Spinal cord myelin is vulnerable to decompression.

J P Bond, D A Kirschner
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引用次数: 7

Abstract

Spinal cord white matter is the major site of tissue damage resulting from decompression sickness (DCS or "the bends"). Damage is thought to result from bubble nucleation within the tissue. Why DCS occurs predominantly in the spinal cord and not in the brain is not known; neither is the exact pathological mechanism by which the spinal cord is damaged, nor how multiple sclerosis (MS)-like symptoms may ensue. To investigate the molecular basis of white matter damage, we subjected myelinated mouse tissues to varying durations of decompression, and then after recompression to one atmosphere, examined them for changes in myelin structure and composition. X-ray diffraction showed that the myelin period in spinal cord decreased by 4%, whereas those of optic and sciatic nerves were stable. The change in period was accompanied by a change in membrane bilayer profile--i.e., relative to control, the width of the bilayer decreased by approximately 6 A, whereas the interbilayer spaces each increased by approximately 3 A. The changes in electron density levels suggested a redistribution of matter from the interbilayer spaces into the lipid headgroup layers. By contrast with these structural changes, sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and high-performance thin layer chromatography (HPTLC) revealed no noticeable change in myelin composition--i.e., there was no release of myelin-specific proteins or lipids. Our findings indicate that spinal cord myelin has an inherent structural vulnerability that may facilitate the targeting of this tissue during pressure changes.

脊髓髓磷脂容易受到减压的影响。
脊髓白质是减压病(DCS或“减压病”)引起的组织损伤的主要部位。损伤被认为是由组织内的气泡成核引起的。为什么DCS主要发生在脊髓而不是在大脑中尚不清楚;脊髓受损的确切病理机制也不清楚,多发性硬化症(MS)样症状如何发生也不清楚。为了研究白质损伤的分子基础,我们对有髓鞘小鼠组织进行了不同时间的减压,然后在再压缩到一个大气压后,检查了髓鞘结构和成分的变化。x射线衍射显示脊髓髓鞘期减少4%,视神经和坐骨神经髓鞘期保持稳定。周期的变化伴随着膜双层结构的变化。与对照相比,双分子层的宽度减少了约6 A,而双分子层间的空间分别增加了约3 A。电子密度水平的变化表明物质从双层间隙重新分布到脂质头群层。与这些结构变化相比,十二烷基硫酸钠聚丙烯酰胺凝胶电泳(SDS-PAGE)和高效薄层色谱(HPTLC)显示髓磷脂成分没有明显变化。没有髓磷脂特异性蛋白或脂质的释放。我们的研究结果表明,脊髓髓磷脂具有固有的结构脆弱性,可能有助于在压力变化时靶向该组织。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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