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神经和胶质限制性前体细胞的联合疗法以及慢性喹哌嗪治疗与被动循环相结合,可促进成年脊髓损伤大鼠出现喹哌嗪诱导的踏步行为。

A combination therapy of neural and glial restricted precursor cells and chronic quipazine treatment paired with passive cycling promotes quipazine-induced stepping in adult spinalized rats.

作者信息

Dugan Elizabeth A, Shumsky Jed S

出版信息

J Spinal Cord Med. 2015 Nov;38(6):792-804. doi: 10.1179/2045772314Y.0000000274. Epub 2014 Oct 20.

DOI:10.1179/2045772314Y.0000000274
PMID:25329574
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4725813/
Abstract

INTRODUCTION

In order to develop optimal treatments to promote recovery from complete spinal cord injury (SCI), we examined the combination of: (1) a cellular graft of neural and glial restricted precursor (NRP/GRP) cells, (2) passive exercise, and (3) chronic quipazine treatment on behavioral outcomes and compared them with the individual treatment elements. NRP/GRP cells were transplanted at the time of spinalization.

METHODS

Daily passive exercise began 1 week after injury to give sufficient time for the animals to recover. Chronic quipazine administration began 2 weeks after spinalization to allow for sufficient receptor upregulation permitting the expression of its behavioral effects. Behavioral measures consisted of the Basso, Beattie, and Bresnahan (BBB) locomotor score and percent of weight-supported steps and hops on a treadmill.

RESULTS

Rats displayed an increased response to quipazine (BBB ≥ 9) beginning at 8 weeks post-injury in all the animals that received the combination therapy. This increase in BBB score was persistent through the end of the study (12 weeks post-injury).

CONCLUSION

Unlike the individual treatment groups which never achieved weight support, the combination therapy animals were able to perform uncoordinated weight-supported stepping without a body weight support system while on a moving treadmill (6.5 m per minute) and were capable of supporting their own weight in stance during open field locomotion testing. No regeneration of descending serotonergic projections into and through the lesion cavity was observed. Furthermore, these results are a testament to the capacity of the lumbar spinal cord, when properly stimulated, to sustain functioning locomotor circuitry following complete SCI.

摘要

引言

为了开发促进完全性脊髓损伤(SCI)恢复的最佳治疗方法,我们研究了以下几种方法的组合:(1)神经和胶质限制性前体细胞(NRP/GRP)的细胞移植;(2)被动运动;(3)长期使用喹哌嗪治疗对行为结果的影响,并将其与各个治疗因素进行比较。在脊髓损伤时移植NRP/GRP细胞。

方法

损伤后1周开始每日进行被动运动,以便给动物足够的时间恢复。脊髓损伤后2周开始长期给予喹哌嗪,以允许足够的受体上调,从而使其行为效应得以表达。行为测量包括Basso、Beattie和Bresnahan(BBB)运动评分以及在跑步机上体重支撑步和跳跃的百分比。

结果

在接受联合治疗的所有动物中,损伤后8周开始,大鼠对喹哌嗪的反应增强(BBB≥9)。这种BBB评分的增加在研究结束时(损伤后12周)持续存在。

结论

与从未实现体重支撑的个体治疗组不同,联合治疗的动物在移动的跑步机(每分钟6.5米)上能够在没有体重支撑系统的情况下进行不协调的体重支撑步,并且在旷场运动测试中能够在站立时支撑自身重量。未观察到下行5-羟色胺能投射进入并穿过损伤腔的再生。此外,这些结果证明了腰段脊髓在受到适当刺激时,在完全性脊髓损伤后维持运动回路功能的能力。

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