一种新颖、低成本、多功能的脊髓刺激柔性多电极阵列制造方法

F. Shanehsazzadeh, Shahin Rouhi, Tala Ahmadvand, Mahrokh Namazi, S. Kiani, M. Fardmanesh
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引用次数: 2

摘要

本文提出了一种新颖、低成本的多电极阵列制造方法,用于硬膜外脊髓刺激(ESCS)以恢复脊髓损伤(SCI)瘫痪后的运动能力。在这种方法中,与现有的神经假体技术不同,消除了昂贵的标准微加工工艺。这使得所提出的电极具有成本效益,适合临床应用的大规模生产。基于电极与脊髓组织的顺应性和力学顺应性,提出了基于全聚二甲基硅氧烷(PDMS)的无源多电极阵列结构。所提出的神经电极阵列结构由PDMS(衬底)和嵌入100 μm厚的铜导线(导电部分)组成。尽管PDMS的杨氏模量低给制造和实施带来了挑战,但其接近脊髓组织的合适机械性能使PDMS成为最佳选择之一。这些电极与脉冲发生器电路一起使用,为两个通道提供双相脉冲波形。采用ESCS系统可使成年雄性Wistar大鼠瘫痪肢体运动。我们的初步ESCS研究表明,这种电极阵列能够有效地刺激神经元。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Novel, Low Cost and Versatile Fabrication Method of Flexible Multi-electrode Array for Spinal Cord Stimulation
In this paper, a novel, low-cost multi-electrode array fabrication method has been proposed for epidural spinal cord stimulation (ESCS) to restore motion ability after paralysis due to spinal cord injury (SCI). In this approach, unlike the existing neural prosthesis technologies, costly standard microfabrication processes are eliminated. This makes the proposed electrodes cost-effective and suitable for massive production for clinical applications. Based on the conformability and mechanical compliance of the electrodes and spinal cord tissue, full polydimethylsiloxane (PDMS)-based passive multi-electrode array structure is proposed. The suggested neural electrode array structure consists of PDMS (as substrate) and embedded 100 μm-thick Cu wires (as conductive parts). Despite the fabrication and implementation challenges caused by the low Young modulus of PDMS, its suitable mechanical properties close to those of the spinal cord tissues make PDMS one of the best options. These electrodes were used along with pulse generator circuits providing biphasic pulse waveforms for two channels. Employing the ESCS system caused movement in the paralyzed limbs in an adult male Wistar rat. Our preliminary ESCS studies have shown that such electrode arrays are capable of neuronal stimulation effectively.
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