A research team at RCSI University of Medicine and Health Sciences has developed a 3D-printed implant to deliver electrical stimulation to injured areas of the spinal cord offering a potential new route to repair nerve damage. Details of the 3D-printed implant and how it performs in lab experiments have been published in the journal Advanced Science.
Spinal cord injury is a life-altering condition that can lead to paralysis, loss of sensation and chronic pain. In Ireland, more than 2,300 individuals and families are living with spinal cord injury, but no treatment currently exists to effectively repair the damage. However, therapeutic electrical stimulation at the injury site has shown potential in encouraging nerve cells (neurons) to regrow.
“Promoting the regrowth of neurons after spinal cord injury has been historically difficult however our group is developing electrically conductive biomaterials that could channel electrical stimulation across the injury, helping the body to repair the damaged tissue,” explains Prof. Fergal O’Brien, deputy vice chancellor for research and innovation and professor of bioengineering and regenerative medicine at RCSI and head of RCSI’s Tissue Engineering Research Group (TERG).
“The unique environment provided by the AMBER Centre which sees biomedical engineers, biologists, and material scientists working together to solve grand societal challenges provides a major opportunity for disruptive innovation such as this.”
A New Generation
The study was led by researchers at RCSI’s TERG and the Research Ireland Centre Advanced Materials and Bioengineering Research (AMBER). The team used ultra-thin nanomaterials from Prof. Valeria Nicolosi’s laboratory in the School of Chemistry and AMBER at Trinity College Dublin which are normally used for applications like battery design and integrated them into a soft gel-like structure using 3D printing techniques.
The resulting implant mimics the structure of the human spinal cord and features a fine mesh of tiny fibers that can conduct electricity to our cells. When tested in the lab, the implant was shown to effectively deliver electrical signals to neurons and stem cells, enhancing their ability to grow.
Modifying the fiber layout within the implant was also found to further improve its effectiveness.
“These 3D printed materials allow us to tune the delivery of electrical stimulation to control regrowth and may enable a new generation of medical devices for traumatic spinal cord injuries,” says Dr. Ian Woods, Research Fellow at TERG and first author of the study. “Beyond spinal repair, this technology also has potential for applications in cardiac, orthopedic, and neurological treatments where electrical signaling can drive healing.”
Deepening Our Understanding
The RCSI and AMBER researchers teamed up with the Irish Rugby Football Union Charitable Trust (IRFU-CT) on the project and brought together an advisory panel to oversee and guide the research. The group included seriously injured rugby players, clinicians, neuroscientists, and researchers.
“Through their expertise, the advisory panel helped deepen our understanding of the lived experiences of individuals with spinal cord injuries, their treatment priorities and emerging treatment approaches,” says Dr. Woods. “Our regular meetings allowed for a consistent exchange of input, ideas, and results.”
The study was supported by the Irish Rugby Football Union Charitable Trust, AMBER the Research Ireland Centre for Advanced Materials and BioEngineering Research and an Irish Research Council Government of Ireland Postdoctoral Fellowship.
For more information, contact Prof. Fergal O’Brien at
