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大型动物模型中初次撞击时骨应力的有限元分析:马第三掌骨远端

Finite-Element Analysis of Bone Stresses on Primary Impact in a Large-Animal Model: The Distal End of the Equine Third Metacarpal.

作者信息

McCarty Cristin A, Thomason Jeffrey J, Gordon Karen D, Burkhart Timothy A, Milner Jaques S, Holdsworth David W

机构信息

Department of Biomedical Science, Ontario Veterinary College, University of Guelph, Guelph, Ontario, Canada.

Department of Biomedical Engineering, School of Engineering, University of Guelph, Guelph, Ontario, Canada.

出版信息

PLoS One. 2016 Jul 26;11(7):e0159541. doi: 10.1371/journal.pone.0159541. eCollection 2016.

DOI:10.1371/journal.pone.0159541
PMID:27459189
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4961423/
Abstract

OBJECTIVE

To assess whether the transient stresses of foot impact with the ground are similar to those found during midstance loading and if the location of high stress correlate with the sites most commonly associated with mechanically induced osteoarthritis (OA). We compared impact stresses in subchondral bone between two subject-specific, three-dimensional, finite-element models of the equine metacarpophalangeal (MCP) joint-one with advanced OA and one healthy, and with similar published data on the stresses that occur at midstance.

METHODS

Two right MCP joints (third metacarpal and proximal phalanx) were scanned using micro-computed tomography (μCT). Images were segmented, and meshed using modified 10-node quadratic tetrahedral elements. Bone material properties were assigned based on the bone density. An impact velocity of 3.55 m/s was applied to each model and contact pressures and stress distribution were calculated for each. In a separate iteration, the third metacarpal was loaded statically. A sampling grid of 160 equidistant points was superimposed over selected slices, and average peak stresses were calculated for 6 anatomical regions. Within-region maximal peak and average von Mises stresses were compared between healthy and OA bones in both midstance and impact loading.

RESULTS

Average impact stresses across all regions, in both locations (palmar and dorsal) were greater in the OA model. Highest impact stresses were located in the dorsal medial condyle in the healthy (12.8 MPa) and OA (14.1MPa) models, and were lowest in the palmar medial and lateral parasagittal grooves in the healthy (5.94 MPa) and OA (7.07 MPa) models. The healthy static model had higher peak (up to 49.7% greater) and average (up to 38.6% greater) stresses in both locations and across all regions compared to the OA static model.

CONCLUSIONS

Under simulated footfall a trot, loading on the dorsal aspect of the third metacarpal at impact created stresses similar to those found during midstance. The high accelerations that occur under impact loading are likely responsible for creating the high stresses, as opposed to midstance loading where the high stresses are the result of high mass loading. Although the stress magnitudes were found to be similar among the two loading conditions, the location of the high stress loading occurred in sites that are not typically associated with osteoarthritic changes.

摘要

目的

评估足部与地面撞击时的瞬态应力是否与站立中期负重时的应力相似,以及高应力位置是否与机械性骨关节炎(OA)最常相关的部位相关。我们比较了马掌指关节(MCP)的两个特定个体的三维有限元模型(一个患有晚期OA,一个健康)软骨下骨的撞击应力,并与已发表的关于站立中期应力的类似数据进行了比较。

方法

使用微型计算机断层扫描(μCT)扫描两个右MCP关节(第三掌骨和近端指骨)。对图像进行分割,并使用改良的10节点二次四面体单元进行网格化。根据骨密度分配骨材料属性。对每个模型施加3.55 m/s的撞击速度,并计算每个模型的接触压力和应力分布。在另一次迭代中,对第三掌骨进行静态加载。在选定切片上叠加一个由160个等距点组成的采样网格,并计算6个解剖区域的平均峰值应力。比较了健康和OA骨骼在站立中期和撞击加载时区域内的最大峰值和平均冯·米塞斯应力。

结果

OA模型中所有区域在两个位置(掌侧和背侧)的平均撞击应力均更高。健康模型(12.8 MPa)和OA模型(14.1MPa)中最高撞击应力位于背侧内侧髁,而健康模型(5.94 MPa)和OA模型(7.07 MPa)中掌侧内侧和外侧矢状旁沟的应力最低。与OA静态模型相比,健康静态模型在两个位置和所有区域的峰值应力(高达49.7%)和平均应力(高达38.6%)更高。

结论

在模拟小跑的脚步落地时,第三掌骨背侧在撞击时的负荷产生的应力与站立中期时的应力相似。与站立中期高应力是由高负重导致不同,撞击负荷下的高加速度可能是产生高应力的原因。尽管发现两种负荷条件下的应力大小相似,但高应力负荷的位置发生在通常与骨关节炎变化无关的部位。

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