Psychology: States of Consciousness PDF

Summary

This document is chapter six of a psychology textbook, covering states of consciousness including normal waking consciousness, altered states of consciousness, circadian rhythms, sleep and dreaming, and hypnosis.

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CHAPTER

6
CHAPTER
OUTLINE

States of Consciousness
THE PUZZLE OF CONSCIOUSNESS

DRUGS AND ALTERED CONSCIOUSNESS

Measuring States of Consciousness
Levels of Consciousness: Psychodynamic and Cognitive
Perspectives

Drugs and the Brain
Tolerance and Withdrawal
Depressants

Frontiers: Detecting Awareness

Research Foundations: Drinking and Driving: Decision
Making in Altered States

The Neural Basis of Consciousness

CIRCADIAN RHYTHMS: OUR DAILY BIOLOGICAL
CLOCKS
Keeping Time: Brain and Environment
Environmental Disruptions of Circadian Rhythms

Applications: Outsmarting Winter Depression, Jet Lag,
and Night Shiftwork Disruptions
SLEEP AND DREAMING
Stages of Sleep
Getting a Night’s Sleep: Brain and Environment
How Much Do We Sleep?
Sleep Deprivation
Why Do We Sleep?
Sleep Disorders
The Nature of Dreams

Stimulants
Opiates
Hallucinogens
Marijuana
From Genes to Culture: Determinants of Drug Effects

HYPNOSIS
The Scientific Study of Hypnosis
Hypnotic Behaviours and Experiences

Focus on Neuroscience: The Neuroscience of
Meditation
Theories of Hypnosis

SOME FINAL THOUGHTS

Our normal waking consciousness is but one special type of consciousness,
whilst all about it, parted from it by the filmiest of screens, there lie
potential forms of consciousness entirely different.
—William James

What are the issues
here?
What do we need to
know?
Where can we find the
information to answer
these questions?

Lee Hadwin is a nurse from North Wales. But he is
better known as “Klpasso,” the artist who produces
pencil drawings and works of fantasy. Lee does not
know how he produces such work, because he can only
draw at night when he is asleep. When awake, Lee has no
artistic ability at all and is dumbfounded at the pieces he produces
during the night.
Hadwin has been sleepwalking since he was four years old and
began to draw works of art sometime in his teens. He now leaves

art supplies out at night and routinely draws for 20 to 90 minutes. He awakes with a severe migraine, feeling
totally exhausted.
He has been offered $7500 for one of his works, and he recently placed his entire collection of 100 pieces
for sale on eBay. The asking price is $1.9 million.

lthough the experience of Lee Hadwin is
unusual, it demonstrates the surprising
complexity of our conscious experience. We
all drift into and out of various states of consciousness. By state of consciousness, psychologists mean
a pattern of subjective experience, a way of experiencing internal and external events. You will also
encounter the phrase altered state of consciousness,
which refers to variations from our normal waking
state. While daydreaming or passing from wakefulness to sleep, we may experience vivid images,
and our nighttime dreams can seem just as real and
emotionally charged as our waking perceptions.
We also experience divisions of awareness. Consider this: Why don’t you fall out of bed at night?
You are not consciously aware of major postural
shifts while soundly asleep, yet a part of you somehow knows where the edge of the bed is. Similarly,
have you ever “spaced out” while driving, deeply

A

engrossed in thought? Suddenly you snap out of
it, with no memory of the kilometres just driven.
While you were consciously focused inward, some
part of you kept track of the road and controlled
your responses at the wheel.
Philosopher David Chalmers (1995) notes, “Conscious experience is at once the most familiar thing
in the world and the most mysterious.” As we shall
see, its mysteries span a range from normal waking states to sleep and dreams, drug-induced experiences, hypnosis, and beyond. When psychology was
founded in the late 1800s, its “Great Project” was
to scientifically unravel some of the puzzles of consciousness (Natsoulas, 1999). This interest waned
during behaviourism’s dominance in the mid-20th
century, but resurgence of the cognitive and biological perspectives has sparked new research, forcing
us to rethink long-standing conceptions about the
mind (Figure 6.1).

(a)

(b)

FIGURE 6.1 (a) During a Sufi religious ceremony in Istanbul, Turkey, whirling dervishes perform a spinning dance—a prayer in
motion—that induces an altered state of consciousness. (b) Buddhists believe that meditation produces inner peace, facilitates insight and
enlightenment, and opens a path to different dimensions of consciousness.

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CHAPTER SIX

THE PUZZLE OF
CONSCIOUSNESS
1. Describe some basic
characteristics of
consciousness.

2. How do psychologists
measure states of
consciousness?

What is consciousness, and how does it arise? In
psychology, consciousness often is defined as our
moment-to-moment awareness of ourselves and
our environment. Among its characteristics, consciousness is
• subjective and private. Other people cannot
directly know what reality is for you, nor can
you enter directly into their experiences. As the
author Charles Dickens observed, “Every human
creature is constituted to be that profound secret
and mystery to every other.”
• dynamic (ever-changing). We drift in and out of
various states throughout each day. Although
the stimuli of which we are aware constantly
change, we typically experience consciousness as
a continuously flowing “stream” of mental activity, rather than as disjointed perceptions and
thoughts (James, 1890/1950).
• self-reflective and central to our sense of self. The
mind is aware of its own consciousness. Thus,
no matter what your awareness is focused on—a
lovely sunset or an itch on your back—you can
reflect on the fact that “you” are the one who is
conscious of it.
Finally, consciousness is intimately connected
with the process of selective attention, as discussed in

Chapter 5. William James noted that “the mind is at
every stage a theatre of simultaneous possibilities.
Consciousness consists in . . . the selection of some,
and the suppression of the rest by the . . . agency of
Attention” (1879, p. 13). Selective attention focuses
conscious awareness on some stimuli to the exclusion of others. If the mind is a theatre of mental
activity, then consciousness reflects whatever is illuminated at the moment—the “bright spot on the
stage”—and selective attention is the “spotlight” or
mechanism behind it (Baars, 2007).

Measuring States of Consciousness
Scientists who study consciousness must find ways
to operationally define private inner states in terms
of measurable responses. The most common measure is self-report, in which people describe their
inner experiences. Self-reports offer the most direct
insight into a person’s subjective experiences, but
they are not always verifiable. In contrast, physiological measures establish the correspondence
between bodily states and mental processes. For
example, EEG recordings of brain activity help to
identify different stages of sleep throughout the
night. Physiological measures are objective but cannot tell us what a person is experiencing subjectively. Behavioural measures also are used, including
performance on special tasks, such as the rouge test
(Figure 6.2). Behavioural measures are objective,
but we still must infer the person’s (or chimp’s) state

FIGURE 6.2 Gordon Gallup (1970) exposed four chimps to a mirror. By day three, they used it to inspect hard-to-see parts of their own
bodies and began making odd faces at themselves in the mirror. To further test whether the chimps knew the mirror images were their own
reflections, Gordon anaesthetized them and put a red mark on their faces. Later, with no mirror, the chimps rarely touched the red mark. But
on seeing the mark when a mirror was introduced, they touched the red spot on their face almost 30 times in 30 minutes, suggesting that the
chimps had some self-awareness. Using a similar test in which a red rouge mark is placed on the tip of an infant’s nose, researchers find that
infants begin to recognize themselves in a mirror at around 18 months of age.

