July 14, 2024

The mysterious science of pain - Joshua W. Pate

Published May 29, 2023, 5:20 p.m. by Violet Harris

The Mysterious science of pain | Joshua W. Pate by ted-Ed

Why do we feel pain? It’s a question that has puzzled scientists for centuries. And it’s one that Joshua W. Pate, a pain researcher at the University of Florida, is trying to answer.

In this ted-Ed talk, Pate explains the difference between nociception and pain. Nociception is the ability to sense potentially harmful stimuli. It’s a survival mechanism that helps us avoid injury. pain, on the other hand, is a subjective experience that is influenced by our emotions and past experiences.

Pate describes some of the latest research on pain, including the discovery of pain receptors in the brain. He also discusses the role of the nervous system in pain perception and the potential for new treatments that target pain at the source.

This talk is sure to leave you with a greater understanding of the complex science of pain.

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In 1995, the British Medical Journal

published an astonishing report about a 29-year-old builder.

He accidentally jumped onto a 15-centimeter nail,

which pierced straight through his steel-toed boot.

He was in such agonizing pain that even the smallest movement was unbearable.

But when the doctors took off his boot, they faced a surprising sight:

the nail had never touched his foot at all.

For hundreds of years,

scientists thought that pain was a direct response to damage.

By that logic, the more severe an injury is, the more pain it should cause.

But as we’ve learned more about the science of pain,

we’ve discovered that pain and tissue damage don’t always go hand in hand,

even when the body’s threat signaling mechanisms are fully functioning.

We’re capable of experiencing severe pain out of proportion to an actual injury,

and even pain without any injury,

like the builder, or the well-documented cases of male partners

of pregnant women experiencing pain during the pregnancy or labor.

What’s going on here?

There are actually two phenomena at play:

the experience of pain, and a biological process called nociception.

Nociception is part of the nervous system’s protective response

to harmful or potentially harmful stimuli.

Sensors in specialized nerve endings

detect mechanical, thermal, and chemical threats.

If enough sensors are activated,

electrical signals shoot up the nerve to the spine and on to the brain.

The brain weighs the importance of these signals

and produces pain if it decides the body needs protection.

Typically, pain helps the body avoid further injury or damage.

But there are a whole set of factors besides nociception

that can influence the experience of pain— and make pain less useful.

First, there are biological factors that amplify nociceptive signals to the brain.

If nerve fibers are activated repeatedly,

the brain may decide they need to be more sensitive

to adequately protect the body from threats.

More stress sensors can be added to nerve fibers

until they become so sensitive that even light touches to the skin

spark intense electrical signals.

In other cases,

nerves adapt to send signals more efficiently, amplifying the message.

These forms of amplification

are most common in people experiencing chronic pain,

which is defined as pain lasting more than 3 months.

When the nervous system is nudged into an ongoing state of high alert,

pain can outlast physical injury.

This creates a vicious cycle in which the longer pain persists,

the more difficult it becomes to reverse.

Psychological factors clearly play a role in pain too,

potentially by influencing nociception and by influencing the brain directly.

A person’s emotional state, memories,

beliefs about pain and expectations about treatment

can all influence how much pain they experience.

In one study,

children who reported believing they had no control over pain

actually experienced more intense pain

than those who believed they had some control.

Features of the environment matter too:

In one experiment,

volunteers with a cold rod placed on the back of their hand

reported feeling more pain when they were shown a red light than a blue one,

even though the rod was the same temperature each time.

Finally, social factors like the availability of family support

can affect perception of pain.

All of this means that a multi-pronged approach to pain treatment

that includes pain specialists, physical therapists, clinical psychologists, nurses

and other healthcare professionals is often most effective.

We’re only beginning to uncover the mechanisms behind the experience of pain,

but there are some promising areas of research.

Until recently,

we thought the glial cells surrounding neurons were just support structures,

but now we know they have a huge role in influencing nociception.

Studies have shown that disabling certain brain circuits in the amygdala

can eliminate pain in rats.

And genetic testing in people with rare disorders

that prevent them from feeling pain

have pinpointed several other possible targets for drugs

and perhaps eventually gene therapy.


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