Repetitive magnetic stimulation affects the microenvironment of nerve regeneration and evoked potentials after spinal cord injury

doi:10.4103/1673-5374.182710

Neural Regeneration Research ›› 2016, Vol. 11 ›› Issue (5): 816-822.doi: 10.4103/1673-5374.182710

Previous Articles Next Articles

Repetitive magnetic stimulation affects the microenvironment of nerve regeneration and evoked potentials after spinal cord injury

Jin-lan Jiang1, 2, #, Xu-dong Guo3, Shu-quan Zhang4, Xin-gang Wang5, Shi-feng Wu5, *, #

"1 Scientific Research Center, China-Japan Union Hospital, Jilin University, Changchun, Jilin Province, China 2 Department of Orthopedics, China-Japan Union Hospital, Jilin University, Changchun, Jilin Province, China 3 Department of Cardiovascular Medicine, China-Japan Union Hospital, Jilin University, Changchun, Jilin Province, China 4 Department of Orthopedics, Tianjin Nankai Hospital, Tianjin, China 5 Department of Burns and Plastic Surgery, China-Japan Union Hospital, Jilin University, Changchun, Jilin Province, China"

Received:2016-01-26 Online:2016-05-20 Published:2016-05-20
Contact: Shi-feng Wu, wsf19770620@126.com.

Abstract

Abstract:

"Repetitive magnetic stimulation has been shown to alter local blood flow of the brain, excite the corticospinal tract and muscle, and induce motor function recovery. We established a rat model of acute spinal cord injury using the modified Allen’s method. After 4 hours of injury, rat models received repetitive magnetic stimulation, with a stimulus intensity of 35% maximum output intensity, 5-Hz frequency, 5 seconds for each sequence, and an interval of 2 minutes. This was repeated for a total of 10 sequences, once a day, 5 days in a week, for 2 consecutive weeks. After repetitive magnetic stimulation, the number of apoptotic cells decreased, matrix metalloproteinase 9/2 gene and protein expression decreased, nestin expression increased, somatosensory and motor-evoked potentials recovered, and motor function recovered in the injured spinal cord. These findings confirm that repetitive magnetic stimulation of the spinal cord improved the microenvironment of neural regeneration, reduced neuronal apoptosis, and induced neuroprotective and repair effects on the injured spinal cord."

Key words: "nerve regeneration, spinal cord injury, repetitive magnetic stimulation, motor function, rats, rehabilitation, plasticity, regenerative microenvironment, neural regeneration"

Jin-lan Jiang, Xu-dong Guo, Shu-quan Zhang, Xin-gang Wang, Shi-feng Wu. Repetitive magnetic stimulation affects the microenvironment of nerve regeneration and evoked potentials after spinal cord injury[J]. Neural Regeneration Research, 2016, 11(5): 816-822.