States of Consciousness

of mind. As you will discover in this chapter’s Focus
on Neuroscience feature, progress is being made in
the study of alterations in brain activity that accompany meditation.

Levels of Consciousness: Psychodynamic
and Cognitive Perspectives
A century ago, Sigmund Freud (1900/1953) proposed that the human mind consists of three levels
of awareness. The conscious mind contains thoughts,
perceptions, and other mental events of which we are
currently aware. Preconscious mental events are outside current awareness, but can easily be recalled under
certain conditions. For instance, you may not have
thought about a childhood friend for years, but when
someone mentions your friend’s name, you become
aware of pleasant memories. Unconscious events cannot be brought into conscious awareness under ordinary circumstances. Some unconscious content—such
as unacceptable urges and desires stemming from
instinctive sexual and aggressive drives, traumatic
memories, and threatening emotional conflict—is
kept out of conscious awareness because it would
arouse anxiety, guilt, or other negative emotions.
Behaviourists roundly criticized Freud’s model.
After all, they sought to explain behaviour without invoking conscious mental processes, much
less unconscious ones. Cognitive psychologists and
many contemporary psychodynamic psychologists also take issue with specific aspects of Freud’s
model, which we describe more fully in Chapter 14.
As psychodynamic psychologist Drew Westen
(1998, p. 333) notes, “Many aspects of Freudian
theory are indeed out of date, and they should be.
Freud died in 1939, and he has been slow to undertake further revisions.”
On a broad level, however, research strongly
supports Freud’s general premise: Nonconscious
processes influence behaviour (Dimberg et al.,
2000; Westen, 1998). Studies of placebo effects (see
Chapter 2), split-brain patients (see Chapter 3), subliminal perception (see Chapter 5), and phenomena
that you will encounter in upcoming chapters all indicate that mental processes can affect our behaviour
without conscious awareness (Kirsch & Lynn, 1999).

The Cognitive Viewpoint
Cognitive psychologists reject the notion of an
unconscious mind driven by instinctive urges and
repressed conflicts. Rather, they view conscious and
unconscious mental life as complementary forms
of information processing (Hassin et al., 2005).
As Daniel Reisberg (1997, p. 601) notes, unconscious mental activity is “not an adversary to the
conscious mind. Instead, the cognitive unconscious

185

functions as a sophisticated support service, working in harmony with our conscious thoughts.” To
illustrate, consider how we perform everyday tasks.
Controlled versus automatic processing. Many
activities, such as planning a vacation or studying,
involve controlled (effortful) processing, the voluntary use of attention and conscious effort. Other
activities involve automatic processing and can be
performed with little or no conscious effort. Automatic processing occurs most often when we carry
out routine actions or well-learned tasks. Learning
to type, drive, and eat with utensils all involve controlled processing; you have to pay a lot of attention
to what you are doing. With practice, performance
becomes more automatic and brain areas involved
in conscious thought become less active (Saling &
Phillips, 2007). Through years of practice, typists,
athletes, and musicians program themselves to execute highly complex skills with a minimum of conscious thought.
Automatic processing, however, has a key disadvantage: It can reduce our chances of finding
new ways to approach problems (Langer, 1989).
Controlled processing is more flexible and open
to change. Still, automatic processing offers speed
and economy of effort, and in everyday life most
actions may be processed this way (Bargh & Chartrand, 1999). In fact, many well-learned behaviours
seem performed best when our mind is on “autopilot,”
with controlled processing taking a backseat. The
famous baseball player Yogi Berra captured this
idea in his classic statement that “You can’t think
and hit at the same time.” At tasks ranging from golf
putting to video-game playing, experiments suggest
that too much self-focused thinking can hurt task
performance and cause people to “choke” under
pressure (Beilcock & Carr, 2001).
Divided attention. Automatic processing also facilitates divided attention, the ability to perform more
than one activity at the same time. We can talk while
we walk, type as we read, eat while watching TV, and
so on. Without the capacity to divide attention, every
act would require our full attention and quickly overwhelm our mental capacity. Yet divided attention has
limits, and is more difficult when tasks require similar
mental resources (Reisberg, 1997). For example, the
shadowing experiments described in Chapter 5 indicate that we cannot attend fully to separate messages
delivered simultaneously through two earphones.
Although divided attention is wonderfully adaptive most of the time, it can have serious negative
consequences in certain situations (Figure 6.3). For
example, some studies have found that collision rates
triple or quadruple when people talk on the telephone while driving; they are more likely to speed,

3. Explain Freud’s
three-level model of
consciousness.

4. How do cognitive
psychologists view
the unconscious?
5. What is automatic
processing, and why is
it important?

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CHAPTER SIX

Frontiers
DETECTING AWARENESS
It reads like the plot for a horror movie or a short story by
Edgar Allen Poe: As a result of brain injury, a person is rendered immobile and unresponsive, but is still conscious and
aware of the surroundings, trapped inside his or her head,
unable to move or communicate. Adrian Owen and his colleagues have been investigating whether such patients exist.
He studies patients who have sustained brain injuries that
result in what is called a vegetative state, or a minimally conscious state. The term “vegetative state” refers to a condition in which the individual appears to be awake, but shows
no evidence of awareness (Figure 6.4). These patients have
a sleep-wake cycle and when their eyes are open they may
show simple behaviours such random eye movements, but
they do not respond to sight, sound, or touch. That is, they
appear to be awake but completely unaware. If these patients
are conscious, how could you tell? How do you communicate
with someone who cannot move or speak?
While he was at the University of Cambridge, Owen
began his ground-breaking and controversial work with the
study of a 26-year-old patient named Kate Bainbridge. Kate
had been in a coma due to a viral infection. When the infection cleared and she came out of the coma, she entered a
vegetative state. When you see a familiar face, an area of
the temporal cortex called the fusiform face area (FFA) is
activated. Owen tested Kate by showing her familiar faces

