用于长期光遗传神经回路操作的植入式光纤的构建。
Construction of implantable optical fibers for long-term optogenetic manipulation of neural circuits.
机构信息
Department of Psychiatry, University of North Carolina at Chapel Hill, USA.
出版信息
Nat Protoc. 2011 Dec 8;7(1):12-23. doi: 10.1038/nprot.2011.413.
Abstract
In vivo optogenetic strategies have redefined our ability to assay how neural circuits govern behavior. Although acutely implanted optical fibers have previously been used in such studies, long-term control over neuronal activity has been largely unachievable. Here we describe a method to construct implantable optical fibers to readily manipulate neural circuit elements with minimal tissue damage or change in light output over time (weeks to months). Implanted optical fibers readily interface with in vivo electrophysiological arrays or electrochemical detection electrodes. The procedure described here, from implant construction to the start of behavioral experimentation, can be completed in approximately 2-6 weeks. Successful use of implantable optical fibers will allow for long-term control of mammalian neural circuits in vivo, which is integral to the study of the neurobiology of behavior.
摘要
在体光遗传学策略重新定义了我们检测神经回路如何控制行为的能力。尽管以前在这类研究中曾使用过急性植入的光纤,但长期控制神经元活动在很大程度上是无法实现的。在这里,我们描述了一种构建可植入光纤的方法,以便在不造成组织损伤或随时间(数周到数月)改变光输出的情况下,轻松地操纵神经回路元件。植入的光纤可轻松与体内电生理微阵列或电化学检测电极连接。从植入物的构建到行为实验的开始,这里描述的过程大约需要 2-6 周即可完成。可植入光纤的成功使用将允许对哺乳动物神经回路进行长期的体内控制,这是行为神经生物学研究的重要组成部分。
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