|
 |
Web Site:
ScienceDaily Magazine
Page URL:
http://www.sciencedaily.com/releases/2003/11/031111064658.htm
Original Source: Society For
Neuroscience
Date Posted:
2003-11-11
Scientists Uncover Neurobiological Basis For Romantic Love,
Trust, And Self
NEW ORLEANS, Nov. 10 - In new studies, scientists are discovering
the neurobiological underpinnings of romantic love, trust, and even
of self. New research also shows that a specific brain area - the
amygdala - is involved in the process of understanding the
intentions of others, in particular when lying is involved.
Using brain imaging, researchers Helen Fisher, Arthur Aron, Lucy
Brown and colleagues find that feelings of intense romantic love are
associated with specific activity in dopamine-rich brain regions
associated with reward and motivation. Those study participants who
expressed more romantic passion on a questionnaire showed more brain
activity in these regions. Those in longer relationships showed more
activation in emotion-related areas as well. And men and women
tended to show some different brain responses. The researchers
conclude that romantic love may be best classified as a motivation
system or drive associated with a range of emotions. Further studies
of intense, early stage romantic love may help to define how the
brain encodes reward and memory.
In this experiment, 17 young men and women who had "just fallen
madly in love" were tested with functional magnetic resonance
imaging (fMRI) to identify the brain circuitry of romantic love.
"We believe romantic love is a developed form of one of three
primary brain networks that evolved to direct mammalian
reproduction," says researcher Helen Fisher, PhD, of Rutgers
University in New Brunswick, NJ. "The sex drive evolved to motivate
individuals to seek sex with any appropriate partner. Attraction,
the mammalian precursor of romantic love, evolved to enable
individuals to pursue preferred mating partners, thereby conserving
courtship time and energy. The brain circuitry for male-female
attachment evolved to enable individuals to remain with a mate long
enough to complete species-specific parenting duties."
In the study, participants alternately viewed a photo of a
beloved and a photo of a familiar, emotionally neutral individual,
interspersed with a distraction task. The researchers hypothesized
that intense early stage romantic love is: (1) primarily associated
with dopamine pathways in the reward system in the brain; and (2)
primarily a motivation system (as opposed to an emotion) oriented
around planning and pursuit of a pleasurable reward - an intimate
relationship with a preferred mating partner.
"Our evidence suggests that both hypotheses are correct," says
Lucy Brown, PhD, of the Albert Einstein College of Medicine in New
York. "We found specific activity in regions of the right caudate
nucleus and right ventral tegmental area. These brain areas are rich
in dopamine and are part of the brain's motivation and reward
system. Elevated levels of central dopamine produce energy, focused
attention on novel stimuli, motivation to win a reward and feelings
of elation - some of the core feelings of romantic love. Activity in
other regions changed also, including one that another imaging study
has shown to became active when people eat chocolate."
The researchers also found that those who scored higher on the
"Passionate Love Scale," a questionnaire administered prior to
scanning, also showed more activity in the caudate. Arthur Aron,
PhD, of SUNY Stony Brook, NY, says, "This result is among the first
to show a direct link between responses to a survey questionnaire
and a specific pattern of brain activation."
Fisher, Aron, and Brown also found a tendency toward gender
differences. Among them, most of the women in this study showed more
activity in the body of the caudate, the septum, and posterior
parietal cortex, regions associated with reward, emotion and
attention; most of the men in this study showed more activity in
visual processing areas, including one associated with sexual
arousal.
Aron, Fisher and Brown have embarked on a follow-up fMRI study of
men and women who have recently been rejected in love. They wish to
understand the full range of brain systems associated with this
primordial, powerful and universal human phenomenon.
In another study, Paul Zak, PhD, and his colleagues at Claremont
Graduate University investigated trust - something that pervades
nearly every aspect of our daily lives. Even so, the neurobiological
mechanisms that permit human beings to trust each are not
understood.
In the new research, Zak and his colleagues find that when
someone observes that another person trusts them, oxytocin - a
hormone that circulates in the brain and the body - rises. The
stronger the signal of trust, the more oxytocin increases. In
addition, the more oxytocin increases, the more trustworthy
(reciprocating trust) people are.
"Interestingly, participants in this experiment were unable to
articulate why they behaved they way they did, but nonetheless their
brains guided them to behave in 'socially desirable ways,' that is,
to be trustworthy," says Zak. "This tells us that human beings are
exquisitely attuned to interpreting and responding to social
signals.
The findings are even more surprising because monetary transfers
were used to gauge trust and trustworthiness, and the entire
interaction took place by computer without any face to face
communication. Signals of trust are sent by sending money that
participants earned to another person in a laboratory, without
knowing who that person is or what they will do. That, is, there is
a real cost to signaling that you trust someone.
In the experiment, people were recruited and paid $10 for showing
up. Then they took seats in a large computer lab and were matched up
in pairs, but this was done completely anonymously so that no one
knew (or would know) the other person in his or her pair. One-half
of the participants (decision-maker 1s) then had the opportunity to
send none, some, or all of their $10 show-up fee to the other person
in their pair. Whatever is sent is tripled. So, if $4 was sent, the
other person would have $22 ($4 tripled, plus the $10 show-up fee
the second person receives). The second decision-maker could then
send some amount of this money back to decision-maker 1, but need
not. This is how the researchers produced a social signal of trust:
decision-maker 1's only reason to transfer money to the other person
is because he or she trusts that that person will understand why the
money is being sent to them, and in turn will return some to them
(be trustworthy). All subjects are told that the initial monetary
transfer is tripled, and there is no deception of any kind.
After each person makes his or her decision, they were taken to
another room and four tablespoons of blood were taken from an arm
vein. Animal studies have shown that oxytocin, a hormone little
studied in humans, facilitates social recognition and social
bonding, for example, bonding of mothers to their offspring, and in
some monogamous species the bonding of males and females in a family
unit.
