Fabrication of Convex PDMS-Parylene Microstructures for Conformal Contact of Planar Micro-Electrode Array

• Published in: Polymers Vol. 11; no. 9; p. 1436
• Main Authors: Lee, Woo Ram, Im, Changkyun, Park, Hae-Yong, Seo, Jong-Mo, Kim, Jun-Min
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 02.09.2019; MDPI
• Subjects: Adhesive strength; Arrays; beta frequency band; Biocompatibility; conformal contact; Contact angle; convex microstructure; electrocorticography (ECoG); Electrodes; Entrapment; Epilepsy; Flexibility; Frequencies; Gas flow; Gold; hybrid microstructure; Insulation; micro-electrode array (MEA); Microelectrodes; Molding (process); molding fabrication process; Parkinson's disease; Pattern generation; Patterning; Photolithography; Plasma etching; polymer; Polymers; Protective coatings; rat olfactory bulb; respiration; Silicon wafers; Surface energy; United States > US; conformal contact; polymer; rat olfactory bulb; beta frequency band; hybrid microstructure; electrocorticography (ECoG); micro-electrode array (MEA); respiration; molding fabrication process; convex microstructure
• ISSN: 2073-4360; 2073-4360
• DOI: 10.3390/polym11091436

Polymer-based micro-electrode arrays (MEAs) are gaining attention as an essential technology to understand brain connectivity and function in the field of neuroscience. However, polymer based MEAs may have several challenges such as difficulty in performing the etching process, difficulty of micro-pattern generation through the photolithography process, weak metal adhesion due to low surface energy, and air pocket entrapment over the electrode site. In order to compensate for the challenges, this paper proposes a novel MEA fabrication process that is performed sequentially with (1) silicon mold preparation; (2) PDMS replica molding, and (3) metal patterning and parylene insulation. The MEA fabricated through this process possesses four arms with electrode sites on the convex microstructures protruding about 20 μm from the outermost layer surface. The validity of the convex microstructure implementation is demonstrated through theoretical background. The electrochemical impedance magnitude is 204.4 ± 68.1 kΩ at 1 kHz. The feasibility of the MEA with convex microstructures was confirmed by identifying the oscillation in the beta frequency band (13-30 Hz) in the electrocorticography signal of a rat olfactory bulb during respiration. These results suggest that the MEA with convex microstructures is promising for applying to various neural recording and stimulation studies.