CLARITY 成像的简化方法。

Simplified method to perform CLARITY imaging.

机构信息

Department of Medical Physics, St,Petersburg State Polytechnical University, St Petersburg 195251, Russia.

出版信息

Mol Neurodegener. 2014 May 26;9:19. doi: 10.1186/1750-1326-9-19.

DOI:10.1186/1750-1326-9-19

PMID:24885504

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4049387/

Abstract

BACKGROUND

Imaging methods are used widely to understand structure of brain and other biological objects. However, sample penetration by light microscopy is limited due to light scattering by the tissue. A number of methods have been recently developed to solve this problem. In one approach (SeeDB) simple procedure for clarifying brain samples for imaging was described. However, this method is not compatible with immunostaining approach as SeeDB-prepared tissue is not permeable to the antibodies. Another technique for clearing brain tissue (CLARITY) was optimized for immunochemistry, but this method technically much more demanding than SeeDB.

RESULTS

Here we report optimized protocol for imaging of brain samples (CLARITY2). We have simplified and shortened the original protocol. Following hydrogel fixation, we cut brain tissue to 1-1.5 mm thick coronal slices. This additional step enabled us to accelerate and simplify clearing, staining and imaging steps when compared to the original protocol. We validated the modified protocol in imaging experiments with brains from line M Thy1-GFP mouse and in immunostaining experiments with antibodies against postsynaptic protein PSD-95 and striatal-specific protein DARPP32.

CONCLUSIONS

The original CLARITY protocol was optimized and simplified. Application of the modified CLARITY2 protocol could be useful for a broad range of scientists working in neurobiology and developmental biology.

摘要

背景

成像方法被广泛用于了解大脑和其他生物物体的结构。然而，由于组织的光散射，光显微镜的样本穿透受到限制。最近已经开发了许多方法来解决这个问题。在一种方法（SeeDB）中，描述了一种简单的澄清大脑样本进行成像的程序。然而，这种方法与免疫染色方法不兼容，因为 SeeDB 处理的组织对抗体不可渗透。另一种用于清除脑组织的技术（CLARITY）经过了免疫化学的优化，但这种方法在技术上比 SeeDB 要求更高。

结果

在这里，我们报告了优化的大脑样本成像方案（CLARITY2）。我们简化并缩短了原始方案。在水凝胶固定后，我们将脑组织切成 1-1.5 毫米厚的冠状切片。与原始方案相比，这一额外步骤使我们能够加速和简化清除、染色和成像步骤。我们在来自线 M Thy1-GFP 小鼠的大脑的成像实验和针对突触后蛋白 PSD-95 和纹状体特异性蛋白 DARPP32 的抗体的免疫染色实验中验证了改良方案。

结论

原始的 CLARITY 方案进行了优化和简化。改良的 CLARITY2 方案的应用可能对从事神经生物学和发育生物学的广泛科学家有用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dec6/4049387/4cb062b67615/1750-1326-9-19-1.jpg

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CLARITY 成像的简化方法。

Simplified method to perform CLARITY imaging.

机构信息

Department of Medical Physics, St,Petersburg State Polytechnical University, St Petersburg 195251, Russia.