Based on the animal studies, the scientists hypothesized that
what is happening in the trust experiment is that people are forming
temporary social bonds with the other person in their pair. "This is
just what we found. The stronger the signal of trust, the more
oxytocin increases, and the more trustworthy people are. This is
surprising given the sterile laboratory environment of the
interaction so that the effect of oxytocin on face-to-face
interactions must be quite strong," says Zak.
He also found that women in the experiment who are ovulating were
significantly less likely to be trustworthy (for the same signal of
trust). This effect is caused by the physiologic interactions
between progesterone and oxytocin, and it makes sense behaviorally:
women who are, or are about to be, pregnant, need to be much more
selective in their interpretation of social signals, and also need
more resources than at other times.
Zak's lab is now studying brain activation patterns when people
receive signals of trust, as well as in the physiologic responses to
trust signals in patients who have neurological damage. Trust is an
essential part of our daily lives, from walking down the street to
driving to countless other daily activities, so that discovering the
neurobiology of trust tells us something important about human
nature: that we are so highly social that we pick up social signals
of trust and act on them even when we are not consciously aware of
these signals. Our brain acts as an internal compass that guides us
towards the "right" thing to do.
In another imaging study, scientists at Stanford University
located brain areas associated with self and self relevance. The new
work helps answer questions such as why people hear their own names
in the din of a cocktail party or the fog of sleep.
In the study, Wemara Lichty, PhD, and her colleagues used rapid
event-related fMRI to dissociate brain activations related to names.
Sixteen females heard five different auditory stimuli: 1) a tone; 2)
a low frequency name (not self-relevant), 3) a high frequency name
(not self-relevant), 4) a self-relevant name (e.g., sister or best
friend), and 5) their own name. To ensure that participants were
attending, they performed a simple task of pushing a button for each
sound; specifically one button was pressed if a sound was the same
as the preceding one, and a different button was pressed if the
sound was the same. They listened to a total of 250 sounds over a
period of 12 minutes.
The study was designed to answer the question: Is there something
special about our own name and the names of those we are close to;
i.e., is there a hint of that relationship in brain activations? The
researchers identified areas special for personally relevant names
compared to non-personally relevant names: The left medial
prefrontal cortex, an area that has been associated with self, was
active. "Interestingly, this putative self-related area was also
active in a study for names of close associates. This suggests that
the medial prefrontal cortex may be involved in processing a
personal network related to the self," says Lichty. Although imaging
studies have not evaluated this, behavioral studies have shown that
on many cognitive tasks, the performance of self and close others is
often similar and quite different from that of persons not known.
Also activated was the left posterior cingulate, an area involved in
autobiographical memory.
The study also addressed whether there is something completely
unique about a person hearing his or her name. Are there areas
activated only by one's own name and not the name of others we know?
Results showed that the right middle temporal gyrus was active.
"This may suggest that the special status of one's own name is
related to altered cortical perceptual representations. Enhanced
hearing of one's own name may be associated with decreased
thresholds for auditory cortical activation. However, the activation
may also be related to self as separate from close others as
suggested by the similarity of our area of activation with the
findings of an fMRI study of activations related to faces of oneself
and one's partner," Lichty says.
She notes that understanding how we differ from each other and
how we are related to each other can offer insight, both into the
essential aspects of our individual and communal identity.
Clinically, this could be of import regarding understanding of
individuals who may have weak (underdeveloped, undifferentiated)
self. In addition, it may provide greater insight into
relationships.
Another new study explores the brain mechanisms involved in
deception. What happens when you spot deception in a human movement?
The sort of thing a hitter tries to do every time a pitcher prepares
to throw a ball.
Working out whether there is deception results in activation of
the amygdala, a structure in the brain involved in perceiving fear
and in learning about fearful or threatening stimuli. Our new
finding is that the amygdala is also involved in understanding the
intentions of others, in particular when lying is involved and when
actions are being scrutinized.
"Our study finds a link between emotional brain systems and the
complex brain network used to read intention in the movements of
others," says Richard Frackowiak, MD, of University College London.
"So, emotional responses can be driven by factors other than empathy
with someone else's emotions. The emotional brain responds to an
intention to deceive even when the deception involves a trivial
action."
The clinical importance of this work is for patients with
amygdala damage. For example, there are abnormalities reported in
the amygdalae of adults with autism. Such patients tend to be
excessively trusting. This may not be to do with character judgment
as such, but with failing to recognize potential social threats in a
stream of observed actions or gestures.
In a scanning experiment Frackowiak and his colleagues approached
this issue by getting actors to lift boxes with weights. Sometimes
the experimenter lied to them about the weight in the box so their
movements were likely subtly modified. Subjects were shown these
films while brain activity was recorded in a scanner and were asked
to rate whether the actor had been deceived on each occasion.
The researchers specifically compared activity in subjects'
brains when they judged that an actor was deceived with that when
they thought all was above board in order to isolate brain regions
associated with perceived deception. In future work these scientists
plan to compare situations in which an actor is trying to deceive a
third party with those in which the actor is trying to deceive the
subjects themselves. This will indicate whether it is simply the
perception of deception that is important or whether the object of
that deception matters.
Many experiments have been performed using imaging to study
cognitive processes such as attention, memory or action. But,
Frackowiak says we do not simply base our judgments on reason. "The
amygdala can be regarded as part of our emotional core system and
our results show that we are deeply affected when we think someone
is trying to deceive us, over even so simple a matter as the weight
of a box. The interaction between emotion and cognition is thus
becoming clarified.
Note: This story has been adapted from a news release
issued by Society For Neuroscience.
Back to DA*DI's
Home
Dads Against the Divorce Industry