Motivation and Emotion PDF

Summary

This document outlines various perspectives on motivation and emotion. It delves into topics like instinct theory, homeostasis, and the adaptive value of emotions. Different theories are examined and illustrated with applications and research.

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CHAPTER

11
CHAPTER
OUTLINE

Motivation and Emotion
PERSPECTIVES ON MOTIVATION

ACHIEVEMENT MOTIVATION

Instinct Theory and Evolutionary Psychology
Homeostasis and Drive Theory
Incentive and Expectancy Theories
Psychodynamic and Humanistic Theories

The Thrill of Victory, the Agony of Defeat
Achievment Goal Theory
Achievement Needs and Situational Factors
Family and Cultural Influences

HUNGER AND WEIGHT REGULATION

MOTIVATIONAL CONFLICT

The Physiology of Hunger

THE NATURE AND FUNCTIONS OF EMOTION

Frontiers: Excessive Exercise: Activity Anorexia
Psychological Aspects of Hunger
Environmental and Cultural Factors
Obesity

The Adaptive Value of Emotion
The Nature of Emotion

Applications: The Battle to Control Eating and Weight
SEXUAL MOTIVATION
Sexual Behaviour: Patterns and Changes
The Physiology of Sex
The Psychology of Sex
Cultural and Environmental Influences
Sexual Orientation

Focus on Neuroscience: The Neuroscience
of Affective Style
THEORIES OF EMOTION
The James-Lange Somatic Theory
The Cannon-Bard Theory
Cognitive-Affective Theories

Research Foundations: Cognition-Arousal Relations

One can never consent to creep when one feels an impulse to soar.
—Helen Keller

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

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Dr. Larry Farwell, a
former member of
the Harvard Medical
School, has developed a new technique
for determining guilt or innocence.
“Brain fingerprinting” involves the
monitoring of brainwaves to determine whether or not a suspect has
details of a crime or other information stored in the brain. Suspects are
shown words or images that would
be accessible only to someone who
was actually at the scene of the
crime. By monitoring brainwaves, the investigator can determine whether or not the suspect recognizes
these images.

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Dr. Farwell’s testimony was instrumental in exonerating Terry Harrington, a convicted murderer who
was serving a life sentence in Iowa. Brain fingerprinting revealed that the information in Harrington’s brain
did not match the details of the crime but, in fact, were consistent with his alibi. Unlike polygraph examinations, brain fingerprinting has been ruled admissible in U.S. courts.

T

he term motivation often triggers images
of people who persevere to attain their
dreams and stretch the boundaries of human
achievement. But to psychologists, motivational
issues are broader. What motivates eating,
sexual behaviour, thrill seeking, and affiliation?
Motivation is a process that influences the
direction, persistence, and vigour of goal-directed
behaviour. The word motivation derives from the
Latin term meaning “to move,” and psychologists
who study motivation identify factors that move us
toward our goals, whether they are obtaining food,
a mate, success, or even peace and quiet (see the
Frontiers feature later in this chapter).

PERSPECTIVES ON
MOTIVATION
Psychology’s diverse theoretical perspectives view
motivation through different lenses. Let’s examine
some of their basic motivational concepts.

heredity accounts for differences among people
in many aspects of motivated behaviour, such as
desire for security (Woody, & Szechtman, 2011), or
even, as studied by James Olson of the University of
Western Ontario, attitudes toward reading books,
playing organized sports, and riding roller coasters
(Olson, Vernon, Harris, & Jang, 2001).
Modern evolutionary psychologists propose
that many “psychological” motives have evolutionary underpinnings that are expressed through the
actions of genes (Buss, 2007; Palmer & Palmer,
2002). From this perspective, the adaptive significance of behaviour is a key to understanding
motivation. For example, why are we such social
creatures? Presumably, affiliation produced survival
advantages—such as shared resources and protection against predators—that afforded our ancestors a greater opportunity to pass on their genes to
successive generations. Over the ages the genes of
“affiliative people” made up an increasing part of
the human gene pool, and we became biologically
predisposed to be social rather than reclusive.

Instinct Theory and Evolutionary
Psychology

Homeostasis and Drive Theory

Darwin’s theory of evolution inspired early psychological views that instincts motivate much of our
behaviour. An instinct is an inherited predisposition to behave in a specific and predictable way
when exposed to a particular stimulus. Instincts
have a genetic basis, are found universally among all
members of the species, do not depend on learning,
and have survival value for the organism. William
James (1890) proposed about three dozen human
instincts, and by the 1920s, researchers had proposed thousands (Atkinson, 1964).
Human instinct theories faded because there was
little evidence to support them and they often relied
on circular reasoning. Why are people greedy?
Because greed is an instinct. How do we know that
greed is an instinct? Because people are greedy. This
explains nothing. Today, scientists examine hereditary contributions to human motivation more productively. By conducting twin and adoption studies,
behaviour geneticists seek to establish how strongly

Your body’s biological systems are delicately balanced to ensure survival. For example, when you are
hot, your body automatically tries to cool itself by
perspiring. When you are cold, your body generates
warmth by shivering. In 1932, Walter Cannon proposed the concept of homeostasis, a state of internal physiological equilibrium that the body strives
to maintain.
Maintaining homeostasis requires a sensory
mechanism for detecting changes in the internal
environment, a response system that can restore
equilibrium, and a control centre that receives information from the sensors and activates the response
system (Figure 11.1). The control centre functions
somewhat like the thermostat in a furnace or an airconditioning unit. Once the thermostat is set at a
fixed temperature, or set point, the sensors detect
significant temperature changes in either direction.
The control unit responds by turning on the furnace
or the air conditioner until the sensor indicates that

pas77416_ch11_380-428.indd 381

1. According to
evolutionary
psychologists, how
does the concept of
adaptive significance
help us understand
human motivation?

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382

CHAPTER ELEVEN

Control
centre

Response
system

Sensors

Internal
state

FIGURE 11.1 Your body’s internal environment is regulated
by homeostatic mechanisms. Sensors detect bodily changes and
send this information to a control centre, which in turn regulates a
response system that restores bodily equilibrium.

