EEGs reveal high-amplitude (large),
low-frequency (slow)
waves and spindles. This stage is referred to as
"deep" or "slow-wave"
sleep.
Cycling at Night
In healthy adults, sleep typically begins with NREM sleep.
The pattern of
clear rhythmic alpha activity associated with wakefulness
gives way to N1,
the first stage of sleep, which is defined by a low-voltage,
mixed-frequency
pattern. The transition from wakefulness to N1 occurs
seconds to minutes
after the start of the slow eye movements seen when a person
first begins
to nod off. This first period of N1 typically lasts just one
to seven minutes.
The second stage, or N2, which is signaled by sleep spindles
and/or K
complexes in the EEG recording, comes next and generally
lasts 10 to 25
minutes. As N2 sleep progresses, there is a gradual
appearance of the
high-voltage, slow-wave activity characteristic of N3, the
third stage of
NREM sleep. This stage, which generally lasts 20 to 40
minutes, is referred
to as "slow-wave," " delta," or
"deep" sleep. As NREM sleep progresses, the
brain becomes less responsive to external stimuli, and it
becomes
increasingly difficult to awaken an individual from sleep.
Following the N3 stage of sleep, a series of body movements
usually
signals an "ascent" to lighter NREM sleep stages.
Typically, a 5- to 10-
minute period of N2 precedes the initial REM sleep episode.
REM sleep
comprises about 20 to 25 percent of total sleep in typical
healthy adults.
NREM sleep and REM sleep continue to alternate through the
night in a
cyclical fashion. Most slow-wave NREM sleep occurs in the first
part of the
night; REM sleep episodes, the first of which may last only
one to five
minutes, generally become longer through the night. During a
typical night,
N3 sleep occupies less time in the second cycle than the
first and may
disappear altogether from later cycles. The average length
of the first
NREM-REM sleep cycle is between 70 and 100 minutes; the
average length
of the second and later cycles is about 90 to 120 minutes.
The reason for
such a specific cycling pattern of NREM and REM sleep across
the night is
unknown. Some scientists speculate that specific sequences
of NREM and
REM sleep optimize both physical and mental recuperation as
well as some
aspects of memory consolidation that occur during sleep, but
this has not
been confirmed.
Shifting Sleep
Patterns
Sleep patterns can be affected by many factors, including
age, the amount
of recent sleep or wakefulness, the time of the day or night
relative to an
individual’s internal
clock, other behaviors prior to sleep such as exercise,
stress, environmental conditions such as temperature and
light, and various
chemicals.
For example, for the first year of life, sleep often begins
in the REM state.
The cyclical alternation of NREM-REM sleep in newborns is
present from
birth but at 50 to 60 minutes is much shorter than the
90-minute cycles
that occur in adults. Consolidated nocturnal sleep and fully
developed EEG
patterns of the NREM sleep stages emerge only after two to
six months.
Slow-wave sleep is greatest in young children and it
decreases steadily
with age, even if sleep duration does not change. This may
be related to
changes in the structure and function of the brain.
Sleep history—the
quantity and quality of an individual’s
sleep in recent
days—can also
have dramatic effects on sleep patterns. Repeatedly
missing a night’s
sleep, an irregular sleep schedule, or frequent disturbance
of sleep can result in a redistribution of sleep stages, for
instance,
prolonged and deeper periods of slow-wave NREM sleep. Drugs
may affect
sleep stages as well. For example, alcohol before sleep
tends to suppress
REM sleep early in the night. As the alcohol is metabolized
later in the
night, REM sleep rebounds. However, awakenings also become
more
frequent during this time.
Daytime Napping
Although it is common for people in many western societies
to sleep in a
single consolidated block of about eight hours during the
night, this is by
no means the only sleep pattern. In fact, following this
schedule and
foregoing an afternoon nap would seem highly abnormal to
many people
around the world.
In many cultures, particularly those with roots in tropical
regions, afternoon
napping is commonplace and is built into daily routines. And
although the
exact timing of naps is not officially scheduled, it is not
uncommon for
stores and government offices to close and for many
activities to stop for
an hour or two every afternoon.
Afternoon naptime typically coincides with a brief lag in
the body's internal
alerting signal. This signal, which increases throughout the
day to offset
the body's increasing drive to sleep, wanes slightly in
mid-afternoon, giving
sleep drive a slight edge. Napping also typically happens
during the
warmest period of the day and generally follows a large
mid-day meal,
which explains why afternoon sleepiness is so often
associated with warm
afternoon sun and heavy lunches.
Afternoon naps for most people typically last between 30 and
60 minutes.
Any longer and there is a risk of falling into deep sleep
and having a
difficult time waking. Following a nap, having dissipated
some of the
accumulated sleep drive, many people report feeling better
able to stay
awake and alert in the late afternoon and evening. This
increased alertness
typically causes people to go to bed later and generally to
sleep less at
night than people who do not take naps.
According to sleep experts, napping can be a good way for
people who do
not sleep well at night to catch up. They do caution,
however, that people
with insomnia may make their nighttime sleep problem worse
by sleeping
during the day. Otherwise, they generally recommend naps for
people who
feel they benefit from them.
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