Kim Hyungsoo, Dingle Aaron M, Ness Jared P, Baek Dong-Hyun, Bong Jihye, Lee In-Kyu, Shulzhenko Nikita O, Zeng Weifeng, Israel Jacqueline S, Pisaniello Jane A, Millevolte Augusto X T, Park Dong-Wook, Suminski Aaron J, Jung Yei Hwan, Williams Justin C, Poore Samuel O, Ma Zhenqiang
Department of Electrical and Computer Engineering, United States.
Department of Surgery, United States.
J Neurosci Methods. 2020 Apr 15;336:108602. doi: 10.1016/j.jneumeth.2020.108602. Epub 2020 Jan 22.
A number of peripheral nerve interfaces for nerve stimulation and recording exist for the purpose of controlling neural prostheses, each with a set of advantages and disadvantages. The ultimate goal of neural prostheses is a seamless bi-directional communication between the peripheral nervous system and the prosthesis. Here, we developed an interfacing electrode array, the "cuff and sieve electrodes" (CASE), integrating microfabricated cuff and sieve electrodes to a single unit, to decrease the weaknesses faced by these electrode designs in isolation. This paper presents the design and fabrication of CASE with ex vivo and in vivo testing towards chronic application.
Electroplating on electrode sites was performed to improve electrical properties of CASE. The surface morphology and chemical compound were characterized using scanning electron microscopy and energy-dispersive spectroscopy, respectively. Electrochemical impedance spectroscopy and cyclic voltammetry were performed to evaluate the electrical properties of CASE and determine viability for in vivo applications. Terminal CASE implantations were performed in a rat sciatic transection model to test the ease of implantation and capacity to write sensory information into the biological system.
The modified platinum film resulted in reducing impedance magnitude (9.18 kΩ and 2.27 kΩ) and increasing phase angle (over 70°). CASE stimulation of the sciatic nerve at different amplitudes elicited significantly different cortical responses (p < 0.005) as demonstrated by somatosensory evoked potentials, recorded via micro-electrocorticography.
The ability to elicit cortical responses from sciatic nerve stimulation demonstrates the proof of concept for both the implantation and chronic monitoring of CASE interfaces for innovative prosthetic control.
为了控制神经假体,存在多种用于神经刺激和记录的外周神经接口,每种接口都有一系列优缺点。神经假体的最终目标是实现外周神经系统与假体之间无缝的双向通信。在此,我们开发了一种接口电极阵列,即“袖带和筛状电极”(CASE),它将微加工的袖带电极和筛状电极集成到一个单元中,以减少这些电极设计单独使用时所面临的弱点。本文介绍了CASE的设计与制造,并进行了体外和体内测试以用于长期应用。
在电极部位进行电镀以改善CASE的电学性能。分别使用扫描电子显微镜和能谱仪对表面形态和化合物进行表征。进行电化学阻抗谱和循环伏安法以评估CASE的电学性能并确定其体内应用的可行性。在大鼠坐骨神经横断模型中进行CASE终端植入,以测试植入的难易程度以及将感觉信息写入生物系统的能力。
改性铂膜导致阻抗幅值降低(9.18 kΩ和2.27 kΩ)且相角增大(超过70°)。通过微皮层脑电图记录的体感诱发电位表明,以不同幅度对坐骨神经进行CASE刺激会引发明显不同的皮层反应(p < 0.005)。
坐骨神经刺激引发皮层反应的能力证明了CASE接口用于创新假肢控制的植入和长期监测的概念验证。
