Improving Deep Brain Stimulation Electrode Performance in vivo Through Use of Conductive Hydrogel Coatings.

Tomoko Hyakumura,Wenlu Duan,Wendy K Adams,Joel Villalobos,Ulises Aregueta-Robles,James B Fallon,Laura Poole-Warren

doi:10.3389/fnins.2021.761525

Tomoko Hyakumura, Wenlu Duan + Show 5 more

Open Access

https://doi.org/10.3389/fnins.2021.761525

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Abstract

Active implantable neurological devices like deep brain stimulators have been used over the past few decades to treat movement disorders such as those in people with Parkinson’s disease and more recently, in psychiatric conditions like obsessive compulsive disorder. Electrode-tissue interfaces that support safe and effective targeting of specific brain regions are critical to success of these devices. Development of directional electrodes that activate smaller volumes of brain tissue requires electrodes to operate safely with higher charge densities. Coatings such as conductive hydrogels (CHs) provide lower impedances and higher charge injection limits (CILs) than standard platinum electrodes and support safer application of smaller electrode sizes. The aim of this study was to examine the chronic in vivo performance of a new low swelling CH coating that supports higher safe charge densities than traditional platinum electrodes. A range of hydrogel blends were engineered and their swelling and electrical performance compared. Electrochemical performance and stability of high and low swelling formulations were compared during insertion into a model brain in vitro and the formulation with lower swelling characteristics was chosen for the in vivo study. CH-coated or uncoated Pt electrode arrays were implanted into the brains of 14 rats, and their electrochemical performance was tested weekly for 8 weeks. Tissue response and neural survival was assessed histologically following electrode array removal. CH coating resulted in significantly lower voltage transient impedance, higher CIL, lower electrochemical impedance spectroscopy, and higher charge storage capacity compared to uncoated Pt electrodes in vivo, and this advantage was maintained over the 8-week implantation. There was no significant difference in evoked potential thresholds, signal-to-noise ratio, tissue response or neural survival between CH-coated and uncoated Pt groups. The significant electrochemical advantage and stability of CH coating in the brain supports the suitability of this coating technology for future development of smaller, higher fidelity electrode arrays with higher charge density requirement.

Highlights

Deep brain stimulation (DBS) uses electrodes inserted into specific regions of the brain to deliver therapeutic electrical stimulation, such as those targeting the subthalamic nucleus (STN) in treating Parkinson’s disease
This study showed that conductive hydrogels (CHs) coatings tailored with low swelling properties improve the electrochemical performance of smooth Pt electrodes in the brain without causing significant alterations in neural stimulation/recording functions of the electrodes, or in the tissue response or neural survival at the electrode-tissue interface
We found CH-coated electrodes showed significantly lower voltage transient (VT) impedance and Electrochemical impedance spectroscopy (EIS), and higher charge injection limits (CILs) and charge storage capacity (CSC) compared with uncoated smooth Pt electrodes in the rat brain, and these changes were maintained for the entire 8-week duration of the study

Summary

Introduction

Deep brain stimulation (DBS) uses electrodes inserted into specific regions of the brain to deliver therapeutic electrical stimulation, such as those targeting the subthalamic nucleus (STN) in treating Parkinson’s disease. Contemporary DBS devices utilise large ring electrodes of approximately 1.3 mm diameter (6 mm surface area) that can result in a significant risk of damage to brain tissue during insertion (Ory-Magne et al, 2007; Boviatsis et al, 2010; Morishita et al, 2013). Undesirable off-target activation due to spread of stimulation from large electrodes can be an issue (Anderson et al, 2019; Nguyen et al, 2019). Decreasing electrode size for higher fidelity recording and stimulation results in higher charge densities which can impact on device performance

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