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Soft, Thiol‐ene/Acrylate‐Based Electrode Array for Long‐Term Recording of Intracranial EEG Signals with Improved Biocompatibility in Mice

Flóra Zsófia Fedor, Miklós Madarász, Anita Zátonyi, Ágnes Szabó, Tibor Lőrincz, Vindhya Danda, Lisa Spurgin, Connie Manz, Balázs Rózsa, Z. Fekete

2021Advanced Materials Technologies24 citationsDOIOpen Access PDF

Abstract

Abstract Thiol‐ene/acrylate, a softening polymer material, rapidly gained attention during the past few years as a substrate of intracortical probes, as soft polymers can mitigate foreign body response by reducing mechanical mismatch between the neural implant and the surrounding brain tissue. This paper presents a comprehensive analysis of a thiol‐ene/acrylate based microECoG (micro – electrocorticography, μECoG) device with 31 sputtered iridium oxide electrodes. Long‐term electrochemical measurements provide firm evidence on the reliability of the novel layer structure and the related packaging method. In vivo impedance measurements indicated stable electrode yield (over 75%), without apparent signs of delamination or material degradation over 75 days. Awake recordings of theta oscillations with signal‐to‐noise ratio between 1.04 and 5.74 over this extended period also confirmed the applicability of the device. Chronic immune response characterized by Glial Fibrillary Acidic Protein staining of astrocytes and fluorescent Nissl (NeuroTrace) staining of neurons revealed only modest foreign body reaction after 80 days of implantation. The study presents novel data that confirms the feasibility of softening polymer‐based μECoG devices as chronically implantable neural interfaces.

Topics & Concepts

Materials scienceBiomedical engineeringAcrylateElectrodeBiocompatibilityPolymerChemistryComposite materialMedicineMetallurgyPhysical chemistryMonomerNeuroscience and Neural EngineeringEEG and Brain-Computer InterfacesConducting polymers and applications
Soft, Thiol‐ene/Acrylate‐Based Electrode Array for Long‐Term Recording of Intracranial EEG Signals with Improved Biocompatibility in Mice | Litcius