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大鼠脊髓损伤后前肢功能训练可塑性变化的可能发生机制

Possible mechanisms of enhanced plasticity by forelimb training after spinal cord injury in rats
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摘要 目的:探讨大鼠脊髓损伤(SCI)后前肢功能训练引起可塑性变化的可能机制。方法:在立体定位仪的引导下,致伤大鼠双侧红核和皮质脊髓背侧束(dCST)后,对大鼠行前肢功能训练6周。生物素化葡聚糖胺示踪皮质脊髓腹侧束(vCST)的出芽情况,免疫组化检测CST投射神经元(CSNs)生长相关蛋白_(43)(GAP_(43))和神经营养素共同受体P75(P75^(NTR))的表达,荧光金逆行示踪CSNs存活情况。结果:大鼠SCI后,前肢功能训练可诱导vCST出芽增加,上调CSNs GAP43和P75^(NTR)的表达,减少CSNs死亡。结论:大鼠CSI后,前肢功能训练增强可塑性变化的可能机制包括上调CSNs GAP43和P75^(NTR)的表达,减少CSNs死亡的发生。 Objective:To explore the possible mechanisms of enhanced plasticity by forelimb training after spinal cord injury(SCI)in rats.Methods:Stereotaxieally,red nuclei and cervical dorsal corticospinal tract(dCST)were in- jured.Then rats accepted forelimb training for successive 6 weeks.Biotin Dextran Amine was employed to trace the sprouting of ventral eorticospinal traet(vCST).The expression of growth-associated protein(GAP_(43))and P75^(NTR) in eorticospinal neurons(CSNs)was evaluated by immunocytochemistry,and the survival of CNAs was vis- ualized by Fluord-Gold.Results:Forelimb training could enhance the sprouting of uninjured vCST,and could up regulate the expression of GAP_(43) and P75^(NTR) in CSNs.Also,it could reduce the death of CSNs.Conclusions:The possible mechanisms of enhanced plasticity by forelimb training after SCI in rats might include.(i)to up-regulate the expression of certain genes needed to enhance the CSNs potential for plasticity,such as GAP_(43) and P75^(NTR);(ii) to rescue CSNs from axotomy-induced death.
作者 宗兆文 廖维宏
机构地区 重庆第三军医大学创伤
出处 《感染.炎症.修复》 2005年第1期11-13,65,共4页 Infection Inflammation Repair
关键词 脊髓损伤 可塑性 训练 生长相关蛋白43 神经营养素共同受体P75 Spinal cord injury Plasticity Training GAP_(43) P75^(NTR)
分类号 R65 [医药卫生—外科学]
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感染.炎症.修复
2005年 第1期

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