大鼠腹尾部神经作为长距离再生的模型。

IF 2 Q3 NEUROSCIENCES
Ivo Vanický , Juraj Blaško , Zoltán Tomori , Zuzana Michalová , Eva Székiová
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引用次数: 0

摘要

在大鼠体内,尾神经是最长的周围神经。我们认为腹尾神经(VCN)可作为研究神经损伤和长距离再生的模型。为此,我们研究了对照动物腹尾神经的解剖和形态。我们切除了 10 厘米长的 VCN,并在 10 毫米距离处采集了横向切片。对有髓鞘的轴突进行计数,并通过一系列数据来描述神经颅尾渐狭的特征。在另一组动物中,使用荧光金逆行描记法定位和量化投射轴突到 VCN 的脊髓神经元。在完全切断神经后,对远端节段组织病理学变化的时间过程进行了研究。主要目的是确定轴突解体所需的时间。随后,轴突碎屑的清除和组织元素的重新排列也被记录下来。在压迫损伤(轴突挛缩)之后,Wallerian 退化随之而来的是轴突的自发再生。我们发现,生长中的轴突会在4-8周内跨越10厘米的距离。在不同的存活期后,我们对10毫米距离处再生轴突的数量进行了计数。这些数据被用来描述存活期为4个月的轴突再生动态。本研究表明,轴突再生跨越10厘米的距离可以在小型实验动物体内进行研究和定量分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Rat ventral caudal nerve as a model for long distance regeneration

In the rat, tail nerves are the longest peripheral nerves in their body. We suggest that ventral caudal nerve (VCN) may serve as a model for studying nerve injury and long distance regeneration. For this purpose, we have studied the anatomy and morphometry of the VCN in control animals. 10 cm long segment of the VCN was removed, and transversal sections were collected at 10 mm distances. The myelinated axons were counted, and the series of data were used to characterize the craniocaudal tapering of the nerve. In a separate group of animals, retrograde tracing with Fluorogold was used to localize and quantitate the spinal neurons projecting their axons into the VCN. After complete nerve transection, the time course of histopathological changes in the distal segment was studied. The primary goal was to define the time needed for axonal disintegration. In later periods, axonal debris removal and rearrangement of tissue elements was documented. After compression injury (axonotmesis), Wallerian degeneration was followed by spontaneous regeneration of axons. We show that the growing axons will span the 10 cm distance within 4–8 weeks. After different survival periods, the numbers of regenerating axons were counted at 10 mm distances. These data were used to characterize the dynamics of axonal regeneration during 4 months’ survival period. In the present study we show that axonal regeneration across 10 cm distance can be studied and quantitatively analyzed in a small laboratory animal.

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来源期刊
IBRO Neuroscience Reports
IBRO Neuroscience Reports Neuroscience-Neuroscience (all)
CiteScore
2.80
自引率
0.00%
发文量
99
审稿时长
14 weeks
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