while performing a PET scan. Amazingly, her FFA showed
increased activity, just as you would expect if someone saw
and recognized the faces (Menon et al., 1998). Kate was
found to have significant brain function and responded well
to rehabilitation; she is now in a wheelchair but otherwise
active.
An important next step came when Owen and his team
worked with a 24-year-old man, referred to as Patient 23
(Owen et al., 2006). Patient 23 had been in a vegetative state
for five years after suffering brain damage in a car accident.
When you imagine playing tennis and when you imagine
finding your way around your house, different parts of your
brain become active. Owen and his team used this finding
with Patient 23. They told him to imagine playing tennis for
“yes,” and to imagine moving around his house for “no.”
Owen put Patient 23 into an fMRI and asked him questions.
Incredibly, he answered: “Is your father’s name Thomas?” No.
“Is your father’s name Alexander?” Yes. “Do you have any
brothers?” Yes. “Do you have any sisters?” No (Owen et al.,
2006). It was the first time anyone had communicated with a
patient in a vegetative state.
Owen, now at the University of Western Ontario, is working to repeat the fMRI findings using an EEG (Cruse et al.,
2012). Although an EEG does not have the precision of an
fMRI and cannot measure activity deep within the brain, it
is inexpensive, easy to use, and relatively portable. Developing techniques that allow answers to be detected with an
continued

less space between their cars and the cars in front
of them and, especially during long conversations,
they drive faster (Rosenbloom, 2006). Even the use
of a hands-free cellphone has an impact: braking is
delayed, the degree of braking is reduced, and anticipation of upcoming events is degraded (Treffner &
Barrett, 2004), all of which are changes that would be
expected to increase the chance of an accident.

The Emotional Unconscious
6. Can nonconscious
processes influence
emotional responses?

FIGURE 6.3 In 2003 it became illegal in Newfoundland and
Labrador to use a hand-held cellphone while driving. Since then,
all Canadian provinces have adopted a ban on the use of cellphones
while driving, while some, such as British Columbia and Ontario,
banned all hand-held devices while driving.
drive on the wrong side of the road, run off the road,
hit fixed objects, and overturn their cars (Redelmeier
& Tibshirani, 1997; Violanti & Marshall, 1996). While
engaged in a cellphone conversation, drivers leave

Some modern psychodynamic views incorporate
information-processing concepts from cognitive
psychology but strongly emphasize that emotional
and motivational processes also operate unconsciously and influence behaviour (Gillett, 1997;
Westen, 1998). The results of numerous experiments have strengthened the view that unconscious
processes can have an emotional and motivational
flavour (LeDoux, 2000). For example, have you
ever been in a bad mood or a good mood, without
knowing why you were feeling that way? Perhaps, as
Bargh and Chartrand (1999) propose, it is because

States of Consciousness

EEG would allow faster, less expensive, bedside testing of
vegetative patients. For patients far from the large medical
centres that have expensive fMRI equipment and the highly
trained personnel to perform the scans, an EEG may be a
viable option.
Recently, Owen and his team reported a stunning breakthrough while working with normal healthy volunteers (Naci
et al., 2013). Participants were asked to concentrate on “yes”
or “no” to simple yes-or-no questions such as “Do you have
brothers and sisters?” or “Are you younger than 21?” Using
fMRI scans, researchers were able to identify answers with
90 percent accuracy. That is, participants could respond by
concentrating on “yes” or “no,” rather than using some
other mental activity as a code, and the researchers could
correctly identify what the participant had been thinking
90 percent of the time. Owen and his team are beginning
to use this method to attempt communication with patients
diagnosed as being in a vegetative state.
Owen’s work has implications for diagnosis, clinical
care and rehabilitation, medical ethics, and medical/
legal decision making, but his findings and interpretation
are controversial (Cyranoski, 2012). Some disagree with
Owen’s conclusion that these patients are conscious; they
argue that responses are not a sign of consciousness but
are involuntary and reflexive. Others object to what they
consider too simple a view of consciousness. Disorders
of consciousness, including vegetative state, are some
of the least understood of all disorders. Owen’s findings

you were influenced by events in your environment
of which you were not consciously aware.
In one study, Chartrand and Bargh (2002) subliminally presented university students with nouns
that were either strongly negative (e.g., cancer,
cockroach), mildly negative (e.g., Monday, worm),
mildly positive (e.g., parade, clown), or strongly
positive (e.g., friends, music). Later, students rated
their mood on standard psychological inventories.
Although they were not consciously aware of seeing
the nouns, those shown the strongly negative words
displayed the saddest mood, whereas those who had
seen the strongly positive words reported the happiest mood. In Chapter 10, we explore other aspects of
the modern “emotional unconscious.”

The Neural Basis of Consciousness
Within our brains, where does consciousness arise?
And if no individual brain cell is conscious (as far
as we know), then how does brain activity produce
consciousness?

187

FIGURE 6.4 Patients in a vegetative state appear to be awake but show no
awareness of their surroundings, and do not respond to sight, sound, or touch.
Might some of these patients be conscious and aware, but unable to move or
respond?
suggest that some of these patients may be aware of
their surroundings and can communicate if the proper
techniques are used. In 2010, Kate Bainbridge, the first
vegetative state patient Adrian Owen tested more than
a decade earlier, wrote to him, “It scares me to think of
what might have happened to me if I had not had mine
[PET scan]. It was like magic, it found me” (Cyranoski,
2012, p.179).

Windows to the Brain
Some researchers have examined the brain functioning of patients who have disorders that impair
conscious perception. Two of these disorders are
visual agnosia and blindsight.
Visual agnosia is dramatically illustrated by the
case of D.F., as reported by University of Western Ontario psychologist Melvin Goodale (2000).
Due to carbon-monoxide exposure, D.F. lost consciousness and suffered brain damage. When she
regained consciousness, she was unable to recognize the faces of friends and relatives, and she could
not identify even simple objects by sight. She could
recogize peoples’ voices and recognize objects by
touch, but not sight. D.F.’s condition is called visual
agnosia, which is an inability to visually recognize
objects. If D.F. reaches for an object such as a coffee mug or a book, she orients her hand correctly,
opens her hand to the correct width, and grasps
the object with ease, even though she cannot identify what it is she was reaching for (Goodale, 2000;
Young, 2003).

