使用锰增强磁共振成像对损伤大鼠脊髓中的皮质脊髓束连接性进行成像。

Imaging corticospinal tract connectivity in injured rat spinal cord using manganese-enhanced MRI.

作者信息

Bilgen Mehmet

机构信息

High Field MRI Research Laboratory, The University of Kansas Medical Center, 3901 Rainbow Blvd, Kansas City, KS 66160, USA.

出版信息

BMC Med Imaging. 2006 Nov 17;6:15. doi: 10.1186/1471-2342-6-15.

DOI:10.1186/1471-2342-6-15

PMID:17112375

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1660558/

Abstract

BACKGROUND

Manganese-enhanced MRI (MEI) offers a novel neuroimaging modality to trace corticospinal tract (CST) in live animals. This paper expands this capability further and tests the utility of MEI to image axonal fiber connectivity in CST of injured spinal cord (SC).

METHODS

A rat was injured at the thoracic T4 level of the SC. The CST was labeled with manganese (Mn) injected intracortically at two weeks post injury. Next day, the injured SC was imaged using MEI and diffusion tensor imaging (DTI) modalities.

RESULTS

In vivo MEI data obtained from cervical SC confirmed that CST was successfully labeled with Mn. Ex vivo MEI data obtained from excised SC depicted Mn labeling of the CST in SC sections caudal to the lesion, which meant that Mn was transported through the injury, possibly mediated by viable CST fibers present at the injury site. Examining the ex vivo data from the injury epicenter closely revealed a thin strip of signal enhancement located ventrally between the dorsal horns. This enhancement was presumably associated with the Mn accumulation in these intact fibers projecting caudally as part of the CST. Additional measurements with DTI supported this view.

CONCLUSION

Combining these preliminary results collectively demonstrated the feasibility of imaging fiber connectivity in experimentally injured SC using MEI. This approach may play important role in future investigations aimed at understanding the neuroplasticity in experimental SCI research.

摘要

背景

锰增强磁共振成像（MEI）为在活体动物中追踪皮质脊髓束（CST）提供了一种新型神经成像方式。本文进一步拓展了这一能力，并测试了MEI对损伤脊髓（SC）的CST中轴突纤维连接进行成像的效用。

方法

一只大鼠在脊髓胸段T4水平受伤。在损伤后两周通过皮质内注射锰（Mn）标记CST。次日，使用MEI和扩散张量成像（DTI）方式对损伤的脊髓进行成像。

结果

从颈段脊髓获得的活体MEI数据证实CST成功用Mn标记。从切除的脊髓获得的离体MEI数据显示在损伤部位尾侧的脊髓切片中CST有Mn标记，这意味着Mn穿过损伤部位进行了转运，可能是由损伤部位存在的存活CST纤维介导的。仔细检查损伤中心的离体数据发现，在背角之间腹侧有一条细的信号增强带。这种增强可能与作为CST一部分向尾侧投射的这些完整纤维中的Mn积累有关。DTI的额外测量结果支持了这一观点。

结论

综合这些初步结果共同证明了使用MEI对实验性损伤脊髓中的纤维连接进行成像的可行性。这种方法可能在未来旨在理解实验性脊髓损伤研究中神经可塑性的研究中发挥重要作用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/56e6/1660558/871b2570a925/1471-2342-6-15-1.jpg

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使用锰增强磁共振成像对损伤大鼠脊髓中的皮质脊髓束连接性进行成像。

Imaging corticospinal tract connectivity in injured rat spinal cord using manganese-enhanced MRI.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSION

背景

方法

结果

结论

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