非系绳小鼠神经刺激的自跟踪能量转移

arXiv: Neurons and Cognition Pub Date : 2015-03-04 DOI:10.1103/PhysRevApplied.4.024001

J. S. Ho, Y. Tanabe, S. Iyer, A. Christensen, L. Grosenick, K. Deisseroth, S. Delp, A. Poon

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引用次数: 37

摘要

在小鼠自然行为过程中对神经回路进行光或电刺激是研究脑功能的一个重要范例。传统的光遗传学和电微刺激系统需要绳索或大型头戴式设备来干扰动物的行为。我们报告了一种小型植入设备无线供电的方法，该方法基于在小鼠射频腔和固有模式之间的共振相互作用期间发生的强能量定位。该系统的特点是在一个宽(直径16厘米)的操作区域内进行自我跟踪，并用于演示使用完全植入皮肤下的小型化刺激器(10毫米$^{3}$，20毫克)对皮质神经元的无线激活。

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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Self-tracking Energy Transfer for Neural Stimulation in Untethered Mice

Optical or electrical stimulation of neural circuits in mice during natural behavior is an important paradigm for studying brain function. Conventional systems for optogenetics and electrical microstimulation require tethers or large head-mounted devices that disrupt animal behavior. We report a method for wireless powering of small-scale implanted devices based on the strong localization of energy that occurs during resonant interaction between a radio-frequency cavity and intrinsic modes in mice. The system features self-tracking over a wide (16 cm diameter) operational area, and is used to demonstrate wireless activation of cortical neurons with miniaturized stimulators (10 mm$^{3}$, 20 mg) fully implanted under the skin.

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arXiv: Neurons and Cognition

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