2. How are homeostatic
and drive concepts of
motivation related?

3. According to
expectancy × value
theory, why might
people respond
differently to the
same incentive?

the set point temperature has been restored, and
then turns it off. Homeostatic regulation also can
involve learned behaviours. When we’re hot, we not
only perspire, but also may seek a shady place or
deliciously cool drink.
According to Clark Hull’s (1943, 1951) influential
drive theory of motivation, physiological disruptions to homeostasis produce drives, states of internal tension that motivate an organism to behave in
ways that reduce this tension. Drives such as hunger and thirst arise from tissue deficits (e.g., lack of
food and water) and provide a source of energy that
pushes an organism into action. Hull, a prominent
learning theorist, proposed that reducing drives is
the ultimate goal of motivated behaviour.
Homeostatic models currently are applied to
many aspects of motivation, such as the regulation
of hunger, thirst, body temperature, weight, and
sleep (Woods & Seeley, 2002). Drive theory is, however, less influential than in the past. For one thing,
people often behave in ways that seem to increase
rather than reduce states of arousal, as when people
skip meals to diet or flock to tension-generating
horror movies.

Incentive and Expectancy Theories
Whereas drives are viewed as internal factors that
“push” organisms into action, incentives represent environmental stimuli that “pull” an organism
toward a goal. To a student, a good grade can be an
incentive for studying.
Incentive theories focus attention on external stimuli that motivate behaviour, though historically the concepts of incentives and drives were

pas77416_ch11_380-428.indd 382

often linked. Clark Hull (1943, 1951) argued that
all reinforcement involves some kind of biological
drive reduction (e.g., food is an incentive because
it reduces the drive of hunger), but this view is no
longer held. Modern incentive theory emphasizes
the “pull” of external stimuli and how stimuli with
high incentive value can motivate behaviour, even
in the absence of biological need. We have all had
the experience of finishing a meal, and hence having
no biological need for more food, but quite happily
eating dessert when someone places our favourite
cake or pie on the table. In this situation, behaviour is motivated not by biological need but by the
incentive value of the external stimulus (the dessert).
Incentive theories of motivation have been powerfully applied to the study of drug abuse (Stewart,
2000; Stewart & Wise, 1992). An incentive theory
of drug use argues that seeking and administering a
drug is motivated by the positive incentive value of
the drug’s effect. Heroin users, for example, will find
and inject heroin because the drug makes them feel
good, not because of a biological heroin drive or a
desire to escape withdrawal.
Why is it, however, that people often respond
differently to the same incentive? In part to address
such questions, expectancy theories of motivation
include the value of incentives, but take a cognitive
perspective. Incentive theories had more in common with classical conditioning (e.g., Stewart, 2000)
than with cognition, but expectancy theory has
broken from this tradition and given a larger role
to cognition (Erez & Isen, 2002). Consider James,
Lenora, and Harrison, students in a calculus class
who have similar math aptitude. Yet James studies
hard in hopes of getting an A, whereas Lenora and
Harrison put in just enough effort to pass with a C.
How can we explain the differences in the behaviour
of these three students?
According to the cognitive perspective, the answer
lies in their thoughts about this situation. One cognitive approach, called expectancy × value theory
(or simply expectancy theory), proposes that goaldirected behaviour is jointly determined by two factors: the strength of the person’s expectation that
particular behaviours will lead to a goal, and the value
the individual places on that goal—often called incentive value (Brehm & Self, 1989). These two factors are
multiplied, producing the following equation: Motivation 5 expectancy × incentive value. James works
hard because he believes that the more you study, the
greater the probability of getting an A, and he values
an A highly. Lenora also believes that studying hard
will lead to an A, but getting an A holds little value
for her in this course. In contrast, Harrison values an
A, but believes that because the tests are tricky, studying hard is unlikely to produce a high grade.

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Motivation and Emotion

Many cognitive theorists distinguish between
extrinsic motivation, performing an activity to
obtain an external reward or avoid punishment,
and intrinsic motivation, performing an activity
for its own sake—because you find it enjoyable or
stimulating. Students who read their textbooks only
because they want to get good grades are showing
extrinsic motivation. Students who read their textbooks because they find them interesting and want
to learn more are showing intrinsic motivation.
Can external incentives ever decrease motivation? According to the overjustification hypothesis,
giving people extrinsic rewards to perform activities
that they intrinsically enjoy may “overjustify” that
behaviour and reduce intrinsic motivation (Bright
& Penrod, 2009). In essence, if we begin to perceive
that we are performing for the extrinsic rewards
rather than for enjoyment, the rewards will turn
“play” into “work,” and it might be difficult to return
to “play” if those rewards are no longer available. It
is surprisingly common for people to report that an
activity is no longer as enjoyable once they begin to
be paid for it. A student who, for example, makes
jewellery as a hobby (i.e., she simply enjoys the
activity) and then begins to sell the jewellery will
commonly report a marked decrease in the intrinsic
pleasure of the activity.

distinguished between deficiency needs, which are
concerned with physical and social survival, and
growth needs, which are uniquely human and motivate us to develop our potential. He proposed the
concept of a need hierarchy, a progression of needs
containing deficiency needs at the bottom and growth
needs at the top (Figure 11.2). Once our basic physiological needs are satisfied, we focus on our needs for
safety and security. After these needs are met, we turn
our attention to needs at the next highest level, and so
on. Self-actualization represents the need to fulfill
our potential, and it is the ultimate human motive. To
echo an army recruiting slogan, self-actualization is
striving to “be all that you can be.”
Critics question the validity of Maslow’s need
hierarchy and believe that the concept of “selfactualization” is vague (Heylighen, 1992). How does
the hierarchy explain why prisoners of war endure
torture rather than betray their comrades or why
millions of women live in constant hunger to be
thin? Still, the model draws valuable attention to the
human desire for growth, incorporates a wide range
of psychological and biological motives, and has
influenced thinking in such diverse fields as philosophy, education, and business (Muchinsky, 2000).

4. Explain Maslow’s
concept of a need
hierarchy. Do you
agree with this
model?

Thinking critically

Psychodynamic and Humanistic Theories

IS MASLOW’S NEED HIERARCHY VALID?

The psychodynamic and humanistic perspectives
view motivation within a broader context of personality development and functioning, but take radically
different approaches. Freud’s (1923) psychoanalytic
theory highlighted the motivational underworld.
To Freud, much of our behaviour results from a
never-ending battle between unconscious impulses
struggling for release and psychological defences
used to keep them under control. Energy from these
unconscious motives—especially from instinctive
sexual and aggressive drives—is often disguised and
expressed through socially acceptable behaviours.
Thus, hidden aggressive impulses may fuel one’s
career as a trial lawyer, businessperson, or athlete.
Although research offers little support for Freud’s
“dual-instinct” model, his work stimulated other
psychodynamic theories that highlighted different needs, such as needs for self-esteem and relatedness to other people (Adler, 1927; Kohut, 1977).
Today’s diverse psychodynamic theories continue to
emphasize that, along with conscious mental processes, unconscious motives and tensions guide how
we act and feel (Westen, 1998).
Humanist Abraham Maslow believed that psychology’s other perspectives ignored a key motive:
our striving for personal growth. Maslow (1954)

Does the concept of a need hierarchy, shown in Figure 11.2,
make sense to you? How do you feel about the ordering of
needs in Maslow’s hierarchy?

