Measuring functional core regions of hindlimb movement control in the rat spinal cord with intraspinal microstimulation_Journal of Biomedical Engineering

Authors：

CHEN Yi ¹ , MA Lei ² , DU Wei ² ,  SHEN Xiaoyan ²

1. Department of Biomedical Engineering, School of Medicine, Nantong University, Nantong, Jiangsu 226019, P.R.China;
2. Department of Bioelectronics, School of Electronic Information, Nantong University, Nantong, Jiangsu 226019, P.R.China;

Corresponding author：

SHEN Xiaoyan, Email: xiaoyansho@ntu.edu.cn

Keywords：

intraspinal microstimulation; motor function; functional electrical stimulation; core region

DOI：

10.7507/1001-5515.201607029

Video：

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In order to improve the accuracy and reliability of the electrodes implant location when using spinal functional electrical stimulation to rebuild hindlimb motor function, we measured the distributions of function core regions in rat spinal cord associated with hindlimb movements. In this study, we utilized three-dimensional scanning intraspinal microstimulation technology to stimulate the rat spinal cord to generate hip, knee and ankle joint movements, and acquired the coordinates of the sites in spinal cord which evoked these movements. In this article, 12 SD rats were used to overcome the individual differences in the functional region of the spinal cord. After normalized and overlaid the messages, we obtained the function core regions in spinal cord associated with ankle dorsiflexion movement, hip flexion movement, hip extension movement and hip adduction movement. It provides a reference for rebuilding the hindlimb movement function with micro-electronic neural bridge.

Citation： CHEN Yi, MA Lei, DU Wei, SHEN Xiaoyan. Measuring functional core regions of hindlimb movement control in the rat spinal cord with intraspinal microstimulation. Journal of Biomedical Engineering, 2017, 34(4): 622-626. doi: 10.7507/1001-5515.201607029 Copy

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6.	沈晓燕, 王志功, 吕晓迎, 等. 用微电子神经桥实现受控脊蟾蜍运动功能重建的研究. 高技术通讯, 2011, 21(5): 530-534.
7.	Huang Zonghao, Wang Zhigong, Lu Xiaoying, et al. The principle of the Micro-Electronic neural bridge and a prototype system design. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 2016, 24(1): 180-191.
8.	季达峰, 吕广明, 刘苏, 等. 生物素化葡聚糖胺顺行追踪标记大鼠皮质脊髓束. 南通大学学报: 医学版, 2008, 28(5): 336-338.
9.	谭龙旺, 秦兆邦, 朱峰,等. 电针联合嗅鞘细胞移植对大鼠脊髓损伤神经轴突再生及走向的影响. 中国骨伤, 2015, 28(5): 441-445.
10.	叶达伟. 调控小鼠肾脏功能的相关中枢核团神经解剖学研究. 武汉: 华中科技大学, 2012.
11.	Grahn P J, Lee K H, Kasasbeh A, et al. Wireless control of intraspinal microstimulation in a rodent model of paralysis. J Neurosurg, 2015, 123(1): 232-242.
12.	Bamford J A, Mushahwar V K. Chapter 17–Intraspinal microstimulation for the recovery of function following spinal cord injury. Progress in Brain Research, 2011, 194(1): 227-239.
13.	Bamford J A, Putman C T, Mushahwar V K. Intraspinal microstimulation preferentially recruits fatigue-resistant muscle fibres and generates gradual force in rat. Journal of Physiology, 2005, 569(3): 873-884.
14.	van den Honert C, Mortimer J T. The response of the myelinated nerve fiber to short duration biphasic stimulating currents. Ann Biomed Eng, 1979, 7(2): 117-125.

1. 封亚平, 朱辉, 刘艳生, 等. 脊髓损伤治疗现状. 中华神经外科疾病研究杂志, 2008, 7(3): 279-280.
2. 韩倩倩, 许琰, 王宏, 等. 干细胞与脊髓损伤的治疗. 组织工程与重建外科杂志, 2015(4): 269-273.
3. Jackson A, Zimmermann J B. Neural interfaces for the brain and spinal cord-restoring motor function. Nat Rev Neurol, 2012, 8(12): 690-699.
4. 王志功, 顾晓松, 吕晓迎. 微电子系统辅助神经信道功能恢复方法及其装置: CN, CN1810203. 2006-08-02.
5. 王志功, 吕晓迎, 顾晓松. 中枢神经信号微电子技术检测、处理与重建研究//第十四届中国神经网络学术会议论文集. 合肥, 2004: 77-81.
6. 沈晓燕, 王志功, 吕晓迎, 等. 用微电子神经桥实现受控脊蟾蜍运动功能重建的研究. 高技术通讯, 2011, 21(5): 530-534.
7. Huang Zonghao, Wang Zhigong, Lu Xiaoying, et al. The principle of the Micro-Electronic neural bridge and a prototype system design. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 2016, 24(1): 180-191.
8. 季达峰, 吕广明, 刘苏, 等. 生物素化葡聚糖胺顺行追踪标记大鼠皮质脊髓束. 南通大学学报: 医学版, 2008, 28(5): 336-338.
9. 谭龙旺, 秦兆邦, 朱峰,等. 电针联合嗅鞘细胞移植对大鼠脊髓损伤神经轴突再生及走向的影响. 中国骨伤, 2015, 28(5): 441-445.
10. 叶达伟. 调控小鼠肾脏功能的相关中枢核团神经解剖学研究. 武汉: 华中科技大学, 2012.
11. Grahn P J, Lee K H, Kasasbeh A, et al. Wireless control of intraspinal microstimulation in a rodent model of paralysis. J Neurosurg, 2015, 123(1): 232-242.
12. Bamford J A, Mushahwar V K. Chapter 17–Intraspinal microstimulation for the recovery of function following spinal cord injury. Progress in Brain Research, 2011, 194(1): 227-239.
13. Bamford J A, Putman C T, Mushahwar V K. Intraspinal microstimulation preferentially recruits fatigue-resistant muscle fibres and generates gradual force in rat. Journal of Physiology, 2005, 569(3): 873-884.
14. van den Honert C, Mortimer J T. The response of the myelinated nerve fiber to short duration biphasic stimulating currents. Ann Biomed Eng, 1979, 7(2): 117-125.

Journal of Biomedical Engineering

Measuring functional core regions of hindlimb movement control in the rat spinal cord with intraspinal microstimulation

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