体内用超长碳纳米管桥接截断的小鼠脊髓实现神经活动的部分恢复。

In Vivo Partial Restoration of Neural Activity across Severed Mouse Spinal Cord Bridged with Ultralong Carbon Nanotubes.

机构信息

Department of Physics, Northeastern University, Boston, Massachusetts 02115, United States.

Department of Physics, Southern Illinois University, Carbondale, Illinois 62901, United States.

出版信息

ACS Appl Bio Mater. 2021 May 17;4(5):4071-4078. doi: 10.1021/acsabm.1c00248. Epub 2021 May 4.

DOI:10.1021/acsabm.1c00248

PMID:35006823

Abstract

Electrically bridging severed nerves in vivo has transformative healthcare implications, but current materials are inadequate. Carbon nanotubes (CNTs) are promising, with low impedance, high charge injection capacity, high flexibility, are chemically inert, and can electrically couple to neurons. Ultralong CNTs are unexplored for neural applications. Using only ultralong CNTs in saline, without neuroregeneration or rehabilitation, we partially restored neural activity across a severed mouse spinal cord, recovering 23.8% of the intact amplitude, while preserving signal shape. Neural signals are preferentially facilitated over artifact signals by a factor of ×5.2, suggesting ultralong CNTs are a promising material for neural-scaffolding and neural-electronics applications.

摘要

电桥接体内切断的神经具有变革性的医疗保健意义，但目前的材料还不够完善。碳纳米管（CNTs）具有低阻抗、高电荷注入能力、高柔韧性、化学惰性以及能够与神经元电耦合等特点，是很有前途的材料。尚未探索用于神经应用的超长 CNT。我们仅使用超长 CNT 生理盐水，不进行神经再生或康复，部分恢复了切断的小鼠脊髓的神经活动，恢复了完整振幅的 23.8%，同时保持信号形状。神经信号比伪迹信号优先促进 5.2 倍，表明超长 CNT 是神经支架和神经电子应用的有前途的材料。

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体内用超长碳纳米管桥接截断的小鼠脊髓实现神经活动的部分恢复。

In Vivo Partial Restoration of Neural Activity across Severed Mouse Spinal Cord Bridged with Ultralong Carbon Nanotubes.

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