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383

Think about it, and then see the Answers section at the end
of the book.

A more recent humanistic theory of motivation has been advanced by Edward Deci and
Richard Ryan (1985, 2009). Self-determination
theory focuses on three fundamental psychological needs: competence, autonomy, and relatedness.
People are most fulfilled in their lives when they
are able to satisfy these fundamental needs. On the
other hand, when these needs are not met, there can
be consequences for both psychological and physical well-being (Deci & Ryan, 2009).
Competence motivation reflects a human need to
master new challenges and perfect skills. This need
motivates much exploratory and growth-inducing
human behaviour. The need for autonomy (or selfdetermination) is satisfied when people experience
their actions as a result of free choice without outside interference. Relatedness refers to our desire
to form meaningful bonds with others. At first

5. What are the three
needs identified in
self-determination
theory?

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384

CHAPTER ELEVEN

es
gr
Re
sio
ni
f lo
r
we
ne

ni

ot
t
me

s
re
ati
sfi
ed

Safety needs
security • psychological safety

sa
ed

Belongingness and love needs
affiliation • acceptance • affection

ne

Deficiency
needs

r
we

Esteem needs
approval • recognition

f lo

Cognitive needs
knowledge • understanding

n
re

sa
ed

sio

Aesthetic needs
beauty • symmetry

res
og
Pr

Selfactualization

Growth
needs

Physiological needs
food • drink

FIGURE 11.2 Maslow proposed that needs are arranged in a hierarchy. After meeting our more basic needs, we experience need
progression and focus on needs at the next level. If a need at a lower level is no longer satisfied, we experience need regression and focus once
again on meeting that lower-level need. Critics wonder whether people might focus on belonging, love, esteem, and higher-level needs even
when their physiological and safety needs are not met. What do you think?
glance, relatedness may seem opposed to autonomy, but the two actually complement each other.
When true relatedness is achieved, people often feel
freer to be themselves. Adolescents who feel that
their autonomy is acknowledged and supported
by their parents feel a strong sense of relatedness
to their parents (Ryan & Lynch, 1989). Similarly,
workers who are given freedom to develop their
own plans (increased autonomy) experience an
increased emotional bond with their employer and
company (Tremblay et al., 2009).

The importance of self-determination theory’s
three basic needs has been strongly supported
by research. They appear to have independent
and additive effects on positive outcomes such as
psychological well-being, happiness, worker performance and satisfaction, positive social relationships, and a sense of meaningfulness in life (Deci
& Ryan, 2009; Sheldon et al., 2003). The most
positive psychological outcome of all results from
a balance among the three needs (Milyavskaya
et al., 2009).

In Review
• Motivation is a process that influences the
direction, vigour, and persistence of behaviour.
Evolutionary psychologists propose that in our
ancestral past, motivational tendencies that had
adaptive significance were more likely to be
passed from one generation to the next, eventually evolving into genetically based predispositions to act in certain ways.
• Homeostatic models view motivation as an
attempt to maintain equilibrium in bodily systems. Drive theories propose that tissue deficits
create drives, such as hunger, that motivate or
“push” an organism from within to reduce the
deficit and restore homeostasis.

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• Incentive theories emphasize the role of environmental factors that “pull” people toward a
goal. The cognitive expectancy × value theory
explains why the same incentive may motivate
some people but not others.
• Psychodynamic theories emphasize that unconscious motives and mental processes guide
much of our behaviour. Humanist Abraham
Maslow proposed that needs exist in a hierarchy,
from basic biological needs to the ultimate need
for self-actualization.
• Self-determination theory focuses on three psychological needs: competence, autonomy, and
relatedness.

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Motivation and Emotion

In sum, each of these theoretical approaches
raises provocative questions about human motivation and has strong proponents and critics, just as
some perspectives no doubt resonate more than
others with your own views about motivation.
Taken together, they underscore the complexity of
behaviour and the value of studying it from multiple
levels of analysis. We begin that analysis with one of
our most basic motives: hunger.

HUNGER AND WEIGHT
REGULATION
If you could give up all food forever and satisfy your
hunger and nutritional needs with a daily pill, would
you? Eating is a necessity, but for many people it
also is one of life’s delicious pleasures. Thus, while
biology provides a “push” to eat, the anticipated and
actual good taste of food offers a powerful “pull”
(Bolles, 1980). Indeed, numerous biological, psychological, and environmental factors regulate our
food intake.

The Physiology of Hunger
Eating and digestion supply the body with the fuel
it needs to function and survive. Metabolism is
the body’s rate of energy (or caloric) utilization,
and about two-thirds of the energy we normally
use goes to support basal metabolism, the resting,
continuous metabolic work of body cells. Several
mechanisms attempt to keep the body in energy
homeostasis by regulating food intake (Woods &
Seeley, 2002). There are “short-term” signals that
start meals by producing hunger and stop food
intake by producing satiety (the state in which we
no longer feel hungry as a result of eating). Your
body also monitors “long-term” signals based on
how much body fat you have. These signals adjust
appetite and metabolism to compensate for times
when you overeat or eat too little in the short term.
Before we describe some of these signals, consider three points. First, many of us believe that hunger occurs when we begin to “run low on energy,”
and that we feel “full” when immediate energy supplies are restored (Assanand et al., 1998). Your body
does monitor its immediate energy supplies, but this
information interacts with other signals to regulate
food intake. Thus, hunger is not necessarily linked
to immediate energy needs (Pinel, 1997; Woods
et al., 1998). Second, homeostatic mechanisms are
designed to prevent you from “running low” on
energy in the first place. In evolutionary terms, an
organism that does not eat until its energy supply
is low (in any absolute sense) would be at a serious
survival disadvantage.

