Department of Bioengineering, University of Pittsburgh, Pittsburgh, PA, USA.
Neurosci Bull. 2013 Aug;29(4):445-59. doi: 10.1007/s12264-013-1362-7. Epub 2013 Jul 18.
Spinal cord injury (SCI) results in permanent loss of function leading to often devastating personal, economic and social problems. A contributing factor to the permanence of SCI is that damaged axons do not regenerate, which prevents the re-establishment of axonal circuits involved in function. Many groups are working to develop treatments that address the lack of axon regeneration after SCI. The emergence of biomaterials for regeneration and increased collaboration between engineers, basic and translational scientists, and clinicians hold promise for the development of effective therapies for SCI. A plethora of biomaterials is available and has been tested in various models of SCI. Considering the clinical relevance of contusion injuries, we primarily focus on polymers that meet the specific criteria for addressing this type of injury. Biomaterials may provide structural support and/or serve as a delivery vehicle for factors to arrest growth inhibition and promote axonal growth. Designing materials to address the specific needs of the damaged central nervous system is crucial and possible with current technology. Here, we review the most prominent materials, their optimal characteristics, and their potential roles in repairing and regenerating damaged axons following SCi.
脊髓损伤(SCI)会导致功能永久丧失,从而经常造成个人、经济和社会方面的灾难性问题。导致 SCI 永久性的一个因素是受损的轴突不会再生,这阻止了参与功能的轴突回路的重建。许多研究小组正在努力开发治疗方法,以解决 SCI 后轴突再生不足的问题。再生用生物材料的出现以及工程师、基础和转化科学家以及临床医生之间的合作增加,为 SCI 的有效治疗方法的发展带来了希望。有大量的生物材料可供选择,并在各种 SCI 模型中进行了测试。考虑到挫伤损伤的临床相关性,我们主要关注满足解决这种类型损伤的特定标准的聚合物。生物材料可以提供结构支撑和/或作为输送载体,以阻止生长抑制并促进轴突生长。设计能够满足受损中枢神经系统特定需求的材料是至关重要的,而目前的技术是可行的。在这里,我们回顾了最突出的材料、它们的最佳特性以及它们在修复和再生 SCI 后受损轴突方面的潜在作用。