Researchers at Cornell University, in collaboration with other institutions, have successfully created an incredibly small neural implant. This device, no bigger than a grain of salt, has demonstrated the ability to wirelessly transmit brain activity data from living animals for more than a year.
This groundbreaking advancement, detailed in Nature Electronics, highlights the impressive potential of microelectronic systems operating at an exceptionally tiny scale. The innovation could unlock new possibilities for brain monitoring, integrated biosensors, and various other medical and technological applications.
Introducing the MOTE Device
Known as a microscale optoelectronic tetherless electrode, or MOTE, the device’s development was spearheaded by Alyosha Molnar, a professor in Electrical and Computer Engineering at Cornell, alongside Sunwoo Lee, an assistant professor at Nanyang Technological University. Lee initiated work on this technology during his postdoctoral research period in Molnar’s laboratory.
How the Implant Transmits Brain Signals Using Light
The MOTE operates by utilizing red and infrared laser beams, which are capable of safely passing through brain tissue. It communicates data by emitting minute pulses of infrared light, which effectively encode the electrical signals originating from the brain.
At the core of the MOTE device is a semiconductor diode crafted from aluminum gallium arsenide. This crucial component serves a dual purpose: it captures incoming light to power the system and also emits light to facilitate data transmission. Furthermore, the implant integrates a low-noise amplifier and an optical encoder, both constructed using the same type of semiconductor technology prevalent in everyday microchips.
The implant itself measures approximately 300 microns in length and 70 microns in width, making it exceptionally compact.
“As far as we know, this represents the smallest neural implant capable of both measuring electrical activity in the brain and reporting it wirelessly,” commented Molnar. “By employing pulse position modulation for the communication code — identical to the code used in optical communications for satellites, for instance — we can utilize minimal power for communication while still successfully retrieving the optical data.”
Future Prospects for Brain and Body Monitoring
Molnar suggested that the specific materials used in the MOTE could potentially enable researchers to record brain activity during MRI scans, a feat largely unachievable with current implant technologies. This innovative technology might also be adapted for use in other parts of the body, including the spinal cord, and could eventually be combined with future advancements such as opto-electronics embedded within artificial skull plates.