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385

Finally, researchers believed that there is a set
point—an internal physiological standard—around
which body weight (or more accurately, our fat
mass) is regulated (Powley & Kessey, 1970). This
view holds that if we overeat or eat too little,
homeostatic mechanisms will return us close to our
original weight, our set point. Although this idea is
well ingrained in popular culture, some researchers, such as John Pinel at the University of British
Columbia, believe it is flawed (Pinel, 1997; Pinel,
Assanand, & Lehman, 2000). They propose that, as
we gain or lose weight, homeostatic mechanisms
kick in and make it harder to keep gaining or losing weight, but do not necessarily return us to our
original weight. Over time, we may “settle in” at a
new weight.

Signals That Start and Terminate a Meal
Is hunger produced by those familiar muscular
contractions (“hunger pangs”) of an empty stomach? In an early experiment, A.L. Washburn showcased a unique scientific talent: He swallowed a
balloon. When it reached his stomach, the balloon was inflated and hooked up to an amplifying device to record his stomach contractions.
Washburn then pressed a key every time he felt
hungry (Figure 11.3). The findings revealed that
Washburn’s stomach contractions did indeed correspond to subjective feelings of hunger (Cannon &
Washburn, 1912). But did they cause the “experience” of hunger?
Surprisingly, other research indicates that “hunger pangs” do not depend on an empty stomach,
or any stomach at all! Animals display hunger
and satiety even if all nerves from their stomach
to their brain are cut, and people who have had
their stomach surgically removed for medical reasons continue to feel hungry and “full” (Brown &
Wallace, 1980). Thus, other signals must help to
trigger hunger.
When you eat, digestive enzymes break food
down into various nutrients. One key nutrient
is glucose, a simple sugar that is the body’s (and
especially the brain’s) major source of immediately
usable fuel. After a meal, some glucose is transported into cells to provide energy, but a large portion is transferred to your liver and fat cells, where it
is converted into other nutrients and stored for later
use. Sensors in the hypothalamus and liver monitor
blood glucose concentrations. When blood glucose
levels decrease, the liver responds by converting
stored nutrients back into glucose. This action produces a drop-rise glucose pattern. The meaning
of this drop-rise pattern is not certain, but it may
contain information that helps the brain regulate
hunger (Campfield, 1997).

6. Describe some
physiological signals
that initiate hunger.

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CHAPTER ELEVEN

Stomach
contractions
Time
Pangs
Respiration
Balloon
Signal key

FIGURE 11.3 A.L. Washburn swallowed a balloon and inflated it in his stomach. A machine recorded stomach contractions by amplifying
changes in the pressure on the balloon, and Washburn pressed a telegraph key every time he felt a hunger pang. Hunger pangs occurred when
the stomach contracted.
Based on Cannon and Washburn, 1912.

7. What physiological
signals cause us to
stop eating?

8. Explain how leptin
regulates appetite.
How did scientists
learn about leptin’s
role?

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As we eat, several bodily signals combine and
ultimately cause us to end our meal. Stomach and
intestinal distention are “satiety signals” (Stricker &
Verbalis, 1987). The walls of these organs stretch
as food fills them up, sending nerve signals to the
brain. This does not mean that the stomach literally has to be “full” for us to feel satiated. Nutritionally rich food seems to produce satiety more quickly
than an equal volume of less nutritious food,
suggesting that some satiety signals respond to
food content.
Patients who have had their stomachs removed
continue to experience satiety not only because of
intestinal distention, but also because of chemical
signals (Collier & Johnson, 2004). The intestines
respond to food by releasing several hormones—
called peptides—that help to terminate a meal. For
example, CCK (cholecystokinin) is released into
your bloodstream by the small intestine as food
arrives from the stomach. It travels to the brain and
stimulates receptors in several regions that decrease
eating. Hungry animals injected with CCK will
stop feeding or reduce the size of their meals, and
humans who receive small doses of peptides report
feeling full after eating less food (Gibbs et al., 1973;
Konkle et al., 2000). See Table 11.1.
Whereas CCK decreases feelings of hunger,
another peptide hormone increases feelings of hunger and eating. Ghrelin is released into the bloodstream by the stomach and small intestine and is
now thought to be one of the most important signals
for hunger among humans (Schüssler et al., 2012).

People given an injection of ghrelin report feeling
hungry and, given the opportunity to eat, will consume more food than participants given injections
of saline (Schmid et al., 2005). Ghrelin has also been
reported to increase thoughts about food and mental images of food, especially the mental image of a
favourite meal (Schmid et al., 2005). Your ghrelin
levels are highest just before meal-time, they decline
rapidly after eating, and then they begin to rise
again as the next meal approaches. Ghrelin release
can also be triggered by food-related cues, such as
pictures of food (Schüssler et al., 2012).

Signals That Regulate General Appetite
and Weight
Fat cells are not passive storage sites for fat. Rather,
they actively regulate food intake and weight by
secreting leptin, a hormone that decreases appetite
(Halaas et al., 1995). As we gain fat, more leptin is
secreted into the blood and reaches the brain, where
receptor sites on certain neurons detect it. These
leptin signals influence neural pathways to decrease
appetite and increase energy expenditure (Woods et
al., 1998, 2000). See Table 11.1.
Leptin is a “background” signal. It does not make
us feel “full” like CCK and other satiety signals
that respond directly to food intake during a meal.
Instead, leptin may regulate appetite by increasing
the potency of these other signals (Woods & Seeley,
2002). Thus, as we gain fat and secrete more leptin,
we tend to eat less because these mealtime satiety
factors make us feel full sooner. As we lose fat and

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Motivation and Emotion

TABLE 11.1

Some of the Signals That Control Eating by Increasing or Decreasing Hunger

Signal

Source

Effect

Glucose

blood glucose levels monitored by
hypothalamus, liver
released into bloodstream by intestines
secreted into bloodstream by fat cells
secreted by neurons within the PVN of the
hypothalamus
secreted into bloodstream by stomach, small
intestine

