Bioinformatics Uncovers Regenerative Therapy for Spinal Cord Injury

Research Alerts

Story by:

• Miles Martin- [email protected]

Topics covered:

• Spinal cord injury
• Regeneration
• Neurology

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Spinal cord injury (SCI) remains a major unmet medical challenge, often resulting in permanent paralysis and disability with no effective treatments. Now, researchers at University of California San Diego School of Medicine have harnessed bioinformatics to fast-track the discovery of a promising new drug for SCI. The results will also make it easier for researchers around the world to translate their discoveries into treatments.

One of the reasons SCI results in permanent disability is that the neurons that form our brain and spinal cord cannot effectively regenerate. Encouraging neurons to regenerate with drugs offers a promising possibility for treating these severe injuries.

The researchers found that under specific experimental conditions, some mouse neurons activate a specific pattern of genes related to neuronal growth and regeneration. To translate this fundamental discovery into a treatment, the researchers used data-driven bioinformatics approaches to compare their pattern to a vast database of compounds, looking for drugs that could activate these same genes and trigger neurons to regenerate.

Their approach identified Thiorphan - a drug previously tested in humans for non-neurological conditions - as a top candidate. The researchers successfully tested Thiorphan in adult human brain cells, finding that it increased neurite outgrowth, a key metric of regeneration. Being able to confirm that the drug works in adult human brain cells is a significant technical achievement, as brain cells are notoriously difficult to culture in the lab, making them virtually impossible to study in culture dishes.

The researchers also tested the drug in rats with SCI, finding that when combined with neural stem cell grafts, Thiorphan led to significant improvements in hand function and an increase in neuronal regeneration into the injury site. Rats treated with Thiorphan alone had a 50% increase in recovery of hand function after SCI compared to untreated animals, and another 50% improvement in hand function when Thiorphan was combined with a neural stem cell implant. The researchers are now considering combining Thiorphan with stem cell technology in clinical trials that are planned for the near future.

"We were very happy to see that a drug that worked on cells in culture also showed effectiveness in an actual animal model of spinal cord injury," said Erna van Niekerk, Ph.D., assistant project scientist in the Department of Neurosciences at UC San Diego School of Medicine and lead author of the study. "This is not always the case in new drug development."

"We succeeded in culturing adult human brain cells in large numbers in this study, offering a powerful new tool for the discovery of treatments for neurological disorders... The ability to culture adult brain cells could be useful for testing new drugs or gene therapies for many brain diseases." - Mark H. Tuszynski, professor in the Department of Neurosciences at UC San Diego