Computer Modelling Study of Volume Kinetics in Intraocular Segments Following Airbag Impact Using Finite Element Analysis.

Clinical ophthalmology (Auckland, N.Z.) Pub Date : 2024-09-07 eCollection Date: 2024-01-01 DOI:10.2147/OPTH.S479607

Aya Ikeda, Asami Shimokawa, Kazuhiro Harada, Tomoko Tsukahara-Kawamura, Jane Huang, Hiroaki Ozaki, Eiichi Uchio

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引用次数: 0

Abstract

Background: We have previously studied the physiological and mechanical responses of the eye to blunt trauma in various situations using finite element analysis (FEA). In this study, we evaluated the volume kinetics of an airbag impact on the eye using FEA to sequentially determine the volume change rates of intraocular segments at various airbag deployment velocities.

Methods: The human eye model we created was used in simulations with the FEA program PAM-GENERIS^TM (Nihon ESI, Tokyo, Japan). Different airbag deployment velocities, 30, 40, 50, 60 and 70 m/s, were applied in the forward direction. The volume of the deformed eye impacted by the airbag was calculated as the integrated value of all meshes in each segment, and the decrease rate was calculated as the ratio of the decreased volume of each segment at particular timepoints to the value before the airbag impact.

Results: The minimum volume of the anterior chamber was 63%, 69% and 50% at 50, 60 and 70 m/s airbag impact velocity, respectively, showing a curve with a sharp decline followed by gradual recovery. In contrast to the anterior chamber, the volume of the lens recovered promptly, reaching 80-90% at the end of observation, except for the case of 60 m/s. Following the decrease, the volume increased to more than that of baseline at 60 m/s. The rate of volume change of the vitreous was distributed in a narrow range, 99.2-100.4%.

Conclusion: In this study, we found a large, prolonged decrease of volume in the anterior chamber, a similar large decrease followed by prompt recovery of volume in the lens, and a time-lag in the volume decrease between these tissues. These novel findings may provide an important insight into the pathophysiological mechanism of airbag ocular injuries through this further evaluation, employing a refined FEA model representing cuboidal deformation, to develop a more safe airbag system.

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利用有限元分析法对安全气囊撞击后眼内部分的体积动力学进行计算机建模研究。

背景：我们以前曾利用有限元分析（FEA）研究了眼球在各种情况下对钝性创伤的生理和机械反应。在本研究中，我们使用有限元分析评估了安全气囊撞击眼球时的体积动力学，以确定在不同安全气囊展开速度下眼球内部各节的体积变化率：我们创建的人眼模型使用有限元分析程序 PAM-GENERISTM (Nihon ESI, Tokyo, Japan) 进行模拟。在前进方向应用了 30、40、50、60 和 70 米/秒的不同安全气囊展开速度。受气囊撞击的变形眼球的体积计算为每个节段所有网格的综合值，下降率计算为每个节段在特定时间点下降的体积与气囊撞击前的体积之比：结果：在气囊撞击速度为 50、60 和 70 m/s 时，前房的最小容积分别为 63%、69% 和 50%，呈现出急剧下降后逐渐恢复的曲线。与前房相比，晶状体的体积迅速恢复，在观察结束时达到 80-90%，60 米/秒的情况除外。在下降之后，60 米/秒时的体积增加到超过基线。玻璃体的体积变化率分布范围较窄，为 99.2%-100.4%：在这项研究中，我们发现前房的体积下降幅度大且持续时间长，晶状体的体积在迅速恢复后也有类似的大幅下降，而且这些组织之间的体积下降存在时间差。通过采用代表立方体变形的精细有限元分析模型进行进一步评估，这些新发现可能会为气囊眼损伤的病理生理机制提供重要见解，从而开发出更安全的气囊系统。

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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来源期刊

Clinical ophthalmology (Auckland, N.Z.)

CiteScore

4.10

自引率

0.00%

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