drop-rise pattern increases hunger

CCK
Leptin
Neuropeptide Y
Ghrelin

387

secrete less leptin, it takes more food and a greater
accumulation of satiety signals to make us feel full.
In essence, high leptin levels may tell the brain
“There is plenty of fat tissue, so it’s time to eat less.”
Evidence for leptin’s important role grew out
of research with genetically obese mice (Coleman,
1978; Zhang et al., 1994; Figure 11.4). A gene called
the ob gene (ob = obesity) normally directs fat cells
to produce leptin, but mice with an ob gene mutation lack leptin. As they gain weight, their brains
do not receive this “curb your appetite” signal, and
the mice overeat and become obese. Daily leptin
injections reduce their appetites and increase their
energy expenditure, and the mice become thinner.
Another strain of obese mice produces ample leptin,
but because of a mutation in a different gene (the db
gene), their brain receptors are insensitive to leptin
(Chen et al., 1996; Halaas et al., 1995). The “curb
your appetite” signal is there, but they can’t detect it,
and become obese. Injecting these mice with leptin
does not reduce their food intake and weight.
Are these specific ob and db gene mutations a
major source of human obesity? Probably not, for
both genetic conditions seem to be rare in humans
(Clement, 1999). However, when they do occur,
these conditions are associated with extreme obesity,

decreases hunger
decreases hunger
increases hunger
increases hunger

suggesting the importance of normal leptin functioning in human weight regulation. Might leptin
injections be the “magic bullet” that would help
most obese people lose weight? Unfortunately, there
is reason for doubt, because obese people already
have ample leptin in their blood because of their fat
mass (Jequier & Tappy, 1999; Ravussin & Gautier,
1999). For currently unknown reasons, their brains
appear to be insensitive to that information.

Brain Mechanisms
Many parts of the brain—ranging from the primitive brain stem to the lofty cerebral cortex—play a
role in regulating hunger and eating (Logue, 1991).
But is there a “master control centre”? Early experiments pointed to two regions in the hypothalamus
(Stellar, 1954). Areas near the side, called the lateral
hypothalamus (LH), seemed to be a “hunger on”
centre (Figure 11.5). Electrically stimulating a rat’s

Paraventricular
nucleus
Pituitary
Ventromedial
hypothalamus

FIGURE 11.4 The mouse on the left has an ob gene mutation.
Its fat cells fail to produce leptin, and it becomes obese. Leptin injections help such mice return to normal weight, as seen in the mouse
on the right.

pas77416_ch11_380-428.indd 387

Lateral hypothalamus

FIGURE 11.5 Various structures within the hypothalamus play
a role in regulating hunger, thirst, sexual arousal, and body temperature. The lateral hypothalamus (LH), ventromedial hypothalamus
(VMH), and paraventricular nucleus (PVN) are involved in hunger
regulation.

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CHAPTER ELEVEN

Frontiers
EXCESSIVE EXERCISE: ACTIVITY ANOREXIA
At any one time, in any situation, we have a variety of behaviours we can choose from. We choose one behaviour from a
range of possibilities, and as the situation changes we may
switch from our previous behaviour to doing something new.
Motivated behaviours such as exercise, playing video games,
gambling, or eating occur as part of a range of activities in one’s
life, and under normal circumstances do not pose any undue
threat to the individual. In some situations, however, these
behaviours may become problematic. If an individual devotes
excessive amounts of time and effort to their chosen activity,
their behaviour can create a range of social, psychological, and
health problems. One such activity that has been studied experimentally in nonhumans is wheel running by rats. Understanding this behaviour and the mechanisms that control its excessive
form may provide insight into how once normal, and even
healthy, behaviours can come to dominate an individual’s life.
If rats have access to a running wheel, they will spend
some of their time running. This behaviour tends to increase
in frequency with experience, and, perhaps counterintuitively,
it may become excessive if the animal is hungry (Lett, Grant,
Koh, & Smith, 2001). As Terry Belke, of Mount Alison University, and David Pierce, of the University of Alberta, have
shown, as the body weight of a rat falls, both food and exercise (wheel running) become more reinforcing (Belke & Pierce,
2009). If a rat is allowed limited access to food and unlimited
access to a running wheel except during the meal period, a
condition called activity anorexia develops (Epling & Pierce,
1992). Over days, animals with access to a running wheel
engage in increasing amounts of running; they eat less, lose
weight, and, if left in this situation, will starve. The rats with
the running wheels do not simply eat too little to compensate for the time spent on the added exercise, they actually
eat less than do animals that do not have access to a running wheel. As these animals eat less and lose weight, the
amount of wheel running increases, exacerbating the problem. Eating is increasingly suppressed while physical exercise
becomes excessive. Activity anorexia highlights some intriguing issues in the study of motivation—how the motivation
for a behaviour can increase to the point of endangering an
individual’s health and well-being, how two behaviours with
different motivations (running and eating) can come to compete with each other, and how a single motivated behaviour,
wheel running, can have both aversive and rewarding effects.
Many researchers consider activity anorexia to be an animal
model of the human eating disorder anorexia nervosa (Epling

& Pierce, 1992; Sparkes, Grant, & Lett, 2003). We will discuss
eating disorders, including anorexia nervosa, in Chapter 16.
Although the mechanisms of activity anorexia are not completely understood, the research program of Dr. Virginia Grant
and colleagues at Memorial University of Newfoundland has
contributed much to our understanding of activity anorexia.
Research by Grant and her colleagues, and others, indicates
that wheel running by rats can have both positive and aversive effects; it can act as a reinforcer, but it can also be used
as an aversive consequence to generate a conditioned taste
aversion (CTA; Figure 11.6a; Lett, Grant, Koh, & Smith, 2001;
Lett, Grant, Byrne, & Koh, 2000; Sparkes et al., 2003). As we
saw in our earlier discussion of CTAs (see Chapter 7), a taste
paired with aversive consequences, such as illness, will lead
to a learned (conditioned) aversion to that taste. Reports of
conditioned taste aversions with wheel running, however, are
not always consistent.
Sparkes, Grant, and Lett (2003) investigated one possible
explanation for the inconsistent findings with wheel running
and the development of a CTA. In this study, rats were given
once-daily access to food and were allowed to eat as much as
they wanted for 90 minutes. For some animals the food was
familiar; it was the same food that they ate prior to the start
of the experiment. For some it was a novel food; the first time
these animals had access to this food was during the five days
that they engaged in wheel running. Sparkes et al. found that
animals developed a CTA to the novel food that had been
paired with wheel running, but they did not develop a CTA
to the familiar food. CTAs typically develop rapidly to novel
foods but accrue to familiar foods only slowly. Together with
the finding that CTAs developed using wheel running share
features with more typically induced CTAs, these findings
address an important issue with respect to activity anorexia.
Does the wheel running generate an aversion to food and is
it the aversion, rather than wheel running itself, that leads to
the suppression of eating? A conditioned aversion to foods
cannot be responsible for the decrease in food intake with
activity anorexia since a CTA did not develop to familiar foods
paired with wheel running. Animals that had the familiar food
did not develop a CTA, but these animals did show activity
anorexia. Thus, the wheel running itself suppresses feeding
without necessarily involving a CTA. Since it can be used to
develop a conditioned aversion, wheel running must be considered to have some aversive or negative consequences.
If wheel running does have aversive or negative consequences, as indicated by the CTA findings, why do animals
engage in this behaviour? In a study by Sparkes et al. (2003),
continued

LH causes it to start eating, and lesioning (damaging
or destroying) the LH causes it to refuse to eat, even
to the point of starvation (Anand & Brobeck, 1951).

pas77416_ch11_380-428.indd 388

In contrast, structures in the lower-middle
area, called the ventromedial hypothalamus
(VMH), seemed to be a “hunger off ” centre.

