Department of Bioengineering, University of Utah, Salt Lake City, UT, USA.
J Neural Eng. 2013 Aug;10(4):045003. doi: 10.1088/1741-2560/10/4/045003. Epub 2013 May 31.
Among the currently available neural interface devices, there has been a need for a penetrating electrode array with a high electrode-count and high electrode-density (the number of electrodes/mm(2)) that can be used for electrophysiological studies of sub-millimeter neuroanatomical structures. We have developed such a penetrating microelectrode array with both a high electrode-density (25 electrodes/mm(2)) and high electrode-count (up to 96 electrodes) for small nervous system structures, based on the existing Utah Slanted Electrode Array (USEA). Such high electrode-density arrays are expected to provide greater access to nerve fibers than the conventionally spaced USEA especially in small diameter nerves.
One concern for such high density microelectrode arrays is that they may cause a nerve crush-type injury upon implantation. We evaluated this possibility during acute (<10 h) in vivo experiments with electrode arrays implanted into small diameter peripheral nerves of anesthetized rats (sciatic nerve) and cats (pudendal nerve).
Successful intrafascicular implantation and viable nerve function was demonstrated via microstimulation, single-unit recordings and histological analysis. Measurements of the electrode impedances and quantified electrode dimensions demonstrated fabrication quality. The results of these experiments show that such high density neural interfaces can be implanted acutely into neural tissue without causing a complete nerve crush injury, while mediating intrafascicular access to fibers in small diameter peripheral nerves.
This new penetrating microelectrode array has characteristics un-matched by other neural interface devices currently available for peripheral nervous system neurophysiological research.
在现有的神经接口设备中,需要一种具有高电极计数和高密度(每平方毫米电极数量)的穿透式电极阵列,可用于亚毫米级神经解剖结构的电生理研究。我们基于现有的犹他斜电极阵列(USEA),开发了一种具有高密度(25 个电极/平方毫米)和高电极计数(最多 96 个电极)的穿透式微电极阵列,用于小型神经系统结构。这种高密度电极阵列有望比传统间隔的 USEA 提供更多接近神经纤维的机会,尤其是在小直径神经中。
对于这种高密度微电极阵列,一个令人关注的问题是它们在植入时可能会导致神经挤压损伤。我们在急性(<10 小时)体内实验中评估了这种可能性,将电极阵列植入麻醉大鼠(坐骨神经)和猫(阴部神经)的小直径周围神经中。
通过微刺激、单细胞记录和组织学分析,证明了成功的神经内植入和神经功能的存活。电极阻抗的测量和量化的电极尺寸表明了制造质量。这些实验的结果表明,这种高密度神经接口可以在不造成完全神经挤压损伤的情况下,急性植入神经组织,同时介导小直径周围神经纤维的神经内接入。
这种新的穿透式微电极阵列具有其他目前可用于周围神经系统神经生理研究的神经接口设备无法匹配的特性。