188

CHAPTER SIX

7. According to the
modular model of
mind, how does
consciousness arise?

Brain imaging revealed that D.F.’s primary visual
cortex was largely undamaged from the carbonmonoxide exposure. Why, then, could she not consciously recognize objects and faces? The answer
rests on the idea that there are multiple brain pathways for processing visual information (Goodale,
2000). One pathway carries information to support
the unconscious guidance of movements, while
a second pathway carries information to support
brain areas that perform tasks related to perception, memory, emotion, and so on, and this pathway is accessible to conscious awareness (Gabbard
& Ammar, 2008; Goodale, 2000). D.F.’s nonconscious visual pathway used to guide movement was
intact, but part of the pathway that provides visual
information for consicous recognition of faces and
objects was damaged.
People with visual agnosia are not blind; they
can see and are aware of seeing, but they cannot
identify objects by sight. Conversely, patients with
blindsight will report that they cannot see. In special tests, however, a blindsight patient will respond
to visual stimuli (Kentridge et al., 2004). For example, a blindsight patient may be blind in the right
half of his or her visual field. If a stimulus such as
a photograph or a line is flashed on a screen so that
it appears within the patient’s blind visual field, the
person will report that he or she did not see anything. When asked to point to where the stimulus
was, blindsight patients will guess, but on some
tasks the accuracy of their “guesses” is as high as 80
to 100 percent (Radoeva et al., 2008). That is, they
have no conscious experience of seeing, but behave
as though the stimulus was perceived accurately. As

with visual agnosia, cases of blinsight demonstrate
that visual information can be processed and influence behaviour outside of conscious awareness.

Consciousness and the Modular Mind
Many neuroscientists believe that there is no single
place in the brain that gives rise to consciousness.
Instead, they view the mind as a collection of largely
separate but interacting information-processing
modules that perform tasks related to sensation,
perception, memory, movement, planning, problem solving, emotion, and so on. The modules
process information in parallel—that is, simultaneously and largely independently. However, there
also is cross-talk between them, as when the output from one module is carried by neural circuits
to provide input for another module, or a module
receives input from two independently functioning modules. For example, a formula recalled from
memory can become input for problem-solving
modules that allow you to compute answers during
a math exam.
According to one view, consciousness is a global
workspace that represents the unified activity of multiple modules in different areas of the brain (Baars,
2007). In essence, of the many brain modules and
connecting circuits that are active at any instant, a
particular subset becomes joined in unified activity
that is strong enough to become a conscious perception or thought (Koch, 2004). The specific modules
and circuits that make up this dominant subset can
vary as our brain responds to changing stimuli—
sights, sounds, smells, and so on—that compete for
conscious attention.

In Review
• Consciousness refers to our moment-tomoment awareness of ourselves and the environment. It is subjective, dynamic, self-reflective,
and central to our sense of identity. Selective
attention focuses conscious awareness on some
stimuli to the exclusion of others.
• Scientists use self-report, physiological, and
behavioural measures to operationally define
states of consciousness.
• Freud believed that the mind has conscious, preconscious, and unconscious levels. He viewed
the unconscious as a reservoir of unacceptable
desires and repressed experiences. Cognitive
psychologists view the unconscious as an information-processing system.

• Controlled processing typically is required for
learning new tasks. Automatic processing makes
divided attention possible, enabling us to perform several tasks at once. Research on subliminal perception and other topics suggests
that emotional and motivational processes
also can operate nonconsciously and influence
behaviour.
• Many theorists propose that the mind consists of
separate but interacting information-processing
modules. Our subjective experience of “unitary”
consciousness arises from the integrated output
of these modules.

States of Consciousness

Subjectively, of course, we experience consciousness as unitary, and not as a patchwork of different modules and circuits. This is somewhat akin to
listening to a choir sing. We are aware of the integrated, harmonious sound of the choir rather than
the voice of each individual member. As we will
explore in the rest of this chapter, many factors can
influence these modules and, in so doing, alter our
consciousness.

CIRCADIAN RHYTHMS: OUR
DAILY BIOLOGICAL CLOCKS
Like other animals, humans have adapted to a world
with a 24-hour day-night cycle. Every 24 hours, our
body temperature, certain hormonal secretions, and
other bodily functions undergo a rhythmic change
that affects our mental alertness and readies our
passage back and forth between states of wakefulness and sleep (Figure 6.5). These daily biological
cycles are called circadian rhythms (from the Latin
circa, “around,” and dia, “day”).

Keeping Time: Brain and Environment
Most circadian rhythms are regulated by the brain’s
suprachiasmatic nuclei (SCN), which are located
in the hypothalamus, as shown in Figure 6.6 (Miller
et al., 1996; Albrecht, 2004). Work by Martin Ralph,

(c)

Change in body
temperature (°C)

Plasma
melatonin pg/ml

(b)

60
50
40
30
20
10
0

Alertness

(a)

Awake
0.4
0.2
0.0
–0.2
–0.4

of the University of Toronto (Ralph et al., 1990, Ralph
et al., 1993) has confirmed that the SCN is indeed the
brain’s clock. Ralph transplanted normal, healthy SCN
neurons into the hypothalamus of animals whose
own SCN had been destroyed. The transplanted SCN
neurons restored circadian rhythms to the animals
that had lacked a healthy SCN (Ralph et al., 1990).
SCN neurons have a genetically programmed cycle
of activity and inactivity, functioning like a “biological clock.” They link to the tiny pineal gland, which
secretes melatonin, a hormone that has a relaxing
effect on the body. SCN neurons become active during daytime and reduce the pineal gland’s secretion of
melatonin, raising your body temperature and heightening alertness. At night SCN neurons are inactive,
allowing melatonin levels to increase and promoting
relaxation and sleepiness (Zee & Lu, 2008).
Our circadian clock is biological, but environmental factors such as the day-night cycle help to
keep SCN neurons on a 24-hour schedule (Lewy
et al., 1998; Wever, 1989). Your eyes have neural
connections to the SCN. After a night’s sleep, the
light of day increases SCN activity and helps to
reset your 24-hour biological clock. What would
happen if you lived in the dark, or in a laboratory
or an underground cave without clocks, and could
not tell whether it was day or night outside? Most
people drift into a longer “natural” cycle of about
24.2 to 24.8 hours, called a free-running circadian

Sleep

Awake

Sleep

High

Low
Noon

6 P.M.

Midnight 6 A.M.

Noon

6 P.M. Midnight 6 A.M.

Time of Day

FIGURE 6.5 Changes in our core body temperature (a), levels of melatonin in our blood (b), and degree of alertness/sleepiness (c) follow
a cyclical 24-hour pattern called a circadian rhythm. Humans also have longer and shorter biological cycles, such as the 28-day female menstrual cycle and a roughly 90-minute brain activity cycle during sleep.
Adapted from Monk et al., 1996.