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9
Mean preference score

Mean amount consumed (m)

10
8
7
6
5
4
3
2

60
50
40
30
20
10

1
0

0
Paired

Unpaired
(a)

389

Control
(b)

Group

Saline
Group

Naloxone

FIGURE 11.6 Panel (a) shows the results from a conditioned taste aversion (CTA) experiment. If a taste has been paired with wheel running (Paired), animals will
consume less of that substance than do animals who had exposure to the same taste but it was not paired with wheel running (Unpaired), demonstrating a CTA (adapted
from Lett, Grant, Koh, & Smith, 2001). Panel (b) shows the results of a CPP experiment with wheel running. If a distinctive location is paired with wheel running, animals
will spend more time in that location (Saline group) than if that location is not paired with wheel running (Control group). An opioid antagonist (Naloxone) will block the
development of this CPP (adapted from Lett, Grant, & Koh, 2001). A preference score of 50 indicates no preference.

wheel running was paired with a distinctive location (a holding cage with distinctive visual cues). Interestingly, the same
animals that developed a CTA when wheel running was
paired with a novel taste developed a conditioned place preference (CPP) for a location that had been paired with wheel
running. That is, the same activity, wheel running, can have
both positive (CPP) and aversive (CTA) effects. Although this
may be unexpected, other motivationally powerful stimuli,
such as amphetamines and opiates, support the development
of both conditioned aversions and conditioned preferences.
It has been suggested that the rewarding effects of activities such as wheel running involve the endogenous opioids
(Lett, Grant, & Koh, 2001), a class of neurotransmitters that
have opiate-like effects and include neurotransmitters such as
the endorphins (see Chapter 3). A drug called naloxone binds
to the same receptors as the opioid neurotransmitter and
morphine, but naloxone occupies the receptor without activating it. That is, naloxone is a receptor antagonist that prevents the active substance (endorphin) from having an effect
by blocking its access to the receptor. If wheel running has a
rewarding effect by activating the brain’s opioid system, then
naloxone should block this effect. Lett, Grant, and Koh (2001)
found that naloxone did prevent the development of a CPP
using wheel running. Naloxone did not change the amount of
wheel running significantly, as compared with a saline-injected
control, but it did block the rewarding effects (Figure 11.6b).

Electrically stimulating the VMH caused even
a hungry rat to stop eating, and lesioning the
VMH produced gluttons who ate frequently and

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Further evidence that wheel running activates an opioid
neurotransmitter system comes from a study in which animals were tested for a CPP (Lett, Grant, Koh, & Flynn, 2002).
Animals that had prior experience with wheel running did
not develop a CPP when a distinctive chamber was paired
with morphine. Animals without the wheel running experience showed a morphine-induced CPP. That is, the animals
with prior wheel running experience appeared to be tolerant
to the rewarding effect of morphine, a phenomenon known
generally as cross-tolerance. Within psychopharmacology,
cross-tolerance is considered to be evidence that a common brain mechanism is involved. The studies of CPP with
wheel running and of cross-tolerance to morphine indicate
that wheel running activates the brain’s endogenous opioid
system, and it is this activation that leads to the rewarding
effects of wheel running.
Wheel running is a behaviour that increases in frequency
with experience, and since there is no necessary satiation
(apart from physical exhaustion) this behaviour can come
to dominate the animals’ time, even if the excessive wheel
running and the accompanying suppression of eating means
starvation. Evidence suggests that this behaviour activates the
brain’s reward mechanisms. Understanding the changes in
motivation that allow some behaviours to become excessive,
even to the point of endangering one’s life, is clearly relevant
to the current human condition.

doubled or tripled their body weight (Hetherington & Ranson, 1942). Medical case studies of
people with damage to these hypothalamic areas

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CHAPTER ELEVEN

9. What evidence
suggested that the LH
and VMH were hunger
“on” and “off” centres?
What evidence
suggests otherwise?
10. Describe some
factors that
contribute to the
pressure women feel
to be thin.

also found that normal weight regulation was disrupted (Gazzaniga et al., 1979).
As scientists explored further, they learned that,
although the LH and VMH played a role in hunger
regulation, they were not really “hunger on” and
“hunger off ” centres (Pinel, 1997; Schwartz, 1984).
For example, rats with LH damage stop eating and
lose weight in part because they develop trouble
swallowing and digesting, and they become generally unresponsive to external stimuli, not just
to food. Moreover, axons from many brain areas
funnel into the hypothalamus and then fan out
again upon leaving it. Cutting these nerve tracts
anywhere along their path—not just within the
hypothalamus—duplicates some of the effects of
the LH and VMH lesions (Schwartz, 1984).
Researchers are examining how various neural circuits within the hypothalamus regulate food
intake. Many pathways involve the paraventricular
nucleus (PVN), a cluster of neurons packed with
receptor sites for various transmitters that stimulate
or reduce appetite (Figure 11.5). The PVN appears
to integrate several different short-term and longterm signals that influence metabolic and digestive
processes (Berthoud, 2002). One transmitter, neuropeptide Y, is a powerful appetite stimulant (Leibowitz,
1992). Rats in one experiment quickly became obese
when they received three daily injections of neuropeptide Y into their PVN for ten days. Their food
intake doubled, their fat mass tripled, and their total
body weight increased sixfold (Stanley et al., 1986).
A fascinating finding about leptin and the PVN
in rats may help to explain why we become so hungry when trying to lose weight. When leptin reaches
the hypothalamus, it seems to inhibit the activity of
neurons that release neuropeptide Y into the PVN,
and therefore appetite is reduced. But when rats
lose fat, less leptin is secreted and therefore neuropeptide Y neurons become more active, increasing
appetite (Woods & Seeley, 2002). See Table 11.1.

