Microneedle Penetrating Array with Axon-Sized Dimensions for Cuff-less Peripheral Nerve Interfacing

2019 9th International IEEE/EMBS Conference on Neural Engineering (NER) Pub Date : 2019-03-20 DOI:10.1109/NER.2019.8717097

Dongxiao Yan, Ahmad A. Jiman, David C. Ratze, Shuo Huang, Saman Parizi, Elissa J. Welle, Zhonghua Ouyang, Paras R. Patel, M. Kushner, C. Chestek, T. Bruns, E. Yoon, J. Seymour

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引用次数: 7

Abstract

Autonomic nerves are typically only hundreds of microns in diameter near their organ targets and these carry all of the sympathetic and parasympathetic control signals. We present a cuff-less microneedle array specifically designed to potentially map small autonomic nerves. The focus of this paper is the design and fabrication of an ultra-miniaturized silicon needle array on a silicone substrate. We demonstrate arrays having 25 to 100 microneedles. Each needle has a 1-micron tip and dual-taper shaft. We demonstrate an ability to control the tip shape, angle, and shaft angle which is important for balancing sharpness and stiffness. These high-density arrays also include a special backside anchor embedded in silicone for stability in the elastic substrate, yet the array freely wraps over a 300-µm nerve. Another critical method presented here is a surgical technique for inserting and securing an array without a cuff (as small as 0.3 mm wide and 1.2 mm long) by photochemical bonding of collagen/Rose Bengal adhesive agents to epineurium. Future work will focus on device functionalization and histological characterization in a rat vagus model.

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无袖带外周神经接口的轴突尺寸微针穿透阵列

自主神经在目标器官附近的直径通常只有几百微米，它们携带所有的交感神经和副交感神经控制信号。我们提出了一种专门设计用于绘制小自主神经的无袖微针阵列。本文的重点是在硅基上设计和制造一种超小型化的硅针阵列。我们演示了包含25到100个微针的阵列。每个针有一个1微米的尖端和双锥度轴。我们展示了控制尖端形状、角度和轴角的能力，这对平衡锐度和刚度很重要。这些高密度阵列还包括一个嵌入硅树脂的特殊后锚，用于在弹性衬底中保持稳定性，但该阵列可以自由包裹超过300微米的神经。本文提出的另一种关键方法是通过将胶原/玫瑰孟加拉胶粘剂光化学结合到神经外膜上，在没有袖带的情况下插入和固定阵列的手术技术(小至0.3 mm宽，1.2 mm长)。未来的工作将集中在大鼠迷走神经模型的装置功能和组织学表征上。

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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2019 9th International IEEE/EMBS Conference on Neural Engineering (NER)

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