用双光子显微镜在小鼠体内成像神经元结构可塑性的实验方案。

Christian Stetter, Markus Hirschberg, Bernhard Nieswandt, Ralf-Ingo Ernestus, Manfred Heckmann, Anna-Leena Sirén
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引用次数: 8

摘要

突触形成和消除的结构可塑性是记忆能力的关键组成部分,可能对脑损伤后功能恢复至关重要。在这里,我们详细描述了在小鼠中创建颅窗的两种手术技术,并展示了小鼠新皮层突触结构可塑性的长期重复体内成像过程中的关键点。方法:在麻醉状态下制备表达第5层锥体神经元黄色荧光蛋白(YFP)的转Thy1-YFP(H)小鼠,用开颅镜或薄颅窗对顶叶皮层树突棘进行活体成像。恢复期14天后,在氟烷麻醉下开始持续45-60分钟的成像。为了减少呼吸引起的运动伪像,颅骨被粘在一块固定在金属底座上的不锈钢板上。将实验动物置于多焦扫描头分光器双光子显微镜下(TriMScope, LaVision BioTec),将钛蓝宝石激光调至YFP的最佳激发波长(890 nm)。采用20× 0.95 NA的水浸物镜(Olympus),在距脑膜表面100-200 μm的成像深度上获取图像。包含感兴趣的树突片段的三维图像堆栈的二维投影被保存以供进一步分析。在最后一次成像阶段结束时,将小鼠斩首并移除大脑进行组织学分析。结果:采用开颅玻璃和薄颅窗对第5层锥体神经元树突棘进行了成功的体内重复成像。重复成像后,两种窗口技术都具有较低的光毒性。结论:体内树突棘的重复成像可以监测突触的长期结构动态。当仔细控制反复麻醉和光毒性的影响时,该方法将适用于研究脑损伤后突触结构可塑性的变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

An experimental protocol for in vivo imaging of neuronal structural plasticity with 2-photon microscopy in mice.

An experimental protocol for in vivo imaging of neuronal structural plasticity with 2-photon microscopy in mice.

An experimental protocol for in vivo imaging of neuronal structural plasticity with 2-photon microscopy in mice.

An experimental protocol for in vivo imaging of neuronal structural plasticity with 2-photon microscopy in mice.

Introduction: Structural plasticity with synapse formation and elimination is a key component of memory capacity and may be critical for functional recovery after brain injury. Here we describe in detail two surgical techniques to create a cranial window in mice and show crucial points in the procedure for long-term repeated in vivo imaging of synaptic structural plasticity in the mouse neocortex.

Methods: Transgenic Thy1-YFP(H) mice expressing yellow-fluorescent protein (YFP) in layer-5 pyramidal neurons were prepared under anesthesia for in vivo imaging of dendritic spines in the parietal cortex either with an open-skull glass or thinned skull window. After a recovery period of 14 days, imaging sessions of 45-60 min in duration were started under fluothane anesthesia. To reduce respiration-induced movement artifacts, the skull was glued to a stainless steel plate fixed to metal base. The animals were set under a two-photon microscope with multifocal scanhead splitter (TriMScope, LaVision BioTec) and the Ti-sapphire laser was tuned to the optimal excitation wavelength for YFP (890 nm). Images were acquired by using a 20×, 0.95 NA, water-immersion objective (Olympus) in imaging depth of 100-200 μm from the pial surface. Two-dimensional projections of three-dimensional image stacks containing dendritic segments of interest were saved for further analysis. At the end of the last imaging session, the mice were decapitated and the brains removed for histological analysis.

Results: Repeated in vivo imaging of dendritic spines of the layer-5 pyramidal neurons was successful using both open-skull glass and thinned skull windows. Both window techniques were associated with low phototoxicity after repeated sessions of imaging.

Conclusions: Repeated imaging of dendritic spines in vivo allows monitoring of long-term structural dynamics of synapses. When carefully controlled for influence of repeated anesthesia and phototoxicity, the method will be suitable to study changes in synaptic structural plasticity after brain injury.

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