This review is organized by Prof. Bowen Ji, Prof. Honglong Chang (Unmanned System Institute, Northwestern Polytechnical University), and Prof. Jingquan Liu (Department of Micro/Nano Electronics, Shanghai Jiao Tong University). An implantable brain-computer interface (BCI) has proven to be effective in the field of sensory and motor function restoration and in the treatment of neurological disorders. Using a BCI recording system, we can transform current methods of human interaction with machines and the environment, especially to help those with cognitive and mobility disabilities regain mobility and reintegrate into society. However, most reported work has focused on a simple aspect of the whole system, such as electrodes, circuits, or data transmission, and only a very small percentage of systems are wireless. “A miniature, lightweight, wireless, implantable microsystem is key to realizing long-term, real-time, and stable monitoring on freely moving animals or humans in their natural conditions,” Ji says.
Credit: ©Science China Press
This review is organized by Prof. Bowen Ji, Prof. Honglong Chang (Unmanned System Institute, Northwestern Polytechnical University), and Prof. Jingquan Liu (Department of Micro/Nano Electronics, Shanghai Jiao Tong University). An implantable brain-computer interface (BCI) has proven to be effective in the field of sensory and motor function restoration and in the treatment of neurological disorders. Using a BCI recording system, we can transform current methods of human interaction with machines and the environment, especially to help those with cognitive and mobility disabilities regain mobility and reintegrate into society. However, most reported work has focused on a simple aspect of the whole system, such as electrodes, circuits, or data transmission, and only a very small percentage of systems are wireless. “A miniature, lightweight, wireless, implantable microsystem is key to realizing long-term, real-time, and stable monitoring on freely moving animals or humans in their natural conditions,” Ji says.
Bowen Ji, together with lab director Honglong Chang, and collaborator Jingquan Liu, reviewed the latest progress in wireless epicortical and intracortical neuronal recording systems in five closely linked subsections, including recording electrodes, processing chips and controllers, wireless data transmission, power supply, and packaging. Challenges facing these systems were also summarized to create a direct path for future long-term and reliable recording systems according to existing technical shortcomings.
“The human brain has more than 80 billion neurons; however, current systems are far from sufficient to handle such a large number,” Liu says. Therefore, the development of wireless implantable neuronal recording systems still faces the following challenges: high throughput, wireless transmission, power consumption and supply, heat accumulation, minimization, and lifetime.
Overall, the wireless implantable neuronal recording system is an emerging research field with strong comprehensiveness and interdisciplinary integration. It involves micro-nano manufacturing, microelectronics, communication, energy, biomedicine, brain science, and artificial intelligence. With the development of the above technologies, wireless implantable BCI systems will become more miniaturized, integrated, and intelligent for broader applications in humans in the next decade.
See the article:
Recent advances in wireless epicortical and intracortical neuronal recording systems
https://doi.org/10.1007/s11432-021-3373-1
Journal
Science China Information Sciences
DOI
10.1007/s11432-021-3373-1
Article Publication Date
10-Mar-2022