Psychological Aspects of Hunger
From a behavioural perspective, eating is positively
reinforced by the good taste of food and negatively
reinforced by hunger reduction. Cognitively, we
develop an expectation that eating will be pleasurable, which becomes an important motivator to seek
and consume food. Even the mere thought of food
can trigger hunger, as you may find by closing your
eyes and concentrating on the aroma, sight, and
taste of your favourite dish.
Attitudes, habits, and psychological needs also
regulate food intake. Have you ever felt “stuffed”
after gobbling up part of a meal, yet finished it
and even had dessert? Beliefs such as “don’t leave

pas77416_ch11_380-428.indd 390

food on your plate” and conditioned habits (“autopilot” snacking while watching TV) may lead us to
eat even when we do not feel hungry. Conversely,
countless dieters intentionally restrict their food
intake even though they are hungry.
Especially for women, such food restriction often
stems from social pressures to conform to cultural
standards of beauty (Figure 11.7). Studies of Playboy magazine centrefolds, beauty pageant contestants, and fashion models indicate a clear trend
toward a thinner, leaner, and increasingly unrealistic “ideal” female body shape between the 1950s and
1990s (Owen & Laurel-Seller, 2000). The culturally
defined “ideal” female body has changed again in
recent years, adding an ultra-fit physique in addition to extreme thinness (Homan et al., 2012). Correspondingly, relative to men, over the past 50 years,
women have become increasingly dissatisfied with
their body image (Feingold & Mazzella, 1998).
A classic study by April Fallon and Paul Rozin
(1985) suggests an additional reason why this is
so. University women overestimated how thin they
needed to be to meet men’s preferences, whereas
men overestimated how bulky they should be to
match women’s preferences (Figure 11.8). Women
also perceived their body shape as heavier than
ideal, whereas men viewed their body shape as close
to ideal. As Fallon and Rozin noted, “Overall, men’s
perceptions serve to keep them satisfied with their
figures, whereas women’s perceptions place pressure
on them to lose weight” (1985, p. 102). Researchers
continue to find results similar to Fallon and Rozin’s
(Carlson & McAndrew, 2004; Demarest & Allen,
2000).
People who perceive themselves as heavy tend to
have lower self-esteem, but this relation is stronger
among women than men (Miller & Downey, 1999).
According to Barbara Fredrickson and Tomi Ann
Roberts’s (1997) objectification theory, Western culture teaches women to view their bodies as objects,
much as external observers would. This perspective
increases body shame and anxiety, which in turn
leads to eating restriction and even eating disorders
(Fredrickson et al., 1998). Laboratory experiments
suggest that women do indeed restrict eating to
restore self-esteem. In one experiment, university
women ate less food in the presence of a desirable
versus undesirable male, particularly when their
feelings of femininity had been publicly threatened
beforehand (Mori et al., 1987).
The norms that “thin = attractive” and “you can
never be too thin” are strongly ingrained by adolescence and have a powerful impact even early in
adolescence. As early as the eighth grade, many
girls have adopted the belief that they have to be
thin to be popular with boys (Halpern et al., 1999),

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391

FIGURE 11.7 Throughout much of Western history, a full-bodied woman’s figure was esteemed. This is illustrated by (a) Peter Paul Rubens’s 17th-century painting,
The Three Graces, and by (b) actress Lillian Russell, who represented the American ideal of feminine beauty a century ago. In recent decades, the norm of “thin = attractive” has
evolved, as illustrated (c) by this contemporary fashion model.

and girls as young as ten years old diet to look thinner (McVey et al., 2004). Such social pressures and
beliefs can lead to a high level of dissatisfaction with
one’s own body. As few as one in five adolescent and
young adult females report being happy with their
weight, even when body weight is within a normal,
healthy range (Halpern et al., 1999; Huon et al.,
2002; Kenardy et al., 2001).

Environmental and Cultural Factors
Although not very sensitive to manipulation of
biological variables such as overfeeding, underfeeding, or changes in the caloric density of the
diet, people are very sensitive to changes in environmental stimuli, such as portion size, the number of people present during a meal, the amount
that others eat, and the variety of foods available
(Levitsky, 2005). We will consider a few of the most
important environmental variables that influence
how much we eat.
Food availability is the most obvious environmental regulator of eating. For millions of people
who live in poverty or famine-ravaged regions,
food scarcity limits consumption. In contrast,

pas77416_ch11_380-428.indd 391

abundant low-cost food (including high-fat foods)
in many countries contributes to a high rate of
obesity among children and adults (Wadden
et al., 2002).
Food taste, variety, and serving size all powerfully regulate eating. Good-tasting food positively
reinforces eating and increases food consumption,
but during a meal and from meal to meal, we can
become “tired of eating the same thing” and terminate a meal more quickly (Rolls et al., 1981). In
contrast, food variety increases consumption, which
you know all too well if you attend buffet meals. The
amount of food served also influences how much
we eat. In one study participants were presented
with a macaroni and cheese lunch in one of four
different portion sizes (Rolls et al., 2002). Although
participants did not differ in self-reported hunger
or how much food they predicted they would eat
before the lunch, the larger the portion they were
given, the more they ate. Those presented with
the largest portion size ate, on average, almost 100
grams more macaroni and cheese than those presented with the smallest serving (Figure 11.9). That
represents an additional 676 kJ (162 calories) consumed just because of a larger serving size.

11. Identify several
environmental and
cultural factors that
influence eating.

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CHAPTER ELEVEN

2

2.5
What women
rated as ideal

2

3

What women
thought men
preferred

2.5

3.5

4

3.5

What women
actually preferred

5

4.5

5

Women’s self-image

What men
actually
preferred

3

4.5

4

What men thought
women preferred

Men’s
self-image

What men rated
as ideal

FIGURE 11.8 University women overestimated how thin they needed to be to conform to men’s preferences and viewed their own body
shape as heavier than ideal. In contrast, men overestimated how bulky they should be to conform to women’s preferences but viewed their
body shape as close to ideal.
Data from Fallon & Rozin, 1985.

