中国神经再生研究(英文版)
中國神經再生研究(英文版)
중국신경재생연구(영문판)
NERVE REGENERATION RESEARCH
2014年
4期
377-384
,共8页
nerve regeneration%glial scar%proteoglycan%axon growth%spinal cord injury%contusion%inhibitory%inflammation%astrocyte%macrophage%neural regeneration
Glial cells in the central nervous system (CNS) contribute to formation of the extracellular matrix, which provides adhesive sites, signaling molecules, and a diffusion barrier to enhance efifcient neurotransmission and axon potential propagation. In the normal adult CNS, the extracellular matrix (ECM) is relatively stable except in selected regions characterized by dynamic remodel-ing. However, after trauma such as a spinal cord injury or cortical contusion, the lesion epicenter becomes a focus of acute neuroinlfammation. The activation of the surrounding glial cells leads to a dramatic change in the composition of the ECM at the edges of the lesion, creating a perile-sion environment dominated by growth inhibitory molecules and restoration of the peripheral/central nervous system border. An advantage of this response is to limit the invasion of damaging cells and diffusion of toxic molecules into the spared tissue regions, but this occurs at the cost of inhibiting migration of endogenous repair cells and preventing axonal regrowth. The following review was prepared by reading and discussing over 200 research articles in the ifeld published in PubMed and selecting those with signiifcant impact and/or controversial points. This article highlights structural and functional features of the normal adult CNS ECM and then focuses on the reactions of glial cells and changes in the perilesion border that occur following spinal cord or contusive brain injury. Current research strategies directed at modifying the inhibitory perile-sion microenvironment without eliminating the protective functions of glial cell activation are discussed.