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植入非细胞材料预防椎间盘突出复发:使用定量椎间盘测压检查的猪体内模型

The implantation of non-cell-based materials to prevent the recurrent disc herniation: an in vivo porcine model using quantitative discomanometry examination.

作者信息

Wang Yao-Hung, Kuo Tzong-Fu, Wang Jaw-Lin

机构信息

Department of Electrical Engineering, National Taiwan University, Taipei, Taiwan, ROC.

出版信息

Eur Spine J. 2007 Jul;16(7):1021-7. doi: 10.1007/s00586-007-0306-1. Epub 2007 Jan 25.

DOI:10.1007/s00586-007-0306-1
PMID:17252217
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2219663/
Abstract

Recurrent disc herniation is frequently observed due to leakage of nucleus pulposus through injured anulus fibrosus. There is no effective treatment to prevent recurrent disc herniation yet. In this study, we proposed to implant non-cell-based materials into the porcine disc to stimulate the growth of fibrous tissue and thereby increase the disc functional integrity. The disc herniation was simulated by anular punctures using the spinal needles. Four clinically used implantation materials, i.e., gelfoam, platinum coil, bone cement and tissue glue, were delivered into the discs via percutaneous spinal needles. Two months after the surgery, the swine were killed. The degree of disc integrity of intact, naturally healed and implanted discs, was examined by quantitative discomanometry apparatus. We found the disc injury could not recover after 2 months of healing, and the disc implantation affected the degree of disc integrity. The disc integrity of gelfoam-implanted discs was better than that of coil-, bone cement-, and glue-implanted discs. The implantation of non-cell-based material was proved to be a potentially clinically applicable method to recover the integrity of injured discs and to prevent recurrent disc herniation.

摘要

由于髓核通过受损的纤维环泄漏,复发性椎间盘突出症经常可见。目前尚无预防复发性椎间盘突出症的有效治疗方法。在本研究中,我们建议将非细胞材料植入猪椎间盘,以刺激纤维组织生长,从而增强椎间盘功能完整性。使用脊椎穿刺针穿刺纤维环来模拟椎间盘突出。通过经皮脊椎穿刺针将四种临床常用的植入材料,即明胶海绵、铂金线圈、骨水泥和组织胶,植入椎间盘。术后两个月,处死猪。使用定量椎间盘测压仪检查完整、自然愈合和植入椎间盘的椎间盘完整性程度。我们发现,愈合2个月后椎间盘损伤无法恢复,且椎间盘植入影响了椎间盘完整性程度。植入明胶海绵的椎间盘的完整性优于植入线圈、骨水泥和胶水的椎间盘。事实证明,植入非细胞材料是一种潜在的临床适用方法,可恢复受损椎间盘的完整性并预防复发性椎间盘突出症。

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