Relay strategies combined with axon regeneration: a promising approach to restore spinal cord injury 被引量：2

Relay strategies combined with axon regeneration: a promising approach to restore spinal cord injury

下载PDF

导出

摘要 For decades, numerous investigations have only focused on axon regeneration to restore function after traumatic spinal cord injury （SCI）, as interrupted neuronal pathways have to be reconnected for sensorimotor and autonomic recovery to occur. Experimental approaches have ranged from drug delivery and cell transplantation to genetic manipulations. Certainly, it would be an extraordinary achievement for injured axons to regenerate over long distances, to form synapses with target neurons, and to result in dramatic functional improvement. However, these efforts have been rewarded with limited success to date suggesting that axon regeneration alone may be insufficient to repair compromised functions. For decades, numerous investigations have only focused on axon regeneration to restore function after traumatic spinal cord injury （SCI）, as interrupted neuronal pathways have to be reconnected for sensorimotor and autonomic recovery to occur. Experimental approaches have ranged from drug delivery and cell transplantation to genetic manipulations. Certainly, it would be an extraordinary achievement for injured axons to regenerate over long distances, to form synapses with target neurons, and to result in dramatic functional improvement. However, these efforts have been rewarded with limited success to date suggesting that axon regeneration alone may be insufficient to repair compromised functions.

作者 Shaoping Hou

机构地区 Spinal Cord Research Center

出处《Neural Regeneration Research》 SCIE CAS CSCD 2014年第12期1177-1179,共3页 中国神经再生研究（英文版）

基金 supported by the Craig H.Neilsen Foundation(280072)

关键词 a promising approach to restore spinal cord injury NSCS SCI

分类号 R651.2 [医药卫生—外科学]

引文网络
相关文献

参考文献15

1Alilain WJ,Horn KP,Hu H,Dick TE Silver J. Functional regener-ation of respiratory pathways after spinal cord injury[J].NATURE,2011.196-200.
2Bonner JF,Connors TM,Silverman WF,Kowalski DP Lemay MA Fischer I. Grafted neural progenitors integrate and restore synaptic con-nectivity across the injured spinal cord[J].Journal of Neuroscience,2011.4675-4686.
3Courtine G,Song B,Roy RR,Zhong H Herrmann JE Ao Y Qi J Edgerton VR Sofroniew MV. Recovery of supraspinal control of stepping via indirect propriospinal relay connections after spinal cord injury[J].Nature Medicine,2008.69-74.
4Cummings BJ,Uchida N,Tamaki SJ,Salazar DL Hooshmand M Summers R Gage FH Anderson AJ. Human neural stem cells differentiate and promote locomotor recovery in spinal cord-injured mice[J].Proceedings of the National Academy of Sciences(USA),2005.14069-14074.
5Deng LX,Deng P,Ruan Y,Xu ZC Liu NK Wen X Smith GM Xu XM. A novel growth-promoting pathway formed by GDNF-overexpressing Schwann cells promotes propriospinal axonal regeneration,synapse formation,and partial recovery of function after spinal cord injury[J].Journal of Neuroscience,2013.5655-5667.
6Fyffe REW. Laminar organization of primary afferent terminations in the mammalian spinal cord[A].New York:Oxford University Press,1992.131-139.
7Hou S,Tom VJ,Graham L,Lu P Blesch A. Partial restoration of cardiovascular function by embryonic neural stem cell grafts after com-plete spinal cord transection[J].Journal of Neuroscience,2013.17138-17149.
8Houle JD,Tom VJ,Mayes D,Wagoner G Phillips N Silver J. Com-bining an autologous peripheral nervous system"bridge"and matrix modiifcation by chondroitinase allows robust,functional regeneration beyond a hemisection lesion of the adult rat spinal cord[J].Journal of Neuroscience,2006.7405-7415.
9Kuscha V,Barreiro-Iglesias A,Becker CG,Becker T. Plasticity of tyrosine hydroxylase and serotonergic systems in the regenerating spinal cord of adult zebraifsh[J].Journal of Comparative Neurology,2012.933-951.
10Lee YS,Lin CY,Jiang HH,Depaul M Lin VW Silver J. Nerve regen-eration restores supraspinal control of bladder function after complete spinal cord injury[J].Journal of Neuroscience,2013.10591-10606.