Through classical conditioning we learn to
associate the smell and sight of food with its taste,
and these food cues can trigger hunger. Eating
may be the last thing on your mind until your nose

Amount eaten (grams)

500
450
400
350
300
250
200
150
100

500

625

750

1000

Portion size (grams)

FIGURE 11.9 Participants were presented with a macaroni and
cheese lunch in one of four portion sizes, and the amount of food
eaten increased with portion size. This was true for both men and
women, and for normal-weight and overweight participants (data
shown is for the subject groups combined).
Data from Rolls et al., 2002.

pas77416_ch11_380-428.indd 392

detects the sensuous aroma wafting from a bakery, a pizzeria, or a popcorn machine. Dr. Harvey
Weingarten (1983), then at McMaster University,
demonstrated that rats that have eaten recently
and are not hungry (i.e., they have food available but ignore it) will eat when presented with
sounds and lights that they have learned to associate with food. Similarly, does the musical jingle
of the neighbourhood ice cream truck tweak your
hunger?
Many other environmental stimuli affect food
intake. We typically eat more when dining with
other people than when eating alone, in part
because meals take longer (de Castro, 2002). Cultural norms influence when, how, and what we
eat. In countries such as Spain and Greece, people
often begin dinner in the late evening (say, around
9:00 p.m.), by which time most North Americans
have long finished their supper. And although we
like variety, we usually feel most comfortable selecting from among familiar foods and often have difficulty “getting past” our squeamish thoughts about
unfamiliar dishes.

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Motivation and Emotion

Obesity
The heaviest known man and woman in recorded
history, both Americans, weighed 635 kilograms
and 545 kilograms at their respective peaks in 1978
and 1987 (Guinness Book, 2000). (After hospitalization and dieting, the man lost 418 kilograms over
16 months, and the woman lost 417 kilograms over
seven years.) Health Canada guidelines suggest
that a body mass index (BMI, the ratio of weight
to height—kg/m2) between 25 and 29.9 is considered overweight, and a BMI over 30 is considered
obese. According to recent statistics, more than half
of adult Canadians (52.5 percent) are either overweight or obese, with 19.8 percent of men and 16.8
percent of women classified as obese (Statistics
Canada, 2013). Among Canadian children, almost
20 percent are overweight and 8 percent are obese.
Statistics Canada reported a 500 percent increase
in childhood obesity between 1980 and 2004. Not
only does obesity pose a health risk, but it can also
expose the individual to stereotypes and prejudice
(Teachman et al., 2003).
Obesity is often blamed on a lack of willpower,
a weak character, or emotional disturbances, but
research does not consistently find such psychological differences between obese and nonobese people (Faith et al., 2002). Some scientists
hypothesize that eating is an attempt to cope with
stress (Wallis & Hetherington, 2004) or that obese
people react more strongly than non-obese people
to food cues, such as the appearance or taste of
food (Stice et al., 2008). But again, evidence that
these factors cause obesity is mixed (Greeno &
Wing, 1994).

1998). However, although heredity affects our
susceptibility to obesity, so does the environment.
Genes have not changed much in recent decades,
but obesity rates in Canada and the United States
have increased significantly. According to experts
such as James Hill and John Peters (1998), the
culprits are
• an abundance of inexpensive, tasty, high-fat
foods available almost everywhere;
• a cultural emphasis on “getting the best value,”
which contributes to the “supersizing” of menu
items; and
• technological advances that decrease the need
for daily physical activity and encourage a sedentary lifestyle.
The Pima Indians of Arizona provide a striking
example of how genes and environment interact
to produce obesity. Despite the fact that the Pimas
are genetically predisposed to obesity and diabetes,
both conditions were rare among tribe members
before the 20th century (Savage & Bennett, 1992).
Their native diet and way of life prevented their
genetic predisposition from expressing itself. But,
particularly among Pimas born after World War II,
obesity rates increased dramatically as they adopted
a Westernized diet and sedentary lifestyle (Price
et al., 1993; Esparza et al., 2000). Today, they have
one of the highest rates of obesity (and diabetes) in
the world. In contrast, Pimas living in northwest
Mexico, who still eat a more traditional diet and
perform more physical labour, have an obesity rate
much lower than that of their Arizonan counterparts (Ravussin et al., 1994).

Genes and Environment

Dieting and Weight Loss

Do you know people who seem to gain weight easily
and other envied souls who eat even more food without adding weight? Data from over 25 000 pairs of
twins and 50 000 other biological and adoptive family members point to heredity as one source of such
differences. Heredity influences our basal metabolic
rate and tendency to store energy as either fat or
lean tissue (Bouchard et al., 1990). Overall, genetic
factors appear to account for about 40 to 70 percent
of the variation in body mass among women and
men (Maes et al., 1997; Comuzzie & Allison, 1998).
Identical twins reared apart are about as similar in
body mass as identical twins reared together, and
adopted children resemble their biological parents
more closely than their adoptive parents (Stunkard
et al., 1990).
More than 200 genes have been identified as
possible contributors to human obesity, and in
most cases, it is the combined effect of a subset of
genes—rather than “single-gene” variations—that
produces an increased risk (Comuzzie & Allison,

Unfortunately, being fat primes people to stay fat,
in part by altering body chemistry and energy
expenditure (Logue, 1991). For example, obese
people generally have higher levels of insulin (a
hormone secreted by the pancreas) than people of
normal weight, which increases the conversion of
glucose into fat. Substantial weight gain also makes
it harder to exercise vigorously, and dieting slows
basal metabolism because the body responds to
food deprivation with decreased energy expenditure. Along with a genetic predisposition to obesity,
these factors cause many obese people to maintain
excess weight with fewer calories than people who
are gaining the same weight for the first time. In
contrast to earlier reports, however, there is no
consistent evidence that the body’s energy-saving
metabolic slowdown becomes more pronounced
with each weight loss attempt (Brownell & Rodin,
1994, National Task Force, 1994). Thus, whether
repeated “yo-yo dieting” makes it more difficult to
lose weight is debatable.

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393

12. What evidence
suggests a genetic
role in obesity?
How does obesity
among the Pima
Indians illustrate a
gene–environment
interaction?

13. Why is it especially
hard for obese
people to lose
weight? Are diets
doomed to fail?

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CHAPTER ELEVEN

Applications
THE BATTLE TO CONTROL
EATING AND WEIGHT
Many people, especially high school and university students,
are concerned about their weight. Many adolescent females
with average and even below-average body fat diet (Kenardy
et al., 2001). Our dissatisfaction with our bodies begins at
an alarmingly young age. One study found that almost 30
percent of 10- to 14-year-old girls were trying to lose weight
and look thinner (McVey et al., 2004). Our body size and
shape, or, more accurately, our perception of our body size
and shape forms an important part of our self-image. How
we perceive our own body and how closely that matches
our ideal is an important issue for many (l