Finite Element Analysis of Mechanical Ocular Sequelae from Badminton Shuttlecock Projectile Impact

IF 3.2 Q1 OPHTHALMOLOGY
John D. Hong PhD , Jose A. Colmenarez MS , Elliot H. Choi MD, PhD , Alex Suh BS , Andrew Suh BS , Matthew Lam MD , Annette Hoskin PhD , Don S. Minckler MD, MS , Ken Y. Lin MD, PhD , Kourosh Shahraki MD , Rupesh Agrawal MD , Pengfei Dong PhD , Linxia Gu PhD , Donny W. Suh MD, MBA
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引用次数: 0

Abstract

Purpose

With the growing popularity of badminton worldwide, the incidence of badminton-related ocular injuries is expected to rise. The high velocity of shuttlecocks renders ocular traumas particularly devastating, especially with the possibility of permanent vision loss. This study investigated the mechanism behind ocular complications through simulation analyses of mechanical stresses and pressures upon shuttlecock impact.

Design

Computational simulation study.

Participants

None.

Methods

A 3-dimensional human eye model was reconstructed based on the physiological and biomechanical properties of various ocular tissues. Finite element analysis simulations involved a frontal collision with a shuttlecock projectile at 128.7 km/hour (80 mph). Intraocular pressure (IOP) changes and tissue stress were mapped and quantified in the following ocular structures: the limbus, ciliary body, zonular fibers, ora serrata, retina, and optic nerve head.

Main Outcome Measures

Intraocular pressure and tissue stress.

Results

Upon shuttlecock impact, compressive force was transferred to the anterior pole of the cornea, propagating posteriorly to the optic nerve head. Deflection of forces anteriorly contributed to refractory oscillations of compressive and tensile stress of ocular tissue. Initial impact led to a momentary (<1 ms) spike in IOP 5.66 MPa (42.5 × 103 mmHg) that radially distributed for a very brief instance (<1 ms) of pressure at the trabecular meshwork of the iridocorneal angle of 1.25 MPa (9.4 × 103 mmHg). The lens had a maximal posterior displacement of 1.5 mm with peak zonular fiber tensile strain of 52%. The limbus, ciliary body, and ora serrata had a peak tensile stress of 5.16 MPa, 1.90 MPa, and 0.62 MPa, respectively. Compressive force from the sclera concentrated at the optic nerve head for a peak stress of 5.97 MPa while peak pressure from vitreous humor was 7.99 MPa.

Conclusions

Shuttlecock impact led to a very brief, substantial rise in pressure and stress significant for tissue damage and subsequent complications, such as secondary glaucoma, angle recession, lens subluxation, hyphema, or retinal dialysis. Our findings offer valuable mechanistic insights into how ocular structures are affected by shuttlecock projectile impact to inform clinical assessments and treatment strategies, while highlighting the importance of protective eyewear in racket sports.

Financial Disclosures

Proprietary or commercial disclosure may be found in the Footnotes and Disclosures at the end of this article.
羽毛球毽弹丸冲击眼部机械后遗症的有限元分析
目的随着羽毛球运动在世界范围内的日益普及,与羽毛球运动相关的眼部损伤的发生率预计会上升。高速旋转的羽毛球使眼部创伤尤其具有破坏性,特别是有可能造成永久性视力丧失。本研究通过对毽子撞击时的机械应力和压力进行模拟分析,研究眼部并发症背后的机理。有限元分析模拟了以 128.7 公里/小时(80 英里/小时)的速度与毽子弹丸的正面碰撞。主要结果测量眼压和组织应力。结果毽子撞击时,压缩力传递到角膜前极,并向后传播到视神经头。力向前方的偏转导致眼组织的压应力和拉应力发生折返性振荡。最初的撞击导致眼压瞬时(1 毫秒)飙升至 5.66 兆帕(42.5 × 103 毫米汞柱),在虹膜角小梁网的压力为 1.25 兆帕(9.4 × 103 毫米汞柱)的极短时间内(1 毫秒),压力呈放射状分布。晶状体的最大后移量为 1.5 毫米,晶状体纤维拉伸应变的峰值为 52%。角膜缘、睫状体和血清口的拉伸应力峰值分别为 5.16 兆帕、1.90 兆帕和 0.62 兆帕。来自巩膜的压迫力集中在视神经头,峰值应力为 5.97 兆帕,而来自玻璃体的峰值压力为 7.99 兆帕。我们的研究结果为了解毽球弹射物如何影响眼部结构提供了宝贵的机理见解,为临床评估和治疗策略提供了依据,同时强调了在球拍类运动中佩戴防护眼镜的重要性。
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
Ophthalmology science
Ophthalmology science Ophthalmology
CiteScore
3.40
自引率
0.00%
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0
审稿时长
89 days
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