Illustration of mitochondria transferring from glia to neurons to reduce nerve pain in neuropathy models.
Illustration of mitochondria transferring from glia to neurons to reduce nerve pain in neuropathy models.
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Duke-led Nature study links glia-to-neuron mitochondria transfer to reduced nerve pain in neuropathy models

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Duke University researchers report that boosting the transfer of healthy mitochondria from support cells to sensory neurons reduced pain-like behaviors in mouse models of diabetic and chemotherapy-related peripheral neuropathy, an approach they say could address a root driver of nerve pain rather than simply blocking pain signals.

Researchers at Duke University School of Medicine say they have identified a cell-to-cell “recharging” process that may help explain — and potentially counter — chronic nerve pain caused by peripheral neuropathy.

In a study published in Nature, the team used experiments in human tissue and mouse models to examine how satellite glial cells, which surround sensory neurons in the dorsal root ganglia, deliver mitochondria — the cell’s energy-producing structures — into nearby neurons through tunneling nanotube-like structures. The researchers reported that neuropathy-linked conditions disrupted this transfer and that restoring or enhancing it reduced pain-related behaviors in mice.

When the researchers increased mitochondrial transfer in mice, pain-related behaviors fell by as much as 50%, Duke said in a summary of the findings. In some experiments, the pain relief lasted up to 48 hours.

The Duke report also said the team tested a more direct approach by injecting isolated mitochondria into dorsal root ganglia, finding that outcomes depended on mitochondrial health: mitochondria from healthy donors reduced pain in mice, while mitochondria from people with diabetes did not. The researchers additionally identified the protein MYO10 as important for forming the tunneling nanotubes that enable the transfer.

The work remains preclinical, and the researchers said further studies are needed to clarify exactly how the nanotube structures deliver mitochondria in living nerve tissue and to assess whether the strategy could translate into treatments for people with chronic neuropathic pain.

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Microscopic illustration of migrating neurons in the developing brain showing DNA damage and repair.
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Developing neurons sustain and rapidly repair DNA double-strand breaks during migration, study finds

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A study in Nature reports that newborn neurons can incur double-strand DNA breaks while squeezing through tight spaces in the developing brain, and that healthy cells typically repair most of this damage within about a day.

Researchers at the University of Cambridge have developed miniature lab-grown models of the human brain and spinal cord that show damaged nerve fibers can regain the ability to regrow under certain conditions.

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Researchers at the University of Colorado Boulder have pinpointed a brain region called the caudal granular insular cortex, or CGIC, that acts as a switch turning acute pain into chronic pain. In animal studies, disabling this circuit prevented chronic pain from developing or reversed it once established. The findings, published in the Journal of Neuroscience, open paths to new treatments beyond opioids.

Researchers at Marshall University report that microscopic particles found in the gut lumen—known as exosomes—differ between young and old mice and can influence metabolism and gut-barrier function when transferred between animals. The findings, published in the journal Aging Cell, suggest these particles may help drive biological changes associated with aging, though the work is preclinical.

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Researchers have identified declining levels of phosphatidylcholine as a key driver of age-related mitochondrial dysfunction. The discovery, made at the Leibniz Institute on Aging in Germany, shows that boosting this lipid can restore youthful mitochondrial function in laboratory models.

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