189

8. How do the brain and
environment regulate
circadian rhythms?
9. What are free-running
circadian rhythms?

CHAPTER SIX

3.3

Morning students (“early birds”)
Evening students (“night owls”)

3.2
3.1
3.0
Grades

190

2.9
2.8
2.7

Hypothalamus
SCN
(regulates circadian
rhythms)

2.6
Pineal gland
(secretes melatonin)

FIGURE 6.6 The suprachiasmatic nuclei (SCN) are the brain’s
master circadian clock. Neurons in the SCN have a genetically programmed cycle of activity and inactivity, but daylight and darkness help
to regulate this cycle. The optic nerve links our eyes to the SCN, and SCN
activity affects the pineal gland’s secretion of melatonin. In turn, melatonin influences other brain systems governing alertness and sleepiness.
rhythm (Hillman et al., 1994; Shanahan et al., 1999;
Wever, 1989). Amazingly, SCN neurons exhibit this
longer cycle of firing even when they are surgically
removed from the brain and kept alive in a dish
containing nutrients (Gillette, 1986; Schibler, 2006).
Because their free-running circadian rhythm is
desynchronized (out of sync) with the 24-hour daynight cycle, participants in these “isolation studies”
tend to go to bed and wake up later each day. They do
not realize it, but within a few weeks they may be going
to bed at noon and awakening at midnight. Blind children and adults whose eyes are completely insensitive
to light also may experience free-running circadian
rhythms (Sack & Lewy, 1997). When they try to force
their sleep-wake cycle into the 24-hour world by going
to bed at fixed times, blind people often experience
insomnia, other sleep problems, and daytime fatigue.

Early Birds and Night Owls
Circadian rhythms influence our tendency to be
a “morning person” or a “night person” (Emens
et al., 2009). Compared to night people, morning
people go to bed and rise earlier, and their body
temperature, blood pressure, and alertness peak
earlier in the day. Studies around the globe indicate
that “morningness” is more common among older
adults, whereas more night people are found among
18- to 30-year-olds (Ishihara et al., 1992).
Cultures also differ in their overall tendency
toward “morningness.” Carlla Smith and her colleagues (2002) used questionnaires to measure the
degree of morningness among college students from
six countries. They found that students from Colombia, India, and Spain—regions with warmer annual

2.5
8 A.M.
classes

Later
classes

FIGURE 6.7 In a study of 454 University of Kansas students,
“night owls” struggled in their 8:00 A.M. classes, as compared with
“early birds.” In later classes the two groups performed more similarly. Stated differently, early birds did slightly better in their earliest
class than in later classes, whereas night owls did better in their
later rather than their earliest classes.
Data from Guthrie et al., 1995.

Thinking critically
EARLY BIRDS, CLIMATE, AND CULTURE
Is the study of morningness by Carlla Smith correlational or
experimental? What factors other than climate might explain
why people from warmer regions display greater morningness?
Think about it, and then see the Answers section at the end
of the book.

climates—exhibited greater morningness than students from England, the United States, and the
Netherlands. In university, morning people are more
likely to take very early classes than are night people
and, as Figure 6.7 shows, they perform better than
night people in early morning (8:00 a.m) classes.

Environmental Disruptions of Circadian
Rhythms
Gradual and sudden environmental changes can
disrupt our circadian rhythms. Seasonal affective
disorder (SAD) is a cyclic tendency to become psychologically depressed during certain months of
the year. Symptoms typically begin in fall or winter, which usher in shorter periods of daylight, and
then lift in spring (Rosenthal & Wehr, 1987; Sohn &
Lam, 2005). Many experts believe that the circadian
rhythms of SAD sufferers may be particularly sensitive to light, so as sunrises occur later in winter,
the daily “onset” time of their circadian clocks may

States of Consciousness

50°

45°

SAD

Winter
blues

7.2%

20.2%

6.1%

17.1%

5.0%

13.9%

3.9%

10.6%

2.8%

7.5%

40°
35°

30°

25°

FIGURE 6.8 The latitude puzzle. In North America, the prevalence of winter SAD and milder depression (“winter blues”) increases at
more northerly latitudes, where the hours of daylight diminish more severely in late fall and winter. SAD and “winter blues” rates of 9.2 percent
and 19.1 percent, respectively, have been found in Fairbanks, Alaska (648 latitude). Yet European studies report lower winter SAD rates and a
weaker SAD–latitude relation. In fact, most studies in Sweden, Norway, Finland, and Iceland (roughly 558 to 708 latitude) report winter SAD
rates similar to those in the southern United States (Mersch et al., 1999). At present, the reason for this discrepancy is debated.
12
Sleep duration (hours)

be pushed back to an unusual degree (Avery et al.,
1997; Teicher et al., 1997). In late fall and winter,
when many people must arise for work and school
in darkness, SAD sufferers are still in “sleepiness”
mode long after the alarm clock sounds in the
morning (Figure 6.8).
Jet lag is a sudden circadian disruption caused
by flying across several time zones in one day. Flying east, you “lose” hours from the day; flying west,
the travel day becomes longer than 24 hours. Jet
lag often causes insomnia, decreased alertness, and
poorer performance until the body readjusts. It is a
significant concern for businesspeople, athletes, airline crews, and others who frequently travel across
many time zones (Reilly, 2009). The body naturally
adjusts about one hour or less per day to time zone
changes. Typically, people adjust faster when flying
west, presumably because lengthening the travel day
is more compatible with our natural free-running
circadian cycle (Revel & Eastman, 2005).
The most problematic circadian disruption for
society is caused by night shiftwork. Adjusting to
an inverted night-day world can be difficult. Night
shiftworkers often drive home in morning daylight,
making it harder to reset their biological clocks
(Sasseville et al., 2009). On days off, they often fall
back into a day-night schedule to spend daytime
with family, which disrupts their hard-earned circadian adjustments. Over time, fatigue, stress, and the
likelihood of an accident increases (Folkard, 2008).
Our biological clocks promote sleepiness in the
early-morning hours (Akerstedt, 1988). Combined
with fatigue from poor daytime sleep, this earlymorning sleepiness can be a recipe for disaster.

Shift workers who
go to bed in midday
get little sleep

10
8
6
4

German
Japanese

2
0

12 A.M.

4 A.M.

8 A.M. Noon

4 P.M.

8 P.M. 12 A.M.

Bedtime

FIGURE 6.9 When night workers try to go to bed in midday,
they get little sleep. These data are based on 2322 German shiftworkers (purple line) and 3240 Japanese shiftworkers (green line)
who recorded their bedtimes and length of sleep.
From Monk et al., 1996.

Job performance errors, fatal traffic accidents, and
engineering and industrial disasters peak between
midnight and 6:00 a.m (Akerstedt et al., 2001).
On-the-job sleepiness is a major concern among
nighttime long-distance truck and bus drivers, locomotive engineers, airline crews, and medical doctors and nurses (Quera-Salva et al., 1997).
Some people adjust to night work, but others
never do. They become fatigued, stressed, and more
accident-prone on and off the job. You can see in
Figure 6.9 that, overall, nightworkers who try to go
to bed during the middle of the day get frightfully
little sleep. When work shifts change, it is easier
to extend the “waking day” than to compress it.

