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NOVA ScienceNOW

Mirror Neurons

  • Teacher Resource
  • Posted 04.19.07
  • NOVA scienceNOW

This video segment, adapted from NOVA scienceNow, describes the recent discovery and implications of mirror neurons, a specific kind of brain cell that fires both when performing an action and when observing someone else perform the same action. It turns out that mirror neurons, which are normally associated with physical activities, might also be responsible for signaling the human brain's emotional system, which in turn allows us to empathize with other people. Their failure to work normally might explain why some people, including autistic people, do not interact well with others.

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NOVA scienceNOW Mirror Neurons
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  • Media Type: Video
  • Running Time: 4m 35s
  • Size: 13.7 MB
  • Level: Grades 6-12

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Source: NOVA scienceNOW: "Mirror Neurons"

This media asset was adapted from NOVA scienceNOW: "Mirror Neurons"

Background

Until recently, what doctors and scientists knew about brain function came from observing what stopped working when the brain was injured. Studying head-trauma victims, they attributed different functions to various structures of the brain. They found, for instance, that an injury to the temporal lobe of the brain often compromised a patient's language skills.

New technologies allow scientists to look deep within the human brain and observe what's happening there. For example, Functional Magnetic Resonance Imaging (fMRI) scanners detect the levels of oxygen in blood flowing through an area of the brain. Because blood oxygen levels and brain activity are positively correlated, scientists can tell whether a given part of the brain is functioning during certain tasks: Higher oxygenation means increased neural activity.

Normal brain activity relies on communication between networks of specialized nerve cells, called neurons, and other types of cells in the body. Neurons transmit signals via electrical pulses to control the release of chemicals. These chemicals, called neurotransmitters, are then passed to other neurons or directly to the cells of a target tissue, like a muscle. Neurotransmitters have either an excitatory or an inhibitory effect on neighboring cells. This means that they can either increase or decrease the likelihood that a target cell will be stimulated to forward its own electrochemical signals.

One's ability to identify with and understand another person's situation, feelings, or motives is called empathy. How humans generate empathy remains a subject of debate in cognitive science. Some scientists believe they may have finally discovered its root in specific kinds of nerve cells—mirror neurons. First identified in monkeys in the 1990s, mirror neurons are also known as "monkey-see, monkey-do" cells.

Scientists noted that mirror neurons were active when a monkey performed an action, like reaching out to grab a peanut, as well as when the monkey observed the same action being performed by another monkey. Thus, the neuron activity in the observer monkey mirrored that of the monkey performing the action, just as if the observer monkey had performed the action itself. Interestingly, there is evidence that a similar "observation-action" matching system exists in humans.

Drawing on this connection, researchers have implicated the mirror neuron system in a broad range of human conditions, including certain cognitive disorders. For example, some dysfunction or deficiency in the mirror neuron system may underlie autism, which is characterized by an impaired ability to communicate and relate to others. Understanding the neural basis of autism may lead to early diagnosis and potential therapies.

To learn more about Functional Magnetic Resonance Imaging, a new technology that allows scientists to monitor brain activity, check out Brain Geography.

To learn more about the structures and functions of the brain, check out Growing Up with Epilepsy: Brain Anatomy and Development.

Find viewing ideas on NOVA Teachers for this video segment.

Questions for Discussion

    • Why do the brain waves of mirror neurons for "doing" and for "seeing" look the same?
    • Explain why the action of mirror neurons is a big part of what makes us human.
    • Based on what you have just seen in the video, how would deficits in the mirror neuron system help explain the social behavior of people with autism?

Resource Produced by:


					WGBH Educational Foundation

Collection Developed by:


						WGBH Educational Foundation

Collection Credits

Collection Funded by:


						The William and Flora Hewlett Foundation



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