A Parylene Neural Probe Array for Multi-Region Deep Brain Recordings

• Published in: Journal of microelectromechanical systems Vol. 29; no. 4; pp. 499 - 513
• Main Authors: Wang, Xuechun, Hirschberg, Ahuva Weltman, Xu, Huijing, Slingsby-Smith, Zachary, Lecomte, Aziliz, Scholten, Kee, Song, Dong, Meng, Ellis
• Format: Journal Article
• Language: English
• Published: United States IEEE 01.08.2020; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Arrays; Biodegradability; Brain; Brain-computer interfaces; chronic recording; Electrodes; flexible brain probe; Force; Hippocampus; Implantation; Mechanical properties; Micromachining; multielectrode array; Parylene C; Polymer films; Polymers; Probes; Rats; Recording; Stiffness; Surgical implants; Thin films; Brain-computer interfaces; chronic recording; multielectrode array; Parylene C; flexible brain probe
• ISSN: 1057-7157; 1941-0158
• DOI: 10.1109/JMEMS.2020.3000235

A Parylene C polymer neural probe array with 64 electrodes purposefully positioned across 8 individual shanks to anatomically match specific regions of the hippocampus was designed, fabricated, characterized, and implemented in vivo for enabling recording in deep brain regions in freely moving rats. Thin film polymer arrays were fabricated using surface micromachining techniques and mechanically braced to prevent buckling during surgical implantation. Importantly, the mechanical bracing technique developed in this work involves a novel biodegradable polymer brace that temporarily reduces shank length and consequently, increases its stiffness during implantation, therefore enabling access to deeper brain regions while preserving a low original cross-sectional area of the shanks. The resulting mechanical properties of braced shanks were evaluated at the benchtop. Arrays were then implemented in vivo in freely moving rats, achieving both acute and chronic recordings from the pyramidal cells in the cornu ammonis (CA) 1 and CA3 regions of the hippocampus which are responsible for memory encoding. This work demonstrated the potential for minimally invasive polymer-based neural probe arrays for multi-region recording in deep brain structures. [2020-0018]