10. Explain how
SAD, jet lag, and
night shiftwork
involve circadian
disruptions.

191

192

CHAPTER SIX

Applications
OUTSMARTING WINTER DEPRESSION, JET
LAG, AND NIGHT SHIFTWORK DISRUPTIONS
Circadian research has provided important insight into the
nature of consciousness. It also has led to several treatments
for circadian disruptions affecting millions of people.

Controlling Exposure to Light
Treating SAD
Many experts believe that phototherapy, which involves properly timed exposure to bright artificial light, is the best treatment for SAD (Strong et al., 2009). Several hours of daily
phototherapy can shift circadian rhythms by as much as two
or three hours per day (Shanahan et al., 1999). Timo Partonen
(1994) found that, during Finland’s short winter days, phototherapy for just one hour a day over two weeks significantly
reduced SAD sufferers’ depression. In dawn simulation, artificial light gradually intensifies to normal light levels over the
course of one to two hours in the early morning, which helps
to reset the circadian clock to an earlier time. The fact that
phototherapy effectively treats SAD is the strongest evidence
that SAD is triggered by winter’s lack of sunlight, rather than
its colder temperatures (Figure 6.10).

up” to local time. (Think of morning light as “jump-starting”
your circadian clock at a time when you would be asleep back
at home.) Flying west, your body clock moves “ahead” of
local time, so to reduce jet lag you want to delay your circadian cycles. Avoiding bright light in the morning and exposing yourself to light in the afternoon or early evening will
do this. These are general rules, but the specific timing and
length of exposure to light depend on the number of time
zones crossed (Waterhouse & Reilly, 2009). For jet travellers,

Reducing Jet Lag
When you fly east across time zones, your body’s internal
clock “falls behind” the time at your destination. Exposure to
outdoor light in the morning—and avoiding light late in the
day—moves the circadian clock forward and helps it “catch

FIGURE 6.10 For many people, daily exposure to bright fluorescent lights
can reduce the depression accompanying seasonal affective disorder.
continued

A forward rotating work schedule that takes advantage of this is called rotating shiftwork.
One might wonder whether it takes large changes
in our schedules to disrupt our circadian rhythms,
or whether smaller changes can also have an impact
on our behaviour and our well-being. Stanley
Coren, of the University of British Columbia, analyzed reports of all accidental deaths in the United

States over a three-year period. Interestingly, he
found that the springtime shift to Daylight Savings
Time, when we all lose an hour’s sleep and have to
make a small adjustment to our circadian rhythms,
produced a short-lived increase in the likelihood of
accidental death (Coren, 1996b).
SAD, jet lag, night shiftwork, and even changing
to Daylight Savings Time all disrupt our circadian

In Review
• Circadian rhythms are 24-hour biological cycles
that help to regulate many bodily processes.
The suprachiasmatic nuclei (SCN) are the brain’s
master circadian clock. Environmental factors,
such as the day-night cycle, help to reset our
daily clocks to a 24-hour schedule.
• Circadian rhythms influence whether we are a
“morning person” or a “night person.”

• Seasonal affective disorder (SAD), jet lag, and
night shiftwork involve environmental disruptions of circadian rhythms. Treatments for circadian disruptions include controlling exposure to
light, oral melatonin, and regulating daily activity schedules.

States of Consciousness

spending time outside (even on cloudy days) is the easiest
way to get the needed exposure to light.

Adjusting to Nightwork
Many night employees work indoors, where the artificial
light is too weak to shift their circadian rhythms toward a
night-day schedule. Circadian adjustment can be increased
by having very bright indoor lighting at the workplace, keeping bedrooms dark and quiet to foster daytime sleep, and
maintaining a schedule of daytime sleep even during days off
(Boulos, 1998).

Melatonin Treatment: Uses and Cautions
Melatonin levels in the brain can be manipulated directly by
oral doses. Depending on when it is taken, oral melatonin can
shift some circadian cycles forward or backward by as much
as 30 to 60 minutes per day of use (Zhdanova & Wurtman,
1997). Melatonin treatment has been used to alleviate SAD,
decrease jet lag, and help employees adapt to night shiftwork
(Arendt, 2009; Lewy et al., 2006).
The availability of melatonin varies in different jurisdictions.
Melatonin is sold over-the-counter as a dietary supplement
in Canada and the United States. It is worth noting that substances sold as dietary supplements are not subject to the
same regulations about purity, exact dosage, safety, and efficacy as are drugs. Tablet doses are often 3 milligrams, producing melatonin levels in the blood that are more than 10 times
the normal concentration (Sack et al., 1997). In contrast,
doses of 0.1 to 0.5 milligrams used in research produce blood

rhythms and our behaviour. As explored in the
Applications feature, techniques are available to help
us normalize our circadian rhythms.

SLEEP AND DREAMING
Our circadian rhythms do not regulate sleep directly.
Rather, by decreasing nighttime alertness, they promote a readiness for sleep and help to determine
the optimal period when we can sleep most soundly
(Sack et al., 1998). We spend approximately a third
of our lives asleep, and it is easy to understand why
this state of altered consciousness has mystified
humans for ages. Each night we seem to relinquish
conscious control of our thoughts and actions, enter
a world of dreams, toss about and possibly mutter or
talk, but remember little of it upon awakening. Yet
sleep is a behaviour that, like others, can be studied
scientifically at biological, psychological, and environmental levels.

193

concentrations more typical of normal levels and are sufficient
to produce circadian shifts.
Taking melatonin at the wrong time can backfire and make
circadian adjustments more difficult. Experts are also concerned
that millions of people are using melatonin tablets as a nightly
sleeping aid, even though possible side effects of long-term
use have not been adequately studied, and the evidence is that
the hypnotic, or sleep-promoting, effects of melatonin among
healthy adults are weak and often not replicable (Arendt, 2005;
Sack et al., 1998; Zhdanova & Wurtman, 1997).

Regulating Activity Schedules
Properly timed physical exercise can help to shift the circadian clock (Mistlberger et al., 2000). For example, compared
to merely staying up later than normal, exercising when you
normally go to bed may push back your circadian clock, as
you would want to do when flying west (Baehr, 2001). To
reduce jet lag, you can also begin synchronizing your biological clock to the new time zone in advance. To do so, adjust
your sleep and eating schedules by one to two hours per day,
starting several days before you leave (Eastman et al., 2005).
Schedule management also applies to night shiftwork. For
workers on eight-hour rotating shifts, circadian disruptions
can be reduced by a forward-rotating shift schedule—moving
from day, to evening, to night shifts—rather than a schedule
that rotates backward from day, to night, to evening shifts
(Driscoll et al., 2007). Such forward-rotating shiftwork takes
advantage of our free-running circadian rhythms. When work
shifts change, it is easier to extend the waking day than to
compress it.

