Brain–computer interfaces: an overview of the hardware to record neural signals from the cortex

• Published in: Progress in Brain Research Vol. 175; pp. 297 - 315
• Main Authors: Stieglitz, Thomas, Rubehn, Birthe, Henle, Christian, Kisban, Sebastian, Herwik, Stanislav, Ruther, Patrick, Schuettler, Martin
• Format: Book Chapter Journal Article
• Language: English
• Published: Netherlands Elsevier Science & Technology 2009
• Subjects: Animals; Brain - physiology; brain–computer interface (BCI); Electric Stimulation Therapy - instrumentation; Electric Stimulation Therapy - methods; electrode; Electrodes, Implanted; epicortical; Humans; intracortical; MEMS; Nervous System Diseases - rehabilitation; neuroprostheses; Prostheses and Implants; User-Computer Interface; brain–computer interface (BCI); epicortical; electrode; MEMS; intracortical; neuroprostheses
• ISBN: 012374511X; 9780123745118
• ISSN: 0079-6123; 1875-7855
• DOI: 10.1016/S0079-6123(09)17521-0

Brain–computer interfaces (BCIs) record neural signals from cortical origin with the objective to control a user interface for communication purposes, a robotic artifact or artificial limb as actuator. One of the key components of such a neuroprosthetic system is the neuro–technical interface itself, the electrode array. In this chapter, different designs and manufacturing techniques will be compared and assessed with respect to scaling and assembling limitations. The overview includes electroencephalogram (EEG) electrodes and epicortical brain–machine interfaces to record local field potentials (LFPs) from the surface of the cortex as well as intracortical needle electrodes that are intended to record single-unit activity. Two exemplary complementary technologies for micromachining of polyimide-based arrays and laser manufacturing of silicone rubber are presented and discussed with respect to spatial resolution, scaling limitations, and system properties. Advanced silicon micromachining technologies have led to highly sophisticated intracortical electrode arrays for fundamental neuroscientific applications. In this chapter, major approaches from the USA and Europe will be introduced and compared concerning complexity, modularity, and reliability. An assessment of the different technological solutions comparable to a strength weaknesses opportunities, and threats (SWOT) analysis might serve as guidance to select the adequate electrode array configuration for each control paradigm and strategy to realize robust, fast, and reliable BCIs.