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Image: Rice University neuroengineers and colleagues at the University of Texas Medical Branch at Galveston and the University of Texas Health Sciences Center at Houston publish first proof-of-concept results: A wireless neurostimulator can treat chronic pain and neurological diseases
Source: Josh Chen/Rice University
An implant slightly larger than a grain of rice could replace a much larger device that stimulates nerves
Engineers at Rice University, in collaboration with multiple institutions at Texas Medical Center, released the first proof-of-concept results
The magnetoelectric bioimplant, also known as ME-BIT, is surgically implanted, with electrodes sent into blood vessels and directed at nerves for stimulation
The research team successfully tested its technique in an animal model and found that it could be charged, with some implants that communicate just a few centimeters under the skin
The implant, detailed in Nature Biomedical Engineering, could potentially replace current, more invasive devices for treating Parkinson's disease, epilepsy, chronic pain, hearing loss and paralysis
"Because these devices are so small, we can use blood vessels as a highway system, achieving goals that are difficult to achieve with traditional surgery," Robinson said
The ability to power implants with magnetoelectric materials eliminates the need for electrical leads through the skin and other tissues
ME-BIT's wearable charger requires no surgery
The programmable, 0.
The researchers say the transmitter produces a magnetic field of about 1 milliTesla, which is easily accepted by tissues
"One of the benefits is that all the nerves in our body need oxygen and nutrients, so that means there's a blood vessel within a few hundred micrometers of all the nerves," Robinson said
"Combining imaging and dissection, we can be fairly confident about where to place the electrodes," he said
This study suggests that intravascular bioelectronics like ME-BIT could lead to a range of low-risk, high-precision treatments
Ultimately, the team hopes to take multiple implants and communicate with them simultaneously, Robinson said
article title
A wireless millimetric magnetoelectric implant for the endovascular stimulation of peripheral nerves