[1]	Yu Li, Ping-Ping Shen, Bin Wang. Induced pluripotent stem cell technology for spinal cord injury: a promising alternative therapy [J]. Neural Regeneration Research, 2021, 16(8): 1500-1509.
[2]	Ci Li, Song-Yang Liu, Wei Pi, Pei-Xun Zhang. Cortical plasticity and nerve regeneration after peripheral nerve injury [J]. Neural Regeneration Research, 2021, 16(8): 1518-1523.
[3]	Maral Yeganeh Doost, Benoît Herman, Adrien Denis, Julien Sapin, Daniel Galinski, Audrey Riga, Patrice Laloux, Benoît Bihin, Yves Vandermeeren. Bimanual motor skill learning and robotic assistance for chronic hemiparetic stroke: a randomized controlled trial [J]. Neural Regeneration Research, 2021, 16(8): 1566-1573.
[4]	Shi-Qin Lv, Wutian Wu. ISP and PAP4 peptides promote motor functional recovery after peripheral nerve injury [J]. Neural Regeneration Research, 2021, 16(8): 1598-1605.
[5]	Wen-Jing Wang, Yan-Biao Zhong, Jing-Jun Zhao, Meng Ren, Si-Cong Zhang, Ming-Shu Xu, Shu-Tian Xu, Ying-Jie Zhang, Chun-Lei Shan. Transcranial pulse current stimulation improves the locomotor function in a rat model of stroke [J]. Neural Regeneration Research, 2021, 16(7): 1229-1234.
[6]	Qiang Gao, Aaron Leung, Yong-Hong Yang, Benson Wui-Man Lau, Qian Wang, Ling-Yi Liao, Yun-Juan Xie, Cheng-Qi He. Extremely low frequency electromagnetic fields promote cognitive function and hippocampal neurogenesis of rats with cerebral ischemia [J]. Neural Regeneration Research, 2021, 16(7): 1252-1257.
[7]	Ayaka Sugeno, Wenhui Piao, Miki Yamazaki, Kiyofumi Takahashi, Koji Arikawa, Hiroko Matsunaga, Masahito Hosokawa, Daisuke Tominaga, Yoshio Goshima, Haruko Takeyama, Toshio Ohshima. Cortical transcriptome analysis after spinal cord injury reveals the regenerative mechanism of central nervous system in CRMP2 knock-in mice [J]. Neural Regeneration Research, 2021, 16(7): 1258-1265.
[8]	Dulce Parra-Villamar, Liliana Blancas-Espinoza, Elisa Garcia-Vences, Juan Herrera-García, Adrian Flores-Romero, Alberto Toscano-Zapien, Jonathan Vilchis Villa, Rodríguez Barrera-Roxana, Soria Zavala Karla, Antonio Ibarra, Raúl Silva-García. Neuroprotective effect of immunomodulatory peptides in rats with traumatic spinal cord injury [J]. Neural Regeneration Research, 2021, 16(7): 1273-1280.
[9]	Allison S. Liang, Joanna E. Pagano, Christopher A. Chrzan, Randall D. McKinnon. Suicide transport blockade of motor neuron survival generates a focal graded injury and functional deficit [J]. Neural Regeneration Research, 2021, 16(7): 1281-1287.
[10]	Li-Jian Zhang, Yao Chen, Lu-Xuan Wang, Xiao-Qing Zhuang He-Chun Xia. Identification of potential oxidative stress biomarkers for spinal cord injury in erythrocytes using mass spectrometry [J]. Neural Regeneration Research, 2021, 16(7): 1294-1301.
[11]	Rong Li, Zu-Cheng Huang, Hong-Yan Cui, Zhi-Ping Huang, Jun-Hao Liu, Qing-An Zhu, Yong Hu. Utility of somatosensory and motor-evoked potentials in reflecting gross and fine motor functions after unilateral cervical spinal cord contusion injury [J]. Neural Regeneration Research, 2021, 16(7): 1323-1330.
[12]	Ke-Ke Chen, Zhao-Hui Jin, Lei Gao, Lin Qi, Qiao-Xia Zhen, Cui Liu, Ping Wang, Yong-Hong Liu, Rui-Dan Wang, Yan-Jun Liu, Jin-Ping Fang, Yuan Su, Xiao-Yan Yan, Ai-Xian Liu, Bo-Yan Fang. Efficacy of short-term multidisciplinary intensive rehabilitation in patients with different Parkinson’s disease motor subtypes: a prospective pilot study with 3-month follow-up [J]. Neural Regeneration Research, 2021, 16(7): 1336-1343.
[13]	Zhong-Yue Lv, Ying Li, Jing Liu. Progress in clinical trials of stem cell therapy for cerebral palsy [J]. Neural Regeneration Research, 2021, 16(7): 1377-1382.
[14]	Qiu-Shi Gao, Ya-Han Zhang, Hang Xue, Zi-Yi Wu, Chang Li, Ping Zhao . Brief inhalation of sevoflurane can reduce glial scar formation after hypoxic-ischemic brain injury in neonatal rats [J]. Neural Regeneration Research, 2021, 16(6): 1052-1061.
[15]	Yu-Xuan Wu, Hao Ma, Jian-Lan Wang, Wei Qu. Production of chitosan scaffolds by lyophilization or electrospinning: which is better for peripheral nerve regeneration? [J]. Neural Regeneration Research, 2021, 16(6): 1093-1098.

Repetitive magnetic stimulation affects the microenvironment of nerve regeneration and evoked potentials after spinal cord injury

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments