轴突修复：亚细胞尺度的手术应用。

Axon repair: surgical application at a subcellular scale.

机构信息

Neuroscience and Bioengineering Programs, Department of Ophthalmology, University of California, San Francisco, CA 94143, USA.

出版信息

Wiley Interdiscip Rev Nanomed Nanobiotechnol. 2010 Mar-Apr;2(2):151-61. doi: 10.1002/wnan.76.

DOI:10.1002/wnan.76

PMID:20101712

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3150872/

Abstract

Injury to the nervous system is a common occurrence after trauma. Severe cases of injury exact a tremendous personal cost and place a significant healthcare burden on society. Unlike some tissues in the body that exhibit self healing, nerve cells that are injured, particularly those in the brain and spinal cord, are incapable of regenerating circuits by themselves to restore neurological function. In recent years, researchers have begun to explore whether micro/nanoscale tools and materials can be used to address this major challenge in neuromedicine. Efforts in this area have proceeded along two lines. One is the development of new nanoscale tissue scaffold materials to act as conduits and stimulate axon regeneration. The other is the use of novel cellular-scale surgical micro/nanodevices designed to perform surgical microsplicing and the functional repair of severed axons. We discuss results generated by these two approaches and hurdles confronting both strategies.

摘要

神经系统损伤是创伤后的常见并发症。严重的损伤不仅给患者带来巨大的个人代价，也给社会带来了沉重的医疗负担。与体内一些具有自我修复能力的组织不同，受损的神经细胞，特别是大脑和脊髓中的神经细胞，本身无法通过自身再生回路来恢复神经功能。近年来，研究人员开始探索微/纳米尺度工具和材料是否可用于解决神经医学领域的这一重大挑战。该领域的研究主要沿着两条路线展开。一种是开发新型纳米组织支架材料，作为导管并刺激轴突再生。另一种是使用新型细胞尺度的手术微/纳米器件，用于执行手术微吻合和切断轴突的功能修复。我们讨论了这两种方法所产生的结果，以及这两种策略所面临的障碍。

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