Stability of sputtered iridium oxide neural microelectrodes under kilohertz frequency pulsed stimulation.

Journal of neural engineering Pub Date : 2024-11-18 DOI:10.1088/1741-2552/ad9404

Jimin Maeng, Rebecca Anne Frederick, Behnoush Dousti, Ifra Ilyas Ansari, Alexandra Joshi-Imre, Stuart Cogan, Felix Deku

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Abstract

Objective: Kilohertz (kHz) frequency stimulation has gained attention as a neuromodulation therapy in spinal cord and in peripheral nerve block applications, mainly for treating chronic pain. Yet, few studies have investigated the effects of high-frequency stimulation on the performance of the electrode materials. In this work, we assess the electrochemical characteristics and stability of sputtered iridium oxide film (SIROF) microelectrodes under kHz frequency pulsed electrical stimulation.

Approach: SIROF microelectrodes were subjected to 1.5-10 kHz pulsing at charge densities of 250-1000 µC cm^-2(25-100 nC phase^-1), under monopolar and bipolar configurations, in buffered saline solution. The electrochemical behavior as well as the long-term stability of the pulsed electrodes was evaluated by voltage transient, cyclic voltammetry, and electrochemical impedance spectroscopy measurements.

Main results: Electrode polarization was more pronounced at higher stimulation frequencies in both monopolar and bipolar configurations. Bipolar stimulation resulted in an overall higher level of polarization than monopolar stimulation with the same parameters. In all tested pulsing conditions, except one, the maximum cathodal and anodal potential excursions stayed within the water window of iridium oxide (-0.6 to 0.8 V vs Ag|AgCl). Additionally, these SIROF microelectrodes showed little or no changes in the electrochemical performance under continuous current pulsing at frequencies up to 10 kHz for more than 10⁹pulses.

Significance: Our results suggest that 10,000 μm²SIROF microelectrodes can deliver high-frequency neural stimulation up to 10 kHz in buffered saline at charge densities between 250 and 1000 µC cm^-2(25-100 nC phase^-1).

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溅射氧化铱神经微电极在千赫兹频率脉冲刺激下的稳定性。

目的：千赫兹（kHz）频率刺激作为脊髓和周围神经阻滞应用中的一种神经调控疗法，主要用于治疗慢性疼痛，已受到越来越多的关注。然而，很少有研究调查高频刺激对电极材料性能的影响。在这项工作中，我们评估了溅射氧化铱膜（SIROF）微电极在千赫兹频率脉冲电刺激下的电化学特性和稳定性：方法：在缓冲生理盐水溶液中，以单极和双极配置对 SIROF 微电极进行 1.5-10 kHz 脉冲刺激，电荷密度为 250-1000 µC cm-2（25-100 nC 相-1）。通过瞬态电压、循环伏安法和电化学阻抗谱测量，对脉冲电极的电化学行为和长期稳定性进行了评估：主要结果：在单极和双极配置中，刺激频率越高，电极极化越明显。在参数相同的情况下，双极刺激的极化水平总体高于单极刺激。在所有测试的脉冲条件下，除一种情况外，阴极和阳极电位的最大偏移都保持在氧化铱的水窗范围内（-0.6 至 0.8 V 对 Ag|AgCl）。此外，这些 SIROF 微电极在频率高达 10 kHz、超过 109 脉冲的连续电流脉冲下的电化学性能几乎没有变化：我们的研究结果表明，10,000 μm2SIROF 微电极可在缓冲盐水中以 250 至 1000 µC cm-2（25-100 nC 相-1）的电荷密度提供高达 10 kHz 的高频神经刺激。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of neural engineering

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