同被引文献21

1曾园山,郭畹华,黄巨恩.脊髓移植在替换缺损运动神经元中的作用[J].解剖科学进展,1996,2(2):125-127. 被引量：3
2焦新旭,冯世庆.创伤性脊髓损伤的流行病学研究进展[J].实用医学杂志,2011,27(7):1303-1305. 被引量：24
3徐委,程黎明.神经营养因子修复脊髓损伤的研究与应用[J].中国组织工程研究,2013,17(2):369-374. 被引量：13
4吴周睿,朱元贵,程黎明,孙毅,戴建武,曹河圻,董尔丹.脊髓损伤与修复的关键科学问题——第81期“双清论坛”综述[J].中国科学基金,2013,27(3):147-153. 被引量：16
5李晓光,孙毅,杨朝阳.NT3-壳聚糖支架诱导内源性神经发生修复脊髓损伤[J].前沿科学,2016,10(1):4-10. 被引量：3
6戴建武.引导组织再生智能生物材料的转化研究[J].生命科学,2016,28(8):907-914. 被引量：4
7段红梅,宋伟,赵文,高钰丹,杨朝阳,李晓光.成年哺乳类脊髓损伤后的内源性神经发生[J].中国科学：生命科学,2016,46(12):1382-1387. 被引量：2
8Assinck P,Duncan GJ,Hilton BJ,Plemel JR,Tetzlaff W.细胞移植治疗脊髓损伤（英文）[J].中华神经外科疾病研究杂志,2017,16(3):216-216. 被引量：55
9张长杰,Ajiboye AB,Willett FR,Young DR.概念验证演示:脑控制的肌肉刺激对恢复四肢瘫患者及物及抓握能力[J].中国康复,2017,32(4):349-349. 被引量：13
10Aysegul Gunduz,John Rothwell,Joan Vidal,Hatice Kumru.Non-invasive brain stimulation to promote motor and functional recovery following spinal cord injury[J].Neural Regeneration Research,2017,12(12):1933-1938. 被引量：9

引证文献2

1赖碧琴,曾湘,丁英,李戈,曾园山.神经元中继器策略修复脊髓损伤的研究进展[J].中国科学：生命科学,2020,50(10):1013-1024. 被引量：1
2王子珏,高钰丹,赵文,郝飞,郝鹏,段红梅,李晓光,杨朝阳.脊髓损伤后神经环路重建的研究进展[J].中国科学：生命科学,2022,52(10):1484-1494. 被引量：4

二级引证文献5

1徐旭光,张岩,鲁子瑜,白杰,刘陶迪.IL-1β、IL-6与TNF-α在脊髓损伤急性期与亚急性期中的表达研究[J].疾病监测与控制,2024,18(2):85-89.
2田祎,姚东晓,雷德强.生物材料结合细胞移植治疗脊髓损伤的研究进展[J].沈阳医学院学报,2023,25(1):78-82. 被引量：3
3涂少臣.绞股蓝皂苷ⅩⅦ对急性脊髓损伤大鼠的神经保护及细胞凋亡的影响[J].福建医药杂志,2023,45(4):125-126.
4赵泽丹,郑遵成,樊湘珍,钱红丽,王洪强,王德强.皮层体感诱发电位在脊髓损伤康复评估中的应用[J].中国疗养医学,2023,32(12):1309-1312.
5曾园山,赖碧琴,曾湘,丁英,李戈.神经元中继器——新专业名词浅析[J].解剖学杂志,2024,47(1):86-87.

1Sung Chul Lee,Chae Woo Lim,Wenzhi Lan,Kai He,Sheng Luan.ABA Signaling in Guard Cells Entails a Dynamic Protein-Protein Interaction Relay from the PYL-RCAR Family Receptors to Ion Channels[J].Molecular Plant,2013,6(2):528-538. 被引量：10
2新研究让癌细胞自己积极“吃药”[J].生物学教学,2013(1):69-69.
3Nagi G.Ayad,Jae K.Lee,Vance P.Lemmon.Casein kinase signaling in axon regeneration[J].Neural Regeneration Research,2016,11(2):210-211.
4Menghon Cheah,Melissa R.Andrews.Targeting cell surface receptors for axon regeneration in the central nervous system[J].Neural Regeneration Research,2016,11(12):1884-1887. 被引量：3
5Liwei Lu,Xiuyu Wang,Chuanxi Xiong,Li Yao.Recent advances in biological detection with magnetic nanoparticles as a useful tool[J].Science China Chemistry,2015,58(5):793-809. 被引量：6
6Saijilafu,Bo-Yin Zhang,Feng-Quan Zhou.Signaling pathways that regulate axon regeneration[J].Neuroscience Bulletin,2013,29(4):411-420. 被引量：7
7刘岳松.电力系统继电保护的现状与发展趋势[J].黑龙江科技信息,2008(7):31-31. 被引量：5
8Di Anna L.Hynds.Subcellular localization of Rho GTPases: implications for axon regeneration[J].Neural Regeneration Research,2015,10(7):1032-1033.
9WANG XiaoJing,LIU Zhuang.Carbon nanotubes in biology and medicine:An overview[J].Chinese Science Bulletin,2012,57(2):167-180. 被引量：2
10John Bauman Kevin McVary.Autonomic nerve development contributes to prostate cancer progression[J].Asian Journal of Andrology,2013,15(6):713-714. 被引量：12

Neural Regeneration Research

2014年第12期

浏览历史

内容加载中请稍等...

Relay strategies combined with axon regeneration: a promising approach to restore spinal cord injury 被引量：2

参考文献15

同被引文献21

引证文献2

二级引证文献5

相关作者

相关机构

相关主题

浏览历史