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人纤维环细胞外基质的力学性能与位置和年龄有关。

Mechanical properties of the extra-fibrillar matrix of human annulus fibrosus are location and age dependent.

机构信息

Department of Biomedical Engineering, University of Delaware, 125 E Delaware Ave, Newark, 19716, Delaware.

出版信息

J Orthop Res. 2013 Nov;31(11):1725-32. doi: 10.1002/jor.22430. Epub 2013 Jul 2.

DOI:10.1002/jor.22430
PMID:23818058
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4164199/
Abstract

The mechanical behavior of the annulus fibrosus (AF) of the intervertebral disc can be modeled as a mixture of fibers, extra-fibrillar matrix (EFM), ions, and fluid. However, the properties of the EFM have not been measured directly. We measured mechanical properties of the human EFM at several locations, determined the effect of age and degeneration, and evaluated whether changes in EFM properties correspond to AF compositional changes. EFM mechanical properties were measured using a method that combines osmotic loading and confined compression. AF samples were dissected from several locations, and mechanical properties were correlated with age, degeneration, and composition. EFM modulus was found to range between 10 and 50 kPa, increasing nonlinearly with compression magnitude and being highest in the AF outer-anterior region. EFM properties were not correlated with composition or degeneration. However, the EFM modulus, its relative contribution to tissue modulus, and model parameters were correlated with age. These measurements will result in more accurate predictions of deformations in the intervertebral disc. Additionally, parameters such as permeability and diffusivity used for biotransport analysis of glucose and other solutes depend on EFM deformation. Consequently, the accuracy of biotransport simulations will be greatly improved.

摘要

椎间盘纤维环的力学行为可以模拟为纤维、细胞外基质(EFM)、离子和流体的混合物。然而,EFM 的性质尚未直接测量。我们在几个位置测量了人 EFM 的力学性能,确定了年龄和退变的影响,并评估了 EFM 性质的变化是否与 AF 成分变化相对应。使用结合渗透压加载和受限压缩的方法测量 EFM 力学性能。从几个位置解剖 AF 样本,并将力学性能与年龄、退变和成分相关联。发现 EFM 模量在 10 到 50kPa 之间,随压缩幅度呈非线性增加,在前外侧纤维环区域最高。EFM 性质与组成或退变无关。然而,EFM 模量、其对组织模量的相对贡献以及模型参数与年龄相关。这些测量将导致对椎间盘变形的更准确预测。此外,用于葡萄糖和其他溶质的生物转运分析的参数,如渗透性和扩散性,取决于 EFM 的变形。因此,生物转运模拟的准确性将大大提高。

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