Miniscope GRIN Lens System for Calcium Imaging of Neuronal Activity from Deep Brain Structures in Behaving Animals
Lifeng Zhang, Bo Liang, Giovanni Barbera, Sarah Hawes, Yan Zhang, Kyle Stump, Ira Baum, Yupeng Yang, Yun Li, Da-Ting Lin
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引用次数: 63
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Abstract
Visualizing neural activity from deep brain regions in freely behaving animals through miniature fluorescent microscope (miniscope) systems is becoming more important for understanding neural encoding mechanisms underlying cognitive functions. Here we present our custom-designed miniscope GRadient INdex (GRIN) lens system that enables simultaneously recording from hundreds of neurons for months. This article includes miniscope design, the surgical procedure for GRIN lens implantation, miniscope mounting on the head of a mouse, and data acquisition and analysis. First, a target brain region is labeled with virus expressing GCaMP6; second, a GRIN lens is implanted above the target brain region; third, following mouse surgical recovery, a miniscope is mounted on the head of the mouse above the GRIN lens; and finally, neural activity is recorded from the freely behaving mouse. This system can be applied to recording the same population of neurons longitudinally, enabling the elucidation of neural mechanisms underlying behavioral control. © 2018 by John Wiley & Sons, Inc.
微型GRIN透镜系统对行为动物脑深部结构的神经元活动进行钙成像
通过微型荧光显微镜系统观察自由行为动物脑深部的神经活动,对于理解认知功能背后的神经编码机制变得越来越重要。在这里,我们展示了我们定制设计的微型梯度指数(GRIN)透镜系统,可以同时记录数百个神经元长达数月。本文包括微型显微镜的设计、GRIN晶状体植入的手术步骤、微型显微镜在小鼠头上的安装以及数据采集和分析。首先,用表达GCaMP6的病毒标记靶脑区域;第二,在目标脑区上方植入GRIN透镜;第三,在小鼠手术恢复后,将微型显微镜安装在小鼠头部GRIN透镜上方;最后,记录下自由活动的老鼠的神经活动。该系统可用于纵向记录同一群神经元,从而阐明行为控制背后的神经机制。©2018 by John Wiley &儿子,Inc。
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