by Christina Griffiths, Indiana University School of Medicine
A transmission electron microscope image demonstrates a magnetoelectric nanoparticle with the magnetostrictive core and piezoelectric shell (shown with broken red line) of the core-shell nanostructure. Credit: Indiana University School of Medicine
Indiana University School of Medicine researchers are developing a new, non-invasive brain stimulation technique to treat neurological disorders, including pain, traumatic brain injury (TBI), epilepsy, Parkinson’s disease, Alzheimer’s disease, and more.
“Given the increasing use of brain stimulation in human brain study and treatment of neurological diseases, this research can make a big impact on physicians and their patients,” said Xiaoming Jin, Ph.D., associate professor of anatomy, cell biology, and physiology.
When someone experiences a brain injury, nerve injury, or neurodegeneration, such as in epilepsy and TBI, there is damage to the brain which can lead to loss and damage of nerve or neurons and development of hyperexcitability that underlies some neurological disorders such as neuropathic pain and epilepsy.
“The conventional treatment is mainly to try to directly inhibit such hyperexcitability,” Jin said, “but we found the initial damage of the brain or nervous system was caused by a loss of brain tissue, which causes the nervous system to compensate for the loss of function by working harder, so we need to stimulate activity instead of inhibiting it.”
The technique, described in a newly published paper in Neurotherapeutics, uses a new type of magnetoelectric nanoparticles that can be delivered to a specific part of the brain using a magnetic field. After, a magnetic wave can be emitted to stimulate neural activity in that particular part of the brain. The method is non-invasive, good for stimulating deep brain function, and is more efficient than traditional methods of brain stimulation, without the need for genetic manipulation.
“This is the only new type of nanoparticle that allows us to effectively stimulate the brain without doing any invasive procedures,” Jin said. “We can inject the nanoparticle as a solution into the vein and then bring it to any part of the body. When you apply a magnet on the head, you can localize and deliver the nanoparticle to the targeted brain region.”
The team has been working on the technique for five years in collaboration with the University of Miami and hopes to begin studying the method in humans in the next couple of years. The study has received funding from the Defense Advanced Research Projects Agency (DARPA) of the United States Department of Defense, National Science Foundation, as well as the Indiana Clinical and Translational Sciences Institute (CTSI), which helped provide funding for a medical neuroscience graduate student, Tyler Nguyen, to participate in the research.
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