{"id":66489,"date":"2025-09-04T00:01:22","date_gmt":"2025-09-03T22:01:22","guid":{"rendered":"https:\/\/www.3dnatives.com\/en\/?p=66489"},"modified":"2025-09-02T10:35:57","modified_gmt":"2025-09-02T08:35:57","slug":"3d-printed-scaffolds-offer-new-treatment-for-spinal-cord-injuries-04092025","status":"publish","type":"post","link":"https:\/\/www.3dnatives.com\/en\/3d-printed-scaffolds-offer-new-treatment-for-spinal-cord-injuries-04092025\/","title":{"rendered":"3D Printed Scaffolds Offer New Treatment for Spinal Cord Injuries"},"content":{"rendered":"
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In the United States, approximately 300,000 people are living with spinal cord injuries. These injuries can stem from trauma or previous medical conditions, and each year, there are about 18,000 new cases. Spinal cord injuries mostly affect men, and to date, there are no treatment options that have been able to fully restore lost body functions. The complexity of these injuries lies mainly in the destruction of nerve cells and the inability of nerve fibers to regenerate at the injury site, often resulting in permanent paralysis.<\/p>\n

For the first time, researchers at the University of Minnesota Twin Cities have developed an innovative approach. Their method combines 3D printing, stem cell therapy, and lab-grown tissue engineering, opening new possibilities for repairing spinal cord injuries and promoting functional recovery.<\/p>\n<\/div>\n<\/div>\n<\/div>\n<\/div>\n

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Photo Credit: University of Minnesota<\/p><\/div>\n

3D-Printed Scaffolds to Repair the Spinal Cord<\/h2>\n

The technique is based on the fabrication of a 3D-printed structure designed to host lab-grown tissues, which researchers call an organoid scaffold. This structure contains tiny microscopic channels into which spinal cord\u2013specific neural progenitor cells are introduced. These cells, derived from human adult stem cells, have the ability to multiply and transform into different types of mature nerve cells. \u201cWe use the 3D printed channels of the scaffold to direct the growth of the stem cells, which ensures the new nerve fibers grow in the desired way,<\/em>\u201d explains Guebum Han, former postdoctoral researcher in mechanical engineering at the University of Minnesota and first author of the study. \u201cThis method creates a relay system that, when placed in the spinal cord, bypasses the damaged area.<\/em>“<\/p>\n

In their experiment, the researchers implanted these scaffolds in rats with severe spinal cord injuries. The cells turned into neurons and developed nerve fibers in both directions, forming new connections with existing neural circuits. Over time, these new cells fully integrated into the spinal cord tissue, enabling the rats to regain certain motor functions. \u201cRegenerative medicine has brought about a new era in spinal cord injury research,<\/em>\u201d says Ann Parr, professor of neurosurgery at the University of Minnesota. While this research is still in its early stages, it represents a new source of hope for people affected by such injuries. The team now plans to scale up production of these structures and continue their development for future medical applications.<\/p>\n<\/div>\n