Mechanisms of How Morphine Relieves Pain Mapped Out

Mechanisms of How Morphine Relieves Pain Mapped Out
Identification of neurons that regulate morphine antinociception. (Top) Systemic injection of morphine increases “OFF” cell activity in the RVM. Sequencing reveals many cells with “OFF” cell activity as RVMBDNF neurons. (Middle) Sequencing spinal neurons activated by RVMBDNF neurons identifies SCGal neurons. (Bottom) Under normal physiology, RVMBDNF and SCGal neurons act to suppress ascending pain signals (yellow arrows). Inhibition of RVMBDNF neurons enhances, whereas morphine activation inhibits, these ascending signals. [Figure created with Biorender.com]
In a study published in Science, researchers at Karolinska Institutet describe the neural processes behind how morphine relieves pain. This is valuable knowledge because the drug has such serious side effects.

Morphine is a powerful painkiller that belongs to the group of opioids. It blocks signals in the pain pathways and also increases feelings of pleasure.
Morphine acts on several central and peripheral pain pathways in the body, but the neural processes behind the pain relief have not previously been fully understood.

Researchers have now investigated how morphine relieves pain using several new experimental approaches. They have exposed laboratory animals to morphine and then managed to “capture” the neurons that the morphine activated in the animals. This allowed the researchers to identify, classify and synthetically control the neurons in the neural pathways involved in pain relief.

Morphine activates a ‘morphine ensemble’

The researchers discovered that morphine affects a selected set of neurons in the brain in the part called the rostral ventromedial medulla (RVM). Together, these neurons form a kind of ‘morphine ensemble’. This is a group of neurons whose change in activity leads to pain relief.

When the researchers synthetically inactivated the neurons in this group, they completely abolished the effects of morphine on pain. When they reactivated the neurons, they were able to similarly recreate the pain relief.

A particular type of neuron that wires to the spinal cord was found to play a central role in the ‘morphine ensemble’. In the spinal cord, these neurons connect to so-called inhibitory neurons that slow down pain signaling in the spinal cord and thus prevent pain.

Potentially risky drug

When used as a medicine in healthcare, morphine has potentially very serious side effects in terms of addiction, abuse, overdose and death.

“It has been difficult to find strategies to treat pain without triggering these dangerous side effects,” says Patrik Ernfors, professor at the Department of Medical Biochemistry and Biophysics at Karolinska Institutet and the leader of the study.

He and his colleagues now hope that deeper knowledge of how morphine works in the body can help reduce side effects in the future.

“The study is important because knowledge of the neural pathway and cells may explain how morphine can have such a powerful pain-relieving effect. It may also provide information on how these processes differ from those that induce the feeling of euphoria, well-being and addiction,” says Patrik Ernfors.

In the next step, the researchers want to go further and investigate the reasons why the pain relief decreases more and more with long-term use of morphine.

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