Stages of Sleep
Just as waking consciousness involves different
states of alertness and awareness, so does sleep.
Approximately every 90 minutes while asleep, we
cycle through different stages in which our brain
activity and other physiological responses change
in a generally predictable way (Dement, 2005;
Kleitman, 1963).
As Figure 6.11 shows, sleep research often is carried out in specially equipped laboratories in which
sleepers’ physiological responses are recorded. EEG
recordings of your brain’s electrical activity show a
pattern of beta waves when you are awake and alert.
Beta waves have a high frequency (of about 15 to 30
cycles per second, or cps) but a low “amplitude” or
height (Figure 6.12). As you close your eyes, feeling
relaxed and drowsy, your brain waves slow down
and alpha waves occur at about 8 to 12 cycles per
second.

11. How is exposure
to light used to
treat circadian
disruptions?

194

CHAPTER SIX

1
2

3

1 EEG (brain waves)
4
2 Right eye movements

3 Left eye movements

4 Muscle tension

FIGURE 6.11 In a modern sleep laboratory, people sleep while their physiological responses are monitored. Electrodes attached to the
scalp area record the person’s EEG brain-wave patterns. Electrodes attached beside the eyes record eye movements during sleep. Muscle tension
is recorded, and a neutral electrode is attached to the ear.
12. What brain-wave
patterns distinguish
the first four stages
of sleep?

Stage 1 through Stage 4
As sleep begins, your brain-wave pattern becomes
more irregular, and slower theta waves (3.5 to 7.5
cycles per second) increase. You are now in stage 1,
a form of light sleep from which you can easily be
awakened. You will probably spend just a few minutes (or less) in stage 1, during which time some
people experience images and sudden body jerks.
As sleep becomes deeper, sleep spindles—periodic
one- to two-second bursts of rapid brain-wave
activity (12 to 15 cycles per second)—begin to
appear. Sleep spindles indicate that you are now in
stage 2 (Figure 6.12). Your muscles are more relaxed,
your breathing and heart rate are slower, and you
are harder to awaken.
Sleep deepens as you move into stage 3, marked
by the regular appearance of very slow (0.5 to 2
cycles per second) and large delta waves. As time
passes, they occur more often, and when delta waves
dominate the EEG pattern, you have reached stage 4.
Together, stage 3 and stage 4 are often referred to as
slow-wave sleep. Your body is relaxed, activity in
various parts of your brain has decreased, and you
are hard to awaken. After 20 to 30 minutes of stage
4 sleep, your EEG pattern changes as you go “back
through” stages 3 and 2, spending a little time in
each. Overall, within 60 to 90 minutes of going to
sleep, you will have completed a cycle of stages 1-23-4-3-2. At this point, a remarkably different sleep
stage ensues.

REM Sleep
In 1953, sleep researchers Eugene Aserinsky and
Nathaniel Kleitman of the University of Chicago

Beta waves
Awake/alert
Alpha waves

1 sec

50
µV

Relaxed/drowsy
Theta waves
Stage 1
Sleep spindle
Stage 2
Delta waves
Stage 3
Delta waves
Stage 4

REM sleep

FIGURE 6.12 Changing patterns of brain-wave activity help
to define the various stages of sleep. Note that brain waves become
slower and larger as sleep deepens and that the general pattern of
REM sleep is similar to that of stage 1.
Adapted from Dement, 1978; Hauri, 1982.

struck scientific gold when they identified a sleep
stage unlike the rest. Every half minute or so, bursts
of muscular activity caused the sleepers’ eyeballs
to vigorously move back and forth beneath their
closed eyelids. Because of these rapid eye movements (REMs), this stage was called REM sleep.
When Aserinsky and Kleitman awakened sleepers

States of Consciousness

and participating in a series of real, if bizarre, events.
When subjects are awakened from non-REM sleep,
they often will report some type of mental activity
(Foulkes, 1985). The non-REM dream is shorter
than a REM dream (Stickgold et al., 1994). The nonREM dream is also less storylike, lacking the vivid
sensory and motor experiences of a REM dream.
The non-REM dream is often fixed and unmoving,
resembling a tableau more than a story with a plot.
Apart from non-REM dreams, mental activity that
occurs during non-REM sleep also may resemble
daytime thoughts, although in comparison to waking thoughts they are simple and jumbled. Indeed,
some of the mental activity that occurs during
non-REM sleep has even been referred to as sleep
thoughts because of the closer resemblance to daytime thinking than to REM dreams (Foulkes, 1985).
Each cycle through the sleep stages takes about
90 minutes. Figure 6.13 shows that, as the hours
pass, stage 4 and stage 3 drop out and REM periods
become longer.

from REM periods, they discovered that a dream
was almost always reported. Even people who swore
they “never had dreams” recalled them when awakened during REM. At last, science had a window
through which to examine dreaming more closely.
Wait for a REM period, awaken the sleeper, and
catch a dream.
During REM sleep, physiological arousal may
increase to daytime levels. Heart rate quickens,
breathing becomes more rapid and irregular, and
brain-wave activity resembles that of active wakefulness. Men have penile erections and women experience vaginal lubrication. Because most dreams do
not have sexual content, this REM-induced genital
arousal is not a response to sexual imagery.
The brain also sends signals, making it more difficult for voluntary muscles to contract. As a result,
muscles in the arms, legs, and torso lose tone and
become relaxed. These muscles may twitch, but in
effect you are “paralyzed” and unable to move. This
state is called REM sleep paralysis, and because of
it, REM sleep is sometimes called paradoxical sleep:
Your body is highly aroused, and yet it looks like you
are sleeping peacefully because you move so little.
REM sleep is often thought to be the only sleep
stage in which we dream or even experience mental activity, but that is not correct. We also experience mental activity during non-REM sleep. REM
dreams have their well-known storylike quality, with
vivid sensory and motor elements and the perception of reality. When you are in a REM dream, you
have the experience of sensing people, objects, and
places, of moving and behaving, and of witnessing

Relaxed/
drowsy

Getting a Night’s Sleep:
Brain and Environment
The brain steers our nightly passage into and
through sleep, but it does not contain a single “sleep
centre.” Different aspects of the sleep cycle, such as
falling asleep, REM sleep, and slow-wave sleep, are
controlled by different brain mechanisms. Moreover,
falling asleep is not just a matter of “turning off ” the
brain systems that regulate wakefulness. Separate
systems “turn on” and actively promote sleep.

REM 1

REM 2

REM 3

REM 4 REM 5

REM 1

REM 2

REM 3

REM 4 REM 5

Stage 1
Stage 2
Stage 3
Stage 4
Dreams
Eye
movements
1

2

3

4

5

6

7

Hours of sleep

FIGURE 6.13 This graph shows a record of a typical night’s sleep. People typically average four or five REM periods during the night. As
the night wears on, we spend less time in the deepest stages of sleep and more time in REM sleep.

195

13. Describe some major
characteristics of
REM sleep.

196

CHAPTER SIX

14. What brain areas
help to regulate
sleep onset and REM
sleep?

is in REM. But as we age, three important changes
occur:

Areas at the base of the forebrain (called the
basal forebrain) and within the brain stem are particularly important in regulating our falling asleep
(McGinty & Sterman, 1968; Szymusiak, 1995).
A different brain stem area—where the reticular
formation passes through the pons—plays a key
role in initiating REM sleep (Hobson et al., 1998).
This region contains “REM-sleep On” neurons that
periodically activate other brain systems, each of
which controls a different aspect of REM sleep,
such as eye movements, muscular paralysis, and
genital arousal.
Sleep is biologically regulated, but the environment plays a role as well. The change of seasons
affects sleep; in fall and winter, most people sleep
about 15 to 60 minutes longer per night (Campbell,
1993). Shiftwork, jet lag, stress at work and school,
and nighttime noise can decrease sleep quality
(Saremi et al., 2008).

• We sleep less. On average, 15- to 24-year-olds
average 8.5 hours of sleep per day, and elderly
adults average just under six hours.
• REM sleep decreases dramatically during infancy
and early childhood, but remains relatively stable
thereafter.
• Time spent in stages 3 and 4 declines. By late
adulthood, we get relatively little slow-wave
sleep.
A parent, caregiver, relative, or friend has told you
that you need eight hours of sleep a night. We have all
heard this, but is it true? Many researchers and health
care professionals do suggest that we need about
eight hours of uninterrupted sleep a night. Research
has found, however, that if we follow our own natural
rhythms, with no clocks and scheduled routines, we
sleep between 10 and 12 hours a night (Coren, 1996).
How much sleep a person needs is influenced by
genetic factors, work schedules, stress, age, lifestyle,
and general health, among other factors (de Castro,
2002; Vincent et al., 2009; Williams, 2001). Although
most of us may need eight to ten hours of sleep a
night, some famous individuals have functioned well
on surprisingly little sleep: British prime ministers

How Much Do We Sleep?

24
Waking
16
14
Total hours of daily sleep

15. How do sleep
patterns change as
we age?

The question seems simple enough, as does the
answer for many of us: not enough! In reality, the
issue is complex. Figure 6.14 reveals that there are
substantial differences in how much people sleep
at various ages. Newborn infants average 16 hours
of sleep a day, and almost half of their sleep time

12

50%
40%

10

25–30%

REM sleep

25%
20%

19%

8
6

Percentage of total
sleep spent in REM

19%
20%

22%

Non-REM
sleep

19%

20–23%

4
2
0
1–15
days

3–5
mos

6–23
mos

Infancy

2–3
yrs

3–5
yrs

5–9
yrs

Childhood

10–13 14–18 19–30 31–45
yrs
yrs
yrs
yrs
Adolescence

50
yrs

90
yrs

Adulthood Old age

FIGURE 6.14 The percentage of sleep time in REM and non-REM sleep changes with age. Average daily sleep time decreases over the
lifespan, and most of the decrease in non-REM sleep is due to decreasing delta sleep (stages 3 and 4). REM sleep time decreases throughout
childhood and then is relatively stable through adulthood.
Adapted from H.P. Roffwarg, J.N. Muzio & W.C. Dement, “Ontongenic Development of Human Dream-Sleep Cycle,” Science, 152, 604, Fig 1.
Copyright © 1966, AAAS. Reprinted with permission from AAAS.

States of Consciousness

Winston Churchill and Margaret Thatcher, U.S.
president John F. Kennedy, and Napoleon Bonaparte
all reportedly slept between 3 and 5.5 hours a night
(Sharkey, 1993), and Leonardo DaVinci is reported
to have slept as little as two hours a day. Whether we
need eight or ten hours of sleep a night, how much
time do we actually spend sleeping? Canadians aged
15 and over sleep an average of eight hours and 18
minutes a night (Statistics Canada, 2010). This is an
increase of almost 15 minutes of sleep per night from
the late 1990s. These figures, however, conceal large
individual differences. Although we average more
than eight hours of sleep a night, 15 percent of Canadians 15 years old and older sleep less than 6.5 hours
a night (Williams, 2001).

Sleep Deprivation
Sleep deprivation is a way of life for many university students, and they are not alone. Almost half
of us sacrifice some sleep to accomplish more work
(National Sleep Foundation, 2000; Williams, 2001).
Millions more lose sleep because of disorders.
Psychologists study sleep deprivation for its
practical significance and to gain insight into why
we need to sleep. June Pilcher and Allen Huffcutt
(1996) of Bradley University meta-analyzed 19 sleep
deprivation studies in which participants underwent
either short-term total sleep deprivation (up to 45
hours without sleep), long-term total sleep deprivation (more than 45 hours without sleep), or partial
deprivation (being allowed to sleep no more than
five hours per night for one or more consecutive
nights). Participants’ self-reported mood (e.g., irritability, disorientation), responses on mental tasks
(e.g., ability to concentrate, logical reasoning, word
memory), and physical tasks (e.g., manual dexterity,
treadmill-walking) were measured.
What would you predict? Would all types of
deprivation affect behaviour, and which behaviours would be affected the most? Combining
across the different types of deprivation and behaviour, the results were remarkable: The “average”
sleep-deprived person functioned only as well as
someone in the bottom 9 percent of nondeprived
participants. All three types of sleep deprivation had
a negative impact on functioning. Mood suffered
most, followed by cognitive and then physical performance, although all three behaviours showed significant impairment from sleep loss.
What about students who pull all-nighters or
drastically cut back their sleep, and claim they still
perform as well as ever? Pilcher and Walters (1997)
found that university students deprived of one
night’s sleep performed more poorly on a criticalthinking task than students allowed to sleep. Yet

sleep-deprived students incorrectly perceived that
they performed better and felt that they concentrated and tried harder. The authors concluded that
the students underestimated the negative effects of
sleep loss on performance.
Most total sleep deprivation studies with humans
last less than five days, but 17-year-old Randy
Gardner set a world record by staying awake for
11 days as his project for a 1964 high school science fair in San Diego. Grateful sleep researchers received permission to study him (Gulevich,
Dement, & Johnson, 1966). At times during the
first few days, Randy became irritable, forgetful,
nauseous, and intensely tired. By day five, he had
periods of disorientation and distorted thinking. In
the last four days, he developed finger tremors and
slurred speech. Still, in his final day without sleep,
he beat sleep researcher William Dement 100 consecutive times